Antimicrobial peptides (Homo sapiens)

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46, 676, 655, 29, 57, 70, 80...51, 7512, 431, 64, 68, 7220, 34, 3541, 62, 6910, 52323, 16, 2433, 634, 2331, 36, 619, 18, 487813, 45, 745027, 47, 584, 232, 22, 7937, 6453, 594920, 34, 358, 17, 8511, 15325, 29, 57, 70, 80...66, 8118, 34, 48, 561, 33, 6319, 40, 7727, 4728, 7636026, 3925, 73, 8253, 59cell wallphagocytic vesicle lumencell wallhost cell cytosolAnionic phospholipids CLU(23-227) PI3RNASE7 HTN1 Microbial cell surface REG3A(27-175)/REG3G(27-175)SSA2 REG3A(38-175),REG3G(38-175)ITLN1 ELANE,CTSG,PRTN3:microbialcell surfacehC239-SEMG1 LTF:2xFe3+:2xCO3(2-)Ca2+ ATOX1:Cu1+LPSATOX1 Cu1+DefensinsCO3(2-) Zn2+ Microbial cell surface HTN3 S100A8:S100A9:Ca2+ELANE DCD peptidesAnionicphospholipids:microbial cell surfaceREG3A(38-175) Trypsin 2, 3Anionic phospholipids CTSG Anionic phospholipids PGLYRP3,4 dimersREG3A(38-175) Microbial cell surface S100A8 H+Mn2+ BPIMurNAc heptose PGLYRP2 dimerMicrobial cell surface S100A7A LCN2:2,5DHBAPGLYRP3,4dimer:peptidoglycanREG3A(38-175) Anionic phospholipids HTN1 Fe3+ HTN3 Zn2+Ca2+ SSA1 GNLY:bacterialanionic lipidsZn2+ DCD(63-110)Anionic phospholipids DCD(63-110) ATP7A:PDZD11HTN3(20-43) BPIFB4 ITLN1 trimer:Ca2+PGLYRP1 CO3(2-)SSA1 S100A8:S100A9:Ca2+:Mn2+:Na+BPIFB1 RNASE3,RNASE7,RNASE6,(RNASE8)BPIFA1 PRSS2(24-247) GNLYGlcNac-(1-->4)MurNAc-L-Ala-gamma-D-Glu-L-Lys-(D-Ala)2RNASE8 GNLYDCD(63-109) H2OBPIFA2 REG3A(27-175) LTFLPSRNASE7 PI3(23-117) Anionic phospholipids GlcNac-(1-->4)MurNAc-L-Ala-gamma-D-Glu-L-Lys-(D-Ala)2 RNASE8 (GlcNAc+MurNac)nAnionic phospholipids CLU(23-227) S100A7A PGLYRP3 GNLY BPI GNLY:bacterialanionic lipidsS100A7 Cu1+ ATOX1INTL1:bacterialglycanAnionic phospholipids DCDhexamer:Zn(2+):anionic phospholipidsZn2+L-Ala-gamma-D-Glu-L-Lys-D-AlaAnionic phospholipids CAMP(134-170):microbial cell surfaceFe2+ betaGlcNAcMicrobial cell surface PGLYRP4 2.5DHBA Microbial cell surface ADPRNASEs3,6,7,(8):anionicphospholipidsFe3+Anionic phospholipids DCD(63-110):anionicphospholipidLYZ:PGNNa+hC-EPPIN PLA2G2A:phospholipidsS100A7,S100A7A:Ca2+:Zn2+BPIFB6 KDO REG3G(38-175) Zn2+ CHGA(370-390) LCN2:2,5DHBA:Fe3+KDO beta-D-galactofuranosyl Mn2+ Mn2+PLA2G2A:Ca2+Microbial cellsurfaceHTN3 BPIFB4 SSA2 beta-D-galactofuranosyl Microbial cell surface LPS, PGNHTN1 Ca2+ GlcNAc(1-->4)MurNAc:L-Ala-gamma-D-Glu-L-Lys-(D-Ala)2 REG3A(27-37)/REG3G(27-37)Peptide Zn2+Zn2+ DCD(63-110) REG3A(38-175):anionic phospholipidsCHGA(19-94) PI3(61-117) PGLYRP2 LPS HTN3 ATP7A LCN2 hC-EPPIN GlcNAc(1-->4)MurNAc:L-Ala-gamma-D-Glu-L-Lys-(D-Ala)2 Microbial cell surface REG3G(27-37) LYZPLA2G2A heptose Fe3+HTN1,3,5DCD(20-62)MurNAc:PeptideHTN3(20-43) RNASE6 RNASEs3,6,7,(8):LPS,PGNLEAP2HTN1,3,5:bacterialphospholipidsREG3Ahexamer:anionicphospholipidPGLYRP1dimer:peptidoglycanSSA1,SSA2Ca2+ Zn2+ PRTN3 BPIFB6 LPS DCD(63-110) Ca2+ peptidoglycan-NHAc PiCa2+ HTN5,(HTN1, HTN3)2.5DHBA CHGA-derivedpeptide:bacterialanionic lipidsCHGA(370-390) LTF LEAP2 S100A8 RNASE3 hC239-SEMG1 REG3G(27-175) CAMP(134-170) Microbial cell surface Fe3+ BPIFA2 S100A7 GNLY Mn2+ Microbial cell surface Ca2+ ATPPDZD11 peptidoglycan-NHAc RNASE3 Microbial cell surface DCD(20-110)Microbial cell surface H2OEPPIN:SEMG1:LTF:CLUDCD(63-109) REG3A(27-37) RNASE8 BPIFB2 Microbial cell surface HTN3(20-43) PGLYRP1 dimerELANE DCD:anionicphospholipidNa+ Anionic phospholipids PI3(23-117) PLA2G2A RNASE3 ELANE, CTSG, PRTN3REG3G(38-175) Ca2+ BPIFA/BPIFBREG3A(38-175),REG3G(38-175):peptidoglycanMicrobial cell surface LEAP2:bacterialphospholipidsLTF PI3:LPSRNASE6 DCD(63-109)Microbial cell surface BPIFA/BPIFB:bacterial cellPGLYRP4 BPIFB1 CLU(228-449) ITLN1 HTN3(20-43) PGLYRP2 S100A7, S100A7A:Ca2+HTN5, (HTN1,HTN3):SSA1,SSA2BPIFB2 SLC11A1GlcNAc(1-->4)MurNAc:L-Ala-gamma-D-Glu-L-Lys-(D-Ala)2 Anionic phospholipids CLU(228-449) HTN1(31-57) H2OCa2+ Fe2+ PGLYRP2:peptidoglycanDivalent metalstransported byNRAMP1Divalent metalstransported byNRAMP1BPI:LPSAnionic phospholipids GlcNac-(1-->4)MurNAc-L-Ala-gamma-D-Glu-L-Lys-(D-Ala)2RNASE6 HTN1 LPS LYZ INTL1 ligandsCAMP(134-170)REG3A(38-175)CTSG CHGA fragmentsS100A9 Anionicphospholipids:microbial cell surfaceREG3A(38-175) HTN1(31-57) RNASE7 PRTN3PI3(61-117) LCN2 S100A9 unknown peptidaseMicrobial cell surface H+Microbial cell surface LPS LTF S100A9 PRSS3 S100A8 PRTN3 CAMP(31-170)S100A8:S100A9:Ca2+:Zn2+Microbial cell surface Anionic phospholipids DCD(63-110) EPC:bacterialsurfaceBPIFA1 CHGA(19-94) GlcNAc(1-->4)MurNAc:L-Ala-gamma-D-Glu-L-Lys-(D-Ala)2 PGLYRP1 PGLYRP3 11292183724268, 723232812138553, 14, 162922, 79711171118, 485414, 16, 30, 713, 14, 30, 7144, 48, 562, 22, 7948, 56


Description

Antimicrobial peptides (AMPs) are small molecular weight proteins with broad spectrum of antimicrobial activity against bacteria, viruses, and fungi (Zasloff M 2002; Radek K & Gallo R 2007). The majority of known AMPs are cationic peptides with common structural characteristics where domains of hydrophobic and cationic amino acids are spatially arranged into an amphipathic design, which facilitates their interaction with bacterial membranes (Shai Y 2002; Yeaman MR & Yount NY 2003; Brown KL & Hancock RE 2006; Dennison SR et al. 2005; Zelezetsky I & Tossi A 2006). It is generally excepted that the electrostatic interaction facilitates the initial binding of the positively charged peptides to the negatively charged bacterial membrane. Moreover, the structural amphiphilicity of AMPs is thought to promote their integration into lipid bilayers of pathogenic cells, leading to membrane disintegration and finally to the microbial cell death. In addition to cationic AMPs a few anionic antimicrobial peptides have been found in humans, however their mechanism of action remains to be clarified (Lai Y et al. 2007; Harris F et al. 2009; Paulmann M et al. 2012). Besides the direct neutralizing effects on bacteria AMPs may modulate cells of the adaptive immunity (neutrophils, T-cells, macrophages) to control inflammation and/or to increase bacterial clearance.

AMPs have also been referred to as cationic host defense peptides, anionic antimicrobial peptides/proteins, cationic amphipathic peptides, cationic AMPs, host defense peptides and alpha-helical antimicrobial peptides (Brown KL & Hancock RE 2006; Harris F et al. 2009; Groenink J et al. 1999; Bradshaw J 2003; Riedl S et al. 2011; Huang Y et al. 2010).<p>The Reactome module describes the interaction events of various types of human AMPs, such as cathelicidin, histatins and neutrophil serine proteases, with conserved patterns of microbial membranes at the host-pathogen interface. The module includes also proteolytic processing events for dermcidin (DCD) and cathelicidin (CAMP) that become functional upon cleavage. In addition, the module highlights an AMP-associated ability of the host to control metal quota at inflammation sites to influence host-pathogen interactions. View original pathway at Reactome.</div>

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Pathway is converted from Reactome ID: 6803157
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Reactome version: 73
Reactome Author 
Reactome Author: Shamovsky, Veronica

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Bibliography

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  1. Brodersen DE, Nyborg J, Kjeldgaard M.; ''Zinc-binding site of an S100 protein revealed. Two crystal structures of Ca2+-bound human psoriasin (S100A7) in the Zn2+-loaded and Zn2+-free states.''; PubMed Europe PMC Scholia
  2. Wesener DA, Wangkanont K, McBride R, Song X, Kraft MB, Hodges HL, Zarling LC, Splain RA, Smith DF, Cummings RD, Paulson JC, Forest KT, Kiessling LL.; ''Recognition of microbial glycans by human intelectin-1.''; PubMed Europe PMC Scholia
  3. Schindler M, Assaf Y, Sharon N, Chipman DM.; ''Mechanism of lysozyme catalysis: role of ground-state strain in subsite D in hen egg-white and human lysozymes.''; PubMed Europe PMC Scholia
  4. Sallenave JM.; ''Secretory leukocyte protease inhibitor and elafin/trappin-2: versatile mucosal antimicrobials and regulators of immunity.''; PubMed Europe PMC Scholia
  5. Weiss J, Elsbach P, Shu C, Castillo J, Grinna L, Horwitz A, Theofan G.; ''Human bactericidal/permeability-increasing protein and a recombinant NH2-terminal fragment cause killing of serum-resistant gram-negative bacteria in whole blood and inhibit tumor necrosis factor release induced by the bacteria.''; PubMed Europe PMC Scholia
  6. De Smet K, Contreras R.; ''Human antimicrobial peptides: defensins, cathelicidins and histatins.''; PubMed Europe PMC Scholia
  7. Birts CN, Barton CH, Wilton DC.; ''Catalytic and non-catalytic functions of human IIA phospholipase A2.''; PubMed Europe PMC Scholia
  8. Cho S, Wang Q, Swaminathan CP, Hesek D, Lee M, Boons GJ, Mobashery S, Mariuzza RA.; ''Structural insights into the bactericidal mechanism of human peptidoglycan recognition proteins.''; PubMed Europe PMC Scholia
  9. Bingle CD, Bingle L, Craven CJ.; ''Distant cousins: genomic and sequence diversity within the BPI fold-containing (BPIF)/PLUNC protein family.''; PubMed Europe PMC Scholia
  10. Yeaman MR, Yount NY.; ''Mechanisms of antimicrobial peptide action and resistance.''; PubMed Europe PMC Scholia
  11. Sørensen OE, Follin P, Johnsen AH, Calafat J, Tjabringa GS, Hiemstra PS, Borregaard N.; ''Human cathelicidin, hCAP-18, is processed to the antimicrobial peptide LL-37 by extracellular cleavage with proteinase 3.''; PubMed Europe PMC Scholia
  12. Tsuji S, Uehori J, Matsumoto M, Suzuki Y, Matsuhisa A, Toyoshima K, Seya T.; ''Human intelectin is a novel soluble lectin that recognizes galactofuranose in carbohydrate chains of bacterial cell wall.''; PubMed Europe PMC Scholia
  13. Radek KA, Lopez-Garcia B, Hupe M, Niesman IR, Elias PM, Taupenot L, Mahata SK, O'Connor DT, Gallo RL.; ''The neuroendocrine peptide catestatin is a cutaneous antimicrobial and induced in the skin after injury.''; PubMed Europe PMC Scholia
  14. Paulmann M, Arnold T, Linke D, Özdirekcan S, Kopp A, Gutsmann T, Kalbacher H, Wanke I, Schuenemann VJ, Habeck M, Bürck J, Ulrich AS, Schittek B.; ''Structure-activity analysis of the dermcidin-derived peptide DCD-1L, an anionic antimicrobial peptide present in human sweat.''; PubMed Europe PMC Scholia
  15. Damo SM, Kehl-Fie TE, Sugitani N, Holt ME, Rathi S, Murphy WJ, Zhang Y, Betz C, Hench L, Fritz G, Skaar EP, Chazin WJ.; ''Molecular basis for manganese sequestration by calprotectin and roles in the innate immune response to invading bacterial pathogens.''; PubMed Europe PMC Scholia
  16. Simanski M, Köten B, Schröder JM, Gläser R, Harder J.; ''Antimicrobial RNases in cutaneous defense.''; PubMed Europe PMC Scholia
  17. Oppenheim FG, Xu T, McMillian FM, Levitz SM, Diamond RD, Offner GD, Troxler RF.; ''Histatins, a novel family of histidine-rich proteins in human parotid secretion. Isolation, characterization, primary structure, and fungistatic effects on Candida albicans.''; PubMed Europe PMC Scholia
  18. Surna A, Kubilius R, Sakalauskiene J, Vitkauskiene A, Jonaitis J, Saferis V, Gleiznys A.; ''Lysozyme and microbiota in relation to gingivitis and periodontitis.''; PubMed Europe PMC Scholia
  19. Strupat K, Rogniaux H, Van Dorsselaer A, Roth J, Vogl T.; ''Calcium-induced noncovalently linked tetramers of MRP8 and MRP14 are confirmed by electrospray ionization-mass analysis.''; PubMed Europe PMC Scholia
  20. Wang ZM, Li X, Cocklin RR, Wang M, Wang M, Fukase K, Inamura S, Kusumoto S, Gupta D, Dziarski R.; ''Human peptidoglycan recognition protein-L is an N-acetylmuramoyl-L-alanine amidase.''; PubMed Europe PMC Scholia
  21. Mukherjee S, Partch CL, Lehotzky RE, Whitham CV, Chu H, Bevins CL, Gardner KH, Hooper LV.; ''Regulation of C-type lectin antimicrobial activity by a flexible N-terminal prosegment.''; PubMed Europe PMC Scholia
  22. Krause A, Sillard R, Kleemeier B, Klüver E, Maronde E, Conejo-García JR, Forssmann WG, Schulz-Knappe P, Nehls MC, Wattler F, Wattler S, Adermann K.; ''Isolation and biochemical characterization of LEAP-2, a novel blood peptide expressed in the liver.''; PubMed Europe PMC Scholia
  23. Rivas-Santiago B, Hernandez-Pando R, Carranza C, Juarez E, Contreras JL, Aguilar-Leon D, Torres M, Sada E.; ''Expression of cathelicidin LL-37 during Mycobacterium tuberculosis infection in human alveolar macrophages, monocytes, neutrophils, and epithelial cells.''; PubMed Europe PMC Scholia
  24. Korkmaz B, Moreau T, Gauthier F.; ''Neutrophil elastase, proteinase 3 and cathepsin G: physicochemical properties, activity and physiopathological functions.''; PubMed Europe PMC Scholia
  25. Torrent M, Badia M, Moussaoui M, Sanchez D, Nogués MV, Boix E.; ''Comparison of human RNase 3 and RNase 7 bactericidal action at the Gram-negative and Gram-positive bacterial cell wall.''; PubMed Europe PMC Scholia
  26. Cho JH, Fraser IP, Fukase K, Kusumoto S, Fujimoto Y, Stahl GL, Ezekowitz RA.; ''Human peptidoglycan recognition protein S is an effector of neutrophil-mediated innate immunity.''; PubMed Europe PMC Scholia
  27. Sugawara M, Resende JM, Moraes CM, Marquette A, Chich JF, Metz-Boutigue MH, Bechinger B.; ''Membrane structure and interactions of human catestatin by multidimensional solution and solid-state NMR spectroscopy.''; PubMed Europe PMC Scholia
  28. van der Does AM, Bergman P, Agerberth B, Lindbom L.; ''Induction of the human cathelicidin LL-37 as a novel treatment against bacterial infections.''; PubMed Europe PMC Scholia
  29. Yenugu S, Richardson RT, Sivashanmugam P, Wang Z, O'rand MG, French FS, Hall SH.; ''Antimicrobial activity of human EPPIN, an androgen-regulated, sperm-bound protein with a whey acidic protein motif.''; PubMed Europe PMC Scholia
  30. Haridas M, Anderson BF, Baker EN.; ''Structure of human diferric lactoferrin refined at 2.2 A resolution.''; PubMed Europe PMC Scholia
  31. León R, Murray JI, Cragg G, Farnell B, West NR, Pace TC, Watson PH, Bohne C, Boulanger MJ, Hof F.; ''Identification and characterization of binding sites on S100A7, a participant in cancer and inflammation pathways.''; PubMed Europe PMC Scholia
  32. Schittek B, Hipfel R, Sauer B, Bauer J, Kalbacher H, Stevanovic S, Schirle M, Schroeder K, Blin N, Meier F, Rassner G, Garbe C.; ''Dermcidin: a novel human antibiotic peptide secreted by sweat glands.''; PubMed Europe PMC Scholia
  33. Baechle D, Flad T, Cansier A, Steffen H, Schittek B, Tolson J, Herrmann T, Dihazi H, Beck A, Mueller GA, Mueller M, Stevanovic S, Garbe C, Mueller CA, Kalbacher H.; ''Cathepsin D is present in human eccrine sweat and involved in the postsecretory processing of the antimicrobial peptide DCD-1L.''; PubMed Europe PMC Scholia
  34. Rudolph B, Podschun R, Sahly H, Schubert S, Schröder JM, Harder J.; ''Identification of RNase 8 as a novel human antimicrobial protein.''; PubMed Europe PMC Scholia
  35. Flo TH, Smith KD, Sato S, Rodriguez DJ, Holmes MA, Strong RK, Akira S, Aderem A.; ''Lipocalin 2 mediates an innate immune response to bacterial infection by sequestrating iron.''; PubMed Europe PMC Scholia
  36. Zhang Y, van der Fits L, Voerman JS, Melief MJ, Laman JD, Wang M, Wang H, Wang M, Li X, Walls CD, Gupta D, Dziarski R.; ''Identification of serum N-acetylmuramoyl-l-alanine amidase as liver peptidoglycan recognition protein 2.''; PubMed Europe PMC Scholia
  37. Hodgkinson V, Petris MJ.; ''Copper homeostasis at the host-pathogen interface.''; PubMed Europe PMC Scholia
  38. Moreau T, Baranger K, Dadé S, Dallet-Choisy S, Guyot N, Zani ML.; ''Multifaceted roles of human elafin and secretory leukocyte proteinase inhibitor (SLPI), two serine protease inhibitors of the chelonianin family.''; PubMed Europe PMC Scholia
  39. Mukherjee S, Zheng H, Derebe MG, Callenberg KM, Partch CL, Rollins D, Propheter DC, Rizo J, Grabe M, Jiang QX, Hooper LV.; ''Antibacterial membrane attack by a pore-forming intestinal C-type lectin.''; PubMed Europe PMC Scholia
  40. Bingle CD, LeClair EE, Havard S, Bingle L, Gillingham P, Craven CJ.; ''Phylogenetic and evolutionary analysis of the PLUNC gene family.''; PubMed Europe PMC Scholia
  41. Kishi F, Nobumoto M.; ''Identification of natural resistance-associated macrophage protein in peripheral blood lymphocytes.''; PubMed Europe PMC Scholia
  42. Guan R, Roychowdury A, Ember B, Kumar S, Boons GJ, Mariuzza RA.; ''Crystal structure of a peptidoglycan recognition protein (PGRP) in complex with a muramyl tripeptide from Gram-positive bacteria.''; PubMed Europe PMC Scholia
  43. Lu X, Wang M, Qi J, Wang H, Li X, Gupta D, Dziarski R.; ''Peptidoglycan recognition proteins are a new class of human bactericidal proteins.''; PubMed Europe PMC Scholia
  44. Lehrer RI.; ''Primate defensins.''; PubMed Europe PMC Scholia
  45. Wang Z, Widgren EE, Richardson RT, O'Rand MG.; ''Characterization of an eppin protein complex from human semen and spermatozoa.''; PubMed Europe PMC Scholia
  46. Cash HL, Whitham CV, Behrendt CL, Hooper LV.; ''Symbiotic bacteria direct expression of an intestinal bactericidal lectin.''; PubMed Europe PMC Scholia
  47. Royet J, Dziarski R.; ''Peptidoglycan recognition proteins: pleiotropic sensors and effectors of antimicrobial defences.''; PubMed Europe PMC Scholia
  48. Kishi F.; ''Isolation and characterization of human Nramp cDNA.''; PubMed Europe PMC Scholia
  49. Becknell B, Eichler TE, Beceiro S, Li B, Easterling RS, Carpenter AR, James CL, McHugh KM, Hains DS, Partida-Sanchez S, Spencer JD.; ''Ribonucleases 6 and 7 have antimicrobial function in the human and murine urinary tract.''; PubMed Europe PMC Scholia
  50. Schittek B.; ''The multiple facets of dermcidin in cell survival and host defense.''; PubMed Europe PMC Scholia
  51. Wernimont AK, Huffman DL, Lamb AL, O'Halloran TV, Rosenzweig AC.; ''Structural basis for copper transfer by the metallochaperone for the Menkes/Wilson disease proteins.''; PubMed Europe PMC Scholia
  52. Gazzano-Santoro H, Parent JB, Grinna L, Horwitz A, Parsons T, Theofan G, Elsbach P, Weiss J, Conlon PJ.; ''High-affinity binding of the bactericidal/permeability-increasing protein and a recombinant amino-terminal fragment to the lipid A region of lipopolysaccharide.''; PubMed Europe PMC Scholia
  53. Pham CT.; ''Neutrophil serine proteases: specific regulators of inflammation.''; PubMed Europe PMC Scholia
  54. Spencer JD, Schwaderer AL, Wang H, Bartz J, Kline J, Eichler T, DeSouza KR, Sims-Lucas S, Baker P, Hains DS.; ''Ribonuclease 7, an antimicrobial peptide upregulated during infection, contributes to microbial defense of the human urinary tract.''; PubMed Europe PMC Scholia
  55. Rieg S, Seeber S, Steffen H, Humeny A, Kalbacher H, Stevanovic S, Kimura A, Garbe C, Schittek B.; ''Generation of multiple stable dermcidin-derived antimicrobial peptides in sweat of different body sites.''; PubMed Europe PMC Scholia
  56. Melino S, Santone C, Di Nardo P, Sarkar B.; ''Histatins: salivary peptides with copper(II)- and zinc(II)-binding motifs: perspectives for biomedical applications.''; PubMed Europe PMC Scholia
  57. Hayden JA, Brophy MB, Cunden LS, Nolan EM.; ''High-affinity manganese coordination by human calprotectin is calcium-dependent and requires the histidine-rich site formed at the dimer interface.''; PubMed Europe PMC Scholia
  58. Djoko KY, Ong CL, Walker MJ, McEwan AG.; ''The Role of Copper and Zinc Toxicity in Innate Immune Defense against Bacterial Pathogens.''; PubMed Europe PMC Scholia
  59. Medveczky P, Szmola R, Sahin-Tóth M.; ''Proteolytic activation of human pancreatitis-associated protein is required for peptidoglycan binding and bacterial aggregation.''; PubMed Europe PMC Scholia
  60. Elsbach P, Weiss J.; ''Role of the bactericidal/permeability-increasing protein in host defence.''; PubMed Europe PMC Scholia
  61. Burian M, Schittek B.; ''The secrets of dermcidin action.''; PubMed Europe PMC Scholia
  62. Campbell EJ, Silverman EK, Campbell MA.; ''Elastase and cathepsin G of human monocytes. Quantification of cellular content, release in response to stimuli, and heterogeneity in elastase-mediated proteolytic activity.''; PubMed Europe PMC Scholia
  63. McMichael JW, Roghanian A, Jiang L, Ramage R, Sallenave JM.; ''The antimicrobial antiproteinase elafin binds to lipopolysaccharide and modulates macrophage responses.''; PubMed Europe PMC Scholia
  64. Pulido D, Arranz-Trullén J, Prats-Ejarque G, Velázquez D, Torrent M, Moussaoui M, Boix E.; ''Insights into the Antimicrobial Mechanism of Action of Human RNase6: Structural Determinants for Bacterial Cell Agglutination and Membrane Permeation.''; PubMed Europe PMC Scholia
  65. Williams SE, Brown TI, Roghanian A, Sallenave JM.; ''SLPI and elafin: one glove, many fingers.''; PubMed Europe PMC Scholia
  66. Goetz DH, Holmes MA, Borregaard N, Bluhm ME, Raymond KN, Strong RK.; ''The neutrophil lipocalin NGAL is a bacteriostatic agent that interferes with siderophore-mediated iron acquisition.''; PubMed Europe PMC Scholia
  67. Jung HH, Yang ST, Sim JY, Lee S, Lee JY, Kim HH, Shin SY, Kim JI.; ''Analysis of the solution structure of the human antibiotic peptide dermcidin and its interaction with phospholipid vesicles.''; PubMed Europe PMC Scholia
  68. Murray JI, Tonkin ML, Whiting AL, Peng F, Farnell B, Cullen JT, Hof F, Boulanger MJ.; ''Structural characterization of S100A15 reveals a novel zinc coordination site among S100 proteins and altered surface chemistry with functional implications for receptor binding.''; PubMed Europe PMC Scholia
  69. Stapels DA, Geisbrecht BV, Rooijakkers SH.; ''Neutrophil serine proteases in antibacterial defense.''; PubMed Europe PMC Scholia
  70. Devireddy LR, Hart DO, Goetz DH, Green MR.; ''A mammalian siderophore synthesized by an enzyme with a bacterial homolog involved in enterobactin production.''; PubMed Europe PMC Scholia
  71. Gagnon DM, Brophy MB, Bowman SE, Stich TA, Drennan CL, Britt RD, Nolan EM.; ''Manganese binding properties of human calprotectin under conditions of high and low calcium: X-ray crystallographic and advanced electron paramagnetic resonance spectroscopic analysis.''; PubMed Europe PMC Scholia
  72. Henriques ST, Tan CC, Craik DJ, Clark RJ.; ''Structural and functional analysis of human liver-expressed antimicrobial peptide 2.''; PubMed Europe PMC Scholia
  73. Pepys MB, Hawkins PN, Booth DR, Vigushin DM, Tennent GA, Soutar AK, Totty N, Nguyen O, Blake CC, Terry CJ.; ''Human lysozyme gene mutations cause hereditary systemic amyloidosis.''; PubMed Europe PMC Scholia
  74. Ernst WA, Thoma-Uszynski S, Teitelbaum R, Ko C, Hanson DA, Clayberger C, Krensky AM, Leippe M, Bloom BR, Ganz T, Modlin RL.; ''Granulysin, a T cell product, kills bacteria by altering membrane permeability.''; PubMed Europe PMC Scholia
  75. Stenger S, Hanson DA, Teitelbaum R, Dewan P, Niazi KR, Froelich CJ, Ganz T, Thoma-Uszynski S, Melián A, Bogdan C, Porcelli SA, Bloom BR, Krensky AM, Modlin RL.; ''An antimicrobial activity of cytolytic T cells mediated by granulysin.''; PubMed Europe PMC Scholia
  76. Walch M, Eppler E, Dumrese C, Barman H, Groscurth P, Ziegler U.; ''Uptake of granulysin via lipid rafts leads to lysis of intracellular Listeria innocua.''; PubMed Europe PMC Scholia
  77. Boix E, Torrent M, Sánchez D, Nogués MV.; ''The antipathogen activities of eosinophil cationic protein.''; PubMed Europe PMC Scholia
  78. Anderson DH, Sawaya MR, Cascio D, Ernst W, Modlin R, Krensky A, Eisenberg D.; ''Granulysin crystal structure and a structure-derived lytic mechanism.''; PubMed Europe PMC Scholia
  79. Song C, Weichbrodt C, Salnikov ES, Dynowski M, Forsberg BO, Bechinger B, Steinem C, de Groot BL, Zachariae U, Zeth K.; ''Crystal structure and functional mechanism of a human antimicrobial membrane channel.''; PubMed Europe PMC Scholia
  80. Leukert N, Vogl T, Strupat K, Reichelt R, Sorg C, Roth J.; ''Calcium-dependent tetramer formation of S100A8 and S100A9 is essential for biological activity.''; PubMed Europe PMC Scholia
  81. Festa RA, Thiele DJ.; ''Copper at the front line of the host-pathogen battle.''; PubMed Europe PMC Scholia
  82. Lehotzky RE, Partch CL, Mukherjee S, Cash HL, Goldman WE, Gardner KH, Hooper LV.; ''Molecular basis for peptidoglycan recognition by a bactericidal lectin.''; PubMed Europe PMC Scholia
  83. Elsbach P.; ''The bactericidal/permeability-increasing protein (BPI) in antibacterial host defense.''; PubMed Europe PMC Scholia
  84. Korndörfer IP, Brueckner F, Skerra A.; ''The crystal structure of the human (S100A8/S100A9)2 heterotetramer, calprotectin, illustrates how conformational changes of interacting alpha-helices can determine specific association of two EF-hand proteins.''; PubMed Europe PMC Scholia
  85. Bingle CD, Craven CJ.; ''PLUNC: a novel family of candidate host defence proteins expressed in the upper airways and nasopharynx.''; PubMed Europe PMC Scholia
  86. Bahar AA, Ren D.; ''Antimicrobial peptides.''; PubMed Europe PMC Scholia

History

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CompareRevisionActionTimeUserComment
114972view16:50, 25 January 2021ReactomeTeamReactome version 75
113416view11:49, 2 November 2020ReactomeTeamReactome version 74
112618view15:59, 9 October 2020ReactomeTeamReactome version 73
101534view11:40, 1 November 2018ReactomeTeamreactome version 66
101069view21:22, 31 October 2018ReactomeTeamreactome version 65
100599view19:56, 31 October 2018ReactomeTeamreactome version 64
100149view16:41, 31 October 2018ReactomeTeamreactome version 63
99699view15:10, 31 October 2018ReactomeTeamreactome version 62 (2nd attempt)
99284view12:46, 31 October 2018ReactomeTeamreactome version 62
93538view11:26, 9 August 2017ReactomeTeamNew pathway

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NameTypeDatabase referenceComment
(GlcNAc+MurNac)nR-ALL-6799970 (Reactome)
2.5DHBA MetaboliteCHEBI:17189 (ChEBI)
ADPMetaboliteCHEBI:456216 (ChEBI)
ATOX1 ProteinO00244 (Uniprot-TrEMBL)
ATOX1:Cu1+ComplexR-HSA-3697875 (Reactome)
ATOX1ProteinO00244 (Uniprot-TrEMBL)
ATP7A ProteinQ04656 (Uniprot-TrEMBL)
ATP7A:PDZD11ComplexR-HSA-6803541 (Reactome)
ATPMetaboliteCHEBI:30616 (ChEBI)
Anionic phospholipids:microbial cell surfaceComplexR-ALL-8931784 (Reactome)
Anionic phospholipids MetaboliteCHEBI:62643 (ChEBI)
BPI ProteinP17213 (Uniprot-TrEMBL)
BPI:LPSComplexR-HSA-6807590 (Reactome)
BPIFA/BPIFB:bacterial cellComplexR-HSA-6809519 (Reactome)
BPIFA/BPIFBComplexR-HSA-6809283 (Reactome)
BPIFA1 ProteinQ9NP55 (Uniprot-TrEMBL)
BPIFA2 ProteinQ96DR5 (Uniprot-TrEMBL)
BPIFB1 ProteinQ8TDL5 (Uniprot-TrEMBL)
BPIFB2 ProteinQ8N4F0 (Uniprot-TrEMBL)
BPIFB4 ProteinP59827 (Uniprot-TrEMBL)
BPIFB6 ProteinQ8NFQ5 (Uniprot-TrEMBL)
BPIProteinP17213 (Uniprot-TrEMBL)
CAMP(134-170) ProteinP49913 (Uniprot-TrEMBL)
CAMP(134-170):microbial cell surfaceComplexR-HSA-8879163 (Reactome)
CAMP(134-170)ProteinP49913 (Uniprot-TrEMBL)
CAMP(31-170)ProteinP49913 (Uniprot-TrEMBL)
CHGA fragmentsComplexR-HSA-6808534 (Reactome)
CHGA(19-94) ProteinP10645 (Uniprot-TrEMBL)
CHGA(370-390) ProteinP10645 (Uniprot-TrEMBL)
CHGA-derived

peptide:bacterial

anionic lipids
ComplexR-HSA-6808558 (Reactome)
CLU(228-449) ProteinP10909 (Uniprot-TrEMBL)
CLU(23-227) ProteinP10909 (Uniprot-TrEMBL)
CO3(2-) MetaboliteCHEBI:41609 (ChEBI)
CO3(2-)MetaboliteCHEBI:41609 (ChEBI)
CTSG ProteinP08311 (Uniprot-TrEMBL) After secretion Cathepsin G is extracellular and associated with the plasma membrane.
Ca2+ MetaboliteCHEBI:29108 (ChEBI)
Cu1+ MetaboliteCHEBI:49552 (ChEBI)
Cu1+MetaboliteCHEBI:49552 (ChEBI)
DCD hexamer:Zn(2+):anionic phospholipidsComplexR-HSA-6803105 (Reactome)
DCD peptidesComplexR-HSA-6803037 (Reactome)
DCD(20-110)ProteinP81605 (Uniprot-TrEMBL)
DCD(20-62)ProteinP81605 (Uniprot-TrEMBL)
DCD(63-109) ProteinP81605 (Uniprot-TrEMBL)
DCD(63-109)ProteinP81605 (Uniprot-TrEMBL)
DCD(63-110) ProteinP81605 (Uniprot-TrEMBL)
DCD(63-110):anionic phospholipidComplexR-HSA-6803024 (Reactome)
DCD(63-110)ProteinP81605 (Uniprot-TrEMBL)
DCD:anionic phospholipidComplexR-HSA-6803066 (Reactome)
DefensinsPathwayR-HSA-1461973 (Reactome) The defensins are a family of antimicrobial cationic peptide molecules which in mammals have a characteristic beta-sheet-rich fold and framework of six disulphide-linked cysteines (Selsted & Ouellette 2005, Ganz 2003). Human defensin peptides have two subfamilies, alpha- and beta-defensins, differing in the length of peptide chain between the six cysteines and the order of disulphide bond pairing between them. A third subfamily, the theta defensins, is derived from alpha-defensins prematurely truncated by a stop codon between the third and fourth cysteine residues. The translated products are shortened to nonapeptides, covalently dimerized by disulfide linkages, and cyclized via new peptide bonds between the first and ninth residues. Humans have one pseudogene but no translated representatives of the theta class.
In solution most alpha and beta defensins are monomers but can form dimers and higher order structures.

The primary cellular sources of defensins are neutrophils, epithelial cells and intestinal Paneth cells.Those expressed in neutrophils and the gut are predominantly constitutive, while those in epithelial tissues such as skin are often inducible by proinflammatory stimuli such as LPS or TNF-alpha.

Defensins are translated as precursor polypeptides that include a typical signal peptide or prepiece that is cleaved in the Golgi body, and a propiece, cleaved by differing mechanisms to produce the mature defensin. Mature defensin peptides can be further processed by removal of individual N-terminal residues (Yang et al. 2004). This may be a mechanism to broaden the activity profile of defensins (Ghosh et al. 2002).

Defensins have direct antimicrobial effects and kill a wide range of Gram-positive and negative bacteria, fungi and some viruses. The primary antimicrobial action of defensins is permeabilization of microbial target membranes but several additional mechanisms have been suggested (Brogden 2005, Wilmes et al. 2011). Defensins and related antimicrobial peptides such as cathelicidin bridge the innate and acquired immune responses. In addition to their antimicrobial properties, cathelicidin and several defensins show receptor-mediated chemotactic activity for immune cells such as monocytes, T cells or immature DCs, induce cytokine production by monocytes and epithelial cells, modulate angiogenesis and stimulate wound healing (Yang et al. 1999, 2000, 2004, Rehaume & Hancock 2008, Yeung et al. 2011).
Divalent metals

transported by

NRAMP1
ComplexR-ALL-445829 (Reactome)
Divalent metals

transported by

NRAMP1
ComplexR-ALL-445832 (Reactome)
ELANE ProteinP08246 (Uniprot-TrEMBL)
ELANE, CTSG, PRTN3ComplexR-HSA-6813639 (Reactome)
ELANE,CTSG,

PRTN3:microbial

cell surface
ComplexR-HSA-6813664 (Reactome)
EPC:bacterial surfaceComplexR-HSA-6810673 (Reactome)
EPPIN:SEMG1:LTF:CLUComplexR-HSA-6810613 (Reactome)
Fe2+ MetaboliteCHEBI:29033 (ChEBI)
Fe3+ MetaboliteCHEBI:29034 (ChEBI)
Fe3+MetaboliteCHEBI:29034 (ChEBI)
GNLY ProteinP22749 (Uniprot-TrEMBL)
GNLY:bacterial anionic lipidsComplexR-HSA-6806759 (Reactome)
GNLY:bacterial anionic lipidsComplexR-HSA-8858201 (Reactome)
GNLYProteinP22749 (Uniprot-TrEMBL)
GlcNAc(1-->4)MurNAc:L-Ala-gamma-D-Glu-L-Lys-(D-Ala)2 R-ALL-6788957 (Reactome)
GlcNac-(1-->4)MurNAc-L-Ala-gamma-D-Glu-L-Lys-(D-Ala)2 MetaboliteCHEBI:55424 (ChEBI) In Staphylococcus aureus, the pentapeptide coming off the N-acetyl muramic acid is composed of the amino acids L-alanine, D-glutamine, L-lysine, and two D-alanines.
GlcNac-(1-->4)MurNAc-L-Ala-gamma-D-Glu-L-Lys-(D-Ala)2MetaboliteCHEBI:55424 (ChEBI) In Staphylococcus aureus, the pentapeptide coming off the N-acetyl muramic acid is composed of the amino acids L-alanine, D-glutamine, L-lysine, and two D-alanines.
H+MetaboliteCHEBI:15378 (ChEBI)
H2OMetaboliteCHEBI:15377 (ChEBI)
HTN1 ProteinP15515 (Uniprot-TrEMBL)
HTN1(31-57) ProteinP15515 (Uniprot-TrEMBL)
HTN1,3,5:bacterial phospholipidsComplexR-HSA-6807169 (Reactome)
HTN1,3,5ComplexR-HSA-6807193 (Reactome)
HTN3 ProteinP15516 (Uniprot-TrEMBL)
HTN3(20-43) ProteinP15516 (Uniprot-TrEMBL)
HTN5, (HTN1, HTN3):SSA1,SSA2ComplexR-HSA-6807587 (Reactome)
HTN5,(HTN1, HTN3)ComplexR-HSA-6807573 (Reactome)
INTL1 ligandsComplexR-ALL-6804535 (Reactome)
INTL1:bacterial glycanComplexR-HSA-6804513 (Reactome)
ITLN1 ProteinQ8WWA0 (Uniprot-TrEMBL)
ITLN1 trimer:Ca2+ComplexR-HSA-6804509 (Reactome)
KDO MetaboliteCHEBI:85986 (ChEBI)
L-Ala-gamma-D-Glu-L-Lys-D-AlaMetaboliteCHEBI:61626 (ChEBI)
LCN2 ProteinP80188 (Uniprot-TrEMBL)
LCN2:2,5DHBA:Fe3+ComplexR-HSA-5229238 (Reactome)
LCN2:2,5DHBAComplexR-HSA-5229290 (Reactome)
LEAP2 ProteinQ969E1 (Uniprot-TrEMBL)
LEAP2:bacterial phospholipidsComplexR-HSA-6813633 (Reactome)
LEAP2ProteinQ969E1 (Uniprot-TrEMBL)
LPS MetaboliteCHEBI:16412 (ChEBI)
LPS, PGNComplexR-ALL-6803074 (Reactome)
LPSMetaboliteCHEBI:16412 (ChEBI)
LTF ProteinP02788 (Uniprot-TrEMBL)
LTF:2xFe3+:2xCO3(2-)ComplexR-HSA-1222432 (Reactome)
LTFProteinP02788 (Uniprot-TrEMBL)
LYZ ProteinP61626 (Uniprot-TrEMBL)
LYZ:PGNComplexR-HSA-8862293 (Reactome)
LYZProteinP61626 (Uniprot-TrEMBL)
Microbial cell surfaceR-ALL-8879165 (Reactome) This entity is intended to represent any molecule that might be at the outer cell surface of a microbial cell
Microbial cell surface R-ALL-8879165 (Reactome) This entity is intended to represent any molecule that might be at the outer cell surface of a microbial cell
Mn2+ MetaboliteCHEBI:29035 (ChEBI)
Mn2+MetaboliteCHEBI:29035 (ChEBI)
MurNAc MetaboliteCHEBI:21615 (ChEBI)
MurNAc:PeptideComplexR-ALL-6788991 (Reactome)
Na+ MetaboliteCHEBI:29101 (ChEBI)
Na+MetaboliteCHEBI:29101 (ChEBI)
PDZD11 ProteinQ5EBL8 (Uniprot-TrEMBL)
PGLYRP1 ProteinO75594 (Uniprot-TrEMBL)
PGLYRP1 dimerComplexR-HSA-6789200 (Reactome)
PGLYRP1dimer:peptidoglycanComplexR-HSA-6789175 (Reactome)
PGLYRP2 ProteinQ96PD5 (Uniprot-TrEMBL)
PGLYRP2 dimerComplexR-HSA-8933468 (Reactome)
PGLYRP2:peptidoglycanComplexR-HSA-6799988 (Reactome)
PGLYRP3 ProteinQ96LB9 (Uniprot-TrEMBL)
PGLYRP3,4 dimer:peptidoglycanComplexR-HSA-6799966 (Reactome)
PGLYRP3,4 dimersComplexR-HSA-6799960 (Reactome)
PGLYRP4 ProteinQ96LB8 (Uniprot-TrEMBL)
PI3(23-117) ProteinP19957 (Uniprot-TrEMBL)
PI3(61-117) ProteinP19957 (Uniprot-TrEMBL)
PI3:LPSComplexR-HSA-6810759 (Reactome)
PI3ComplexR-HSA-6810794 (Reactome)
PLA2G2A ProteinP14555 (Uniprot-TrEMBL)
PLA2G2A:Ca2+ComplexR-HSA-1602363 (Reactome)
PLA2G2A:phospholipidsComplexR-HSA-8862769 (Reactome)
PRSS2(24-247) ProteinP07478 (Uniprot-TrEMBL)
PRSS3 ProteinP35030 (Uniprot-TrEMBL)
PRTN3 ProteinP24158 (Uniprot-TrEMBL)
PRTN3ProteinP24158 (Uniprot-TrEMBL)
Peptide MetaboliteCHEBI:16670 (ChEBI)
PiMetaboliteCHEBI:18367 (ChEBI)
REG3A

hexamer:anionic

phospholipid
ComplexR-HSA-6801795 (Reactome)
REG3A(27-175) ProteinQ06141 (Uniprot-TrEMBL)
REG3A(27-175)/REG3G(27-175)ComplexR-HSA-6801779 (Reactome)
REG3A(27-37) ProteinQ06141 (Uniprot-TrEMBL)
REG3A(27-37)/REG3G(27-37)ComplexR-HSA-6801797 (Reactome)
REG3A(38-175) ProteinQ06141 (Uniprot-TrEMBL)
REG3A(38-175), REG3G(38-175):peptidoglycanComplexR-HSA-6801809 (Reactome)
REG3A(38-175), REG3G(38-175)ComplexR-HSA-6801794 (Reactome)
REG3A(38-175):anionic phospholipidsComplexR-HSA-6801804 (Reactome)
REG3A(38-175)ProteinQ06141 (Uniprot-TrEMBL)
REG3G(27-175) ProteinQ6UW15 (Uniprot-TrEMBL)
REG3G(27-37) ProteinQ6UW15 (Uniprot-TrEMBL)
REG3G(38-175) ProteinQ6UW15 (Uniprot-TrEMBL)
RNASE3 ProteinP12724 (Uniprot-TrEMBL)
RNASE3,RNASE7,RNASE6,(RNASE8)ComplexR-HSA-6803116 (Reactome)
RNASE6 ProteinQ93091 (Uniprot-TrEMBL)
RNASE7 ProteinQ9H1E1 (Uniprot-TrEMBL)
RNASE8 ProteinQ8TDE3 (Uniprot-TrEMBL)
RNASEs 3,6,7,(8):LPS,PGNComplexR-HSA-6803051 (Reactome)
RNASEs

3,6,7,(8):anionic

phospholipids
ComplexR-HSA-8948028 (Reactome)
S100A7 ProteinP31151 (Uniprot-TrEMBL)
S100A7, S100A7A:Ca2+:Zn2+ComplexR-HSA-6798500 (Reactome)
S100A7, S100A7A:Ca2+ComplexR-HSA-6798557 (Reactome)
S100A7A ProteinQ86SG5 (Uniprot-TrEMBL)
S100A8 ProteinP05109 (Uniprot-TrEMBL)
S100A8:S100A9:Ca2+:Mn2+:Na+ComplexR-HSA-6798411 (Reactome)
S100A8:S100A9:Ca2+:Zn2+ComplexR-HSA-8944189 (Reactome)
S100A8:S100A9:Ca2+ComplexR-HSA-8944198 (Reactome)
S100A9 ProteinP06702 (Uniprot-TrEMBL)
SLC11A1ProteinP49279 (Uniprot-TrEMBL)
SSA1 ProteinP41797 (Uniprot-TrEMBL)
SSA1,SSA2ComplexR-CAL-6807575 (Reactome)
SSA2 ProteinP46587 (Uniprot-TrEMBL)
Trypsin 2, 3ComplexR-HSA-1460242 (Reactome)
Zn2+ MetaboliteCHEBI:29105 (ChEBI)
Zn2+MetaboliteCHEBI:29105 (ChEBI)
beta-D-galactofuranosyl MetaboliteCHEBI:59496 (ChEBI)
betaGlcNAcMetaboliteCHEBI:28009 (ChEBI)
hC-EPPIN ProteinO95925 (Uniprot-TrEMBL)
hC239-SEMG1 ProteinP04279 (Uniprot-TrEMBL)
heptose MetaboliteCHEBI:42976 (ChEBI)
peptidoglycan-NHAc R-ALL-6788960 (Reactome)
unknown peptidaseR-HSA-3076903 (Reactome)

Annotated Interactions

View all...
SourceTargetTypeDatabase referenceComment
(GlcNAc+MurNac)nArrowR-HSA-6799977 (Reactome)
ADPArrowR-HSA-6803545 (Reactome)
ATOX1:Cu1+R-HSA-6803545 (Reactome)
ATOX1ArrowR-HSA-6803545 (Reactome)
ATP7A:PDZD11mim-catalysisR-HSA-6803545 (Reactome)
ATPR-HSA-6803545 (Reactome)
Anionic phospholipids:microbial cell surfaceR-HSA-6801776 (Reactome)
Anionic phospholipids:microbial cell surfaceR-HSA-6803047 (Reactome)
Anionic phospholipids:microbial cell surfaceR-HSA-6806732 (Reactome)
Anionic phospholipids:microbial cell surfaceR-HSA-6807144 (Reactome)
Anionic phospholipids:microbial cell surfaceR-HSA-6807578 (Reactome)
Anionic phospholipids:microbial cell surfaceR-HSA-6808566 (Reactome)
Anionic phospholipids:microbial cell surfaceR-HSA-6813626 (Reactome)
Anionic phospholipids:microbial cell surfaceR-HSA-8862771 (Reactome)
Anionic phospholipids:microbial cell surfaceR-HSA-8948027 (Reactome)
BPI:LPSArrowR-HSA-6807585 (Reactome)
BPIFA/BPIFB:bacterial cellArrowR-HSA-6809521 (Reactome)
BPIFA/BPIFBR-HSA-6809521 (Reactome)
BPIR-HSA-6807585 (Reactome)
CAMP(134-170):microbial cell surfaceArrowR-HSA-1222685 (Reactome)
CAMP(134-170)ArrowR-HSA-6801687 (Reactome)
CAMP(134-170)R-HSA-1222685 (Reactome)
CAMP(31-170)R-HSA-6801687 (Reactome)
CHGA fragmentsR-HSA-6808566 (Reactome)
CHGA-derived

peptide:bacterial

anionic lipids
ArrowR-HSA-6808566 (Reactome)
CO3(2-)R-HSA-1222491 (Reactome)
Cu1+ArrowR-HSA-6803545 (Reactome)
DCD hexamer:Zn(2+):anionic phospholipidsArrowR-HSA-6803104 (Reactome)
DCD peptidesR-HSA-6803047 (Reactome)
DCD(20-110)R-HSA-6802999 (Reactome)
DCD(20-62)ArrowR-HSA-6802999 (Reactome)
DCD(63-109)ArrowR-HSA-6803060 (Reactome)
DCD(63-110):anionic phospholipidR-HSA-6803104 (Reactome)
DCD(63-110)ArrowR-HSA-6802999 (Reactome)
DCD(63-110)R-HSA-6803060 (Reactome)
DCD:anionic phospholipidArrowR-HSA-6803047 (Reactome)
Divalent metals

transported by

NRAMP1
ArrowR-HSA-435171 (Reactome)
Divalent metals

transported by

NRAMP1
R-HSA-435171 (Reactome)
ELANE, CTSG, PRTN3R-HSA-6813659 (Reactome)
ELANE,CTSG,

PRTN3:microbial

cell surface
ArrowR-HSA-6813659 (Reactome)
EPC:bacterial surfaceArrowR-HSA-6810643 (Reactome)
EPPIN:SEMG1:LTF:CLUR-HSA-6810643 (Reactome)
Fe3+R-HSA-1222491 (Reactome)
Fe3+R-HSA-5229273 (Reactome)
GNLY:bacterial anionic lipidsArrowR-HSA-6806732 (Reactome)
GNLY:bacterial anionic lipidsArrowR-HSA-6807578 (Reactome)
GNLYArrowR-HSA-6807565 (Reactome)
GNLYR-HSA-6806732 (Reactome)
GNLYR-HSA-6807565 (Reactome)
GNLYR-HSA-6807578 (Reactome)
GlcNac-(1-->4)MurNAc-L-Ala-gamma-D-Glu-L-Lys-(D-Ala)2R-HSA-6789072 (Reactome)
GlcNac-(1-->4)MurNAc-L-Ala-gamma-D-Glu-L-Lys-(D-Ala)2R-HSA-6799959 (Reactome)
GlcNac-(1-->4)MurNAc-L-Ala-gamma-D-Glu-L-Lys-(D-Ala)2R-HSA-6799981 (Reactome)
GlcNac-(1-->4)MurNAc-L-Ala-gamma-D-Glu-L-Lys-(D-Ala)2R-HSA-6801808 (Reactome)
GlcNac-(1-->4)MurNAc-L-Ala-gamma-D-Glu-L-Lys-(D-Ala)2R-HSA-8862300 (Reactome)
H+ArrowR-HSA-435171 (Reactome)
H+R-HSA-435171 (Reactome)
H2OR-HSA-6799977 (Reactome)
H2OR-HSA-6803545 (Reactome)
H2OR-HSA-8862320 (Reactome)
HTN1,3,5:bacterial phospholipidsArrowR-HSA-6807144 (Reactome)
HTN1,3,5R-HSA-6807144 (Reactome)
HTN5, (HTN1, HTN3):SSA1,SSA2ArrowR-HSA-6807581 (Reactome)
HTN5,(HTN1, HTN3)R-HSA-6807581 (Reactome)
INTL1 ligandsR-HSA-6804527 (Reactome)
INTL1:bacterial glycanArrowR-HSA-6804527 (Reactome)
ITLN1 trimer:Ca2+R-HSA-6804527 (Reactome)
L-Ala-gamma-D-Glu-L-Lys-D-AlaArrowR-HSA-6799977 (Reactome)
LCN2:2,5DHBA:Fe3+ArrowR-HSA-5229273 (Reactome)
LCN2:2,5DHBAR-HSA-5229273 (Reactome)
LEAP2:bacterial phospholipidsArrowR-HSA-6813626 (Reactome)
LEAP2R-HSA-6813626 (Reactome)
LPS, PGNR-HSA-6803063 (Reactome)
LPSR-HSA-6807585 (Reactome)
LPSR-HSA-6810724 (Reactome)
LPSTBarR-HSA-6801762 (Reactome)
LTF:2xFe3+:2xCO3(2-)ArrowR-HSA-1222491 (Reactome)
LTFR-HSA-1222491 (Reactome)
LYZ:PGNArrowR-HSA-8862300 (Reactome)
LYZ:PGNR-HSA-8862320 (Reactome)
LYZ:PGNmim-catalysisR-HSA-8862320 (Reactome)
LYZR-HSA-8862300 (Reactome)
Microbial cell surfaceR-HSA-1222685 (Reactome)
Microbial cell surfaceR-HSA-6809521 (Reactome)
Microbial cell surfaceR-HSA-6810643 (Reactome)
Microbial cell surfaceR-HSA-6813659 (Reactome)
Mn2+R-HSA-6798528 (Reactome)
MurNAc:PeptideArrowR-HSA-8862320 (Reactome)
Na+R-HSA-6798528 (Reactome)
PGLYRP1 dimerR-HSA-6789072 (Reactome)
PGLYRP1dimer:peptidoglycanArrowR-HSA-6789072 (Reactome)
PGLYRP2 dimerArrowR-HSA-6799977 (Reactome)
PGLYRP2 dimerR-HSA-6799981 (Reactome)
PGLYRP2 dimermim-catalysisR-HSA-6799977 (Reactome)
PGLYRP2:peptidoglycanArrowR-HSA-6799981 (Reactome)
PGLYRP2:peptidoglycanR-HSA-6799977 (Reactome)
PGLYRP3,4 dimer:peptidoglycanArrowR-HSA-6799959 (Reactome)
PGLYRP3,4 dimersR-HSA-6799959 (Reactome)
PI3:LPSArrowR-HSA-6810724 (Reactome)
PI3R-HSA-6810724 (Reactome)
PLA2G2A:Ca2+R-HSA-8862771 (Reactome)
PLA2G2A:phospholipidsArrowR-HSA-8862771 (Reactome)
PRTN3mim-catalysisR-HSA-6801687 (Reactome)
PiArrowR-HSA-6803545 (Reactome)
R-HSA-1222491 (Reactome) Lactoferrin is secreted from many tissues to collect stray iron ions that can catalyze unwanted reactions, and to starve microorganisms of this important metal. One molecule of lactoferrin can load two ferric (Fe(3+)) ions together with two carbonate (CO3(2-)) anions (Haridas et al. 1995).
R-HSA-1222685 (Reactome) Human cathelicidin antimicrobial peptide (hCAP18, also known as CAMP) is synthesized as 18-kDa pro-protein (Sorensen O et al. 1997, 2001; Yang D et al. 2000; Mendez-Samperio P 2010). The proform hCAP18 is stored within vesicles such as specific granules of neutrophils. Upon inflammation or injury hCAP18 undergoes proteolytic cleavage to produce the mature antimicrobial 37-amino acid-long peptide LL-37 (CAMP(134-170)) which is secreted outside the cells (Sorensen O et al. 1997, 2001; Yang D et al. 2000; Mendez-Samperio P 2010). LL-37 has a net positive charge and is thought to interact with bacteria via electrostatic attraction toward the negatively charged bacterial membrane (Wang G et al. 2012, 2014; Kuroda K et al. 2015). LL-37 is amphiphilic in nature and is comprised of hydrophobic and hydrophilic residues aligned on opposite sides of the peptide (Braff MH et al. 2005; Wang G 2008; Wang G et al. 2012, 2014). The hydrophobic domain may facilitate the peptide penetration through phospholipid bilayers of bacteria (Shai Y 1999).

LL-37 has direct microbicidal activities against Gram-positive bacteria (S. aureus, Group A Streptococcus, Bacillus megaterium), Gram-negative bacteria (E. coli, P. aeruginosa, Salmonella minnesota) and fungi such as C. albicans (Yang D et al. 2000; Nagaoka I et al. 2005; Braff MH et al. 2005; Wang G et al. 2012). LL-37 also has antiviral activities against herpes simplex virus, HIV-1, and vaccinia virus (Yasin B et al. 2000; Steinstraesser L et al. 2005; Howell MD et al. 2006; Gordon YJ et al. 2005). LL-37 may have the potential to prevent sepsis or septic shock associated with pathogenic bacterial infection by inhibiting the release of toxic components such as LPS and lipoteichoic acid (LTA) that cause excess tissue damage and inflammation (Larrick JW et al. 1995)

LL-37 expression was found to correlate with an activation of TLR2, TLR4 and TLR9 signaling pathways in M. tuberculosis-stimulatied human monocyte-derived macrophages, alveolar macrophages and neutrophils (Rivas-Santiago et al. 2008).

R-HSA-435171 (Reactome) Natural resistance-associated macrophage proteins (NRAMPs) regulate macrophage activation for antimicrobial activity against intracellular pathogens. They do this by mediating bivalent metal ion transport across macrophage membranes and the subsequent use of these ions in the Fenton/and or Haber–Weiss reactions of free radical formation.
The human gene SLC11A1 encodes NRAMP1 (Kishi F, 2004; Kishi F and Nobumoto M, 1995) which can utilize the protonmotive force to mediate divalent iron (Fe2+), zinc (Zn2+) and manganese (Mn2+) influx to or efflux from phagosomes.
R-HSA-5229273 (Reactome) Neutrophil gelatinase associated lipocalin (LCN2, NGAL) is a member of the lipocalin superfamily that is involved in iron trafficking both in and out of cells. LCN2 binds iron via an association with 2,5 dihydroxybenzoic acid (2,5DHBA), a siderophore that shares structural similarities with bacterial enterobactin, and delivers or removes iron from the cell via interacting with different receptors, depending on cellular requirement (Goetz et al. 2002, Devireddy et al. 2010). LCN2 is a potent bacteriostatic agent in iron limiting conditions therefore it is proposed that LCN2 participates in the antibacterial iron depletion strategy of the innate immune system (Flo et al. 2004).
R-HSA-6789072 (Reactome) Peptidoglycan recognition proteins (PGRPs or PGLYRPs) are innate immunity molecules that contain a conserved peptidoglycan-binding type 2 amidase domain that is homologous to bacteriophage and bacterial type 2 amidases (Kang D et al. 1998; Liu C et al. 2001; Royet J and Dziarski R 2007; Royet J et al. 2011; Dziarski R et al. 2016). Mammals have a family of four PGRPs (PGLYRP1, 2, 3 & 4) that are differentially expressed in a cell‑type‑ or tissue‑specific manner. Human PGLYRP1 (also known as PGRP‑S) is constitutively expressed primarily in polymorphonuclear (PMN) cell granules and functions as disulfide‑linked homodimers (Liu C et al. 2000, 2001; Cho JH et al. 2005; Guan R et al. 2005; Lu X et al. 2006; De Marzi MC et al. 2015). PGLYRP1 has a Zn(2+)-dependent bactericidal activity against both Gram-positive and Gram-negative bacteria at physiologic Zn(2+) concentrations found in the body fluids (Lu X et al. 2006; Wang M et al. 2007). PGLYRP1 is also active against Chlamydia trachomatis (Bobrovsky P et al. 2016). Killing of both Gram-positive and Gram-negative bacteria by PGLYRP1 is synergistically enhanced by antimicrobial peptides (phospholipase A2, alpha- and beta-defensins, and bactericidal permeability-increasing protein (BPI)) (Wang M et al. 2007), and also by lysozyme (Cho JH et al. 2005). The bactericidal activity of PGRPs requires their N-glycosylation, because deglycosylation with N-glycosidase abolished the bactericidal activity of these PGRPs for Bacillus subtilis, Staphylococcus aureus, and Escherichia coli (Lu X et al. 2006; Wang M et al. 2007).

PGRPs are thought to kill bacteria by interacting with cell wall peptidoglycan and by inducing lethal stress response in bacteria, rather than a hydrolysis of peptidoglycan or permeabilizing bacterial membranes as other antibacterial peptides do (Lu X et al. 2006; Wang M et al. 2007; Cho S et al. 2007; Kashyap DR et al. 2011, 2014). In Gram-positive bacteria, including B. subtilis, PGLYRP1, 3 & 4 were found to enter cell wall at the site of daughter cell separation during cell division and to bind to cell wall peptidoglycan in the vicinity of cell membrane (Kashyap DR et al. 2011). However, this binding did not inhibit the extracellular transglycosylation or transpeptidation steps in peptidoglycan synthesis (Kashyap DR et al. 2011), which are well-known targets for bactericidal antibiotics. Instead, this interaction of PGRP proteins and peptidoglycan activated the B. subtilis envelope stress response CssR‑CssS two-component system that detects and disposes of misfolded proteins exported out of bacterial cells. This activation resulted in bacterial membrane depolarization, cessation of intracellular peptidoglycan, protein, RNA, and DNA synthesis, and production of toxic hydroxyl radicals, which were responsible for bacterial death (Kashyap DR et al. 2011). PGRPs were shown to kill Gram-negative bacteria (E. coli) by binding to their outer membrane and activating the functionally homologous CpxA-CpxR two‑component system (Kashyap DR et al. 2011). Furthermore, genome expression arrays, qRT-PCR, and biochemical tests showed that PGRPs kill both E. coli and B. subtilis by inducing oxidative, thiol, and metal stress (Kashyap DR et al. 2014).

There is also emerging evidence that PGLYRP1 can function as a receptor agonist or antagonist for human cells. Human PGLYRP1 (multimerized or complexed with peptidoglycan) binds to and stimulates triggering receptor expressed on myeloid cells-1 (TREM-1), a receptor present on neutrophils, monocytes and macrophages that induces production of pro-inflammatory cytokines (Read CB et al. 2015). Moreover, PGLYRP1 and its complex with 70-kDa heat shock protein (Hsp70) bind to the tumor necrosis factor receptor-1 (TNFR1, which is a death receptor). The PGLYRP1-Hsp70 complex induces a cytotoxic effect via apoptosis and necroptosis (Yashin DV et al. 2015, 2016), which accounts for the tumor cytotoxicity of PGLYRP1-Hsp70 complexes secreted by cytotoxic lymphocytes (Sashchenko LP et al. 2004). By contrast, free PGLYRP1 acts as a TNFR1 antagonist, by binding to TNFR1 and inhibiting its activation by PGLYRP1-Hsp70 complexes.

R-HSA-6798474 (Reactome) Two members of the S100 protein family, S100A8 (also know as migration inhibitory factor-related proteins 8 (MRP8)) and S100A9 (MRP14) are calcium-binding regulators of inflammatory processes and immune response. S100A8 & S100A9 are constitutively expressed in neutrophils, myeloid-derived dendritic cells, platelets, osteoclasts and hypertrophic chondrocytes (Hessian PA et al. 1993; Kumar A et al. 2003; Healy AM et al. 2006; Schelbergen RF et al 2012). In contrast, these molecules are induced under inflammatory stimuli in monocytes/macrophages, microvascular endothelial cells, keratinocytes and fibroblasts (Hessian PA et al. 1993; Eckert RL et al. 2004; Viemann D et al. 2005; McCormick MM et al. 2005; Hsu K et al. 2005). S100A8 & S100A9 are known to have diverse functions including antimicrobial activities. During infectious processes S100A8 and S100A9 are delivered to the tissue abscess by recruited neutrophils. S100A8 & S100A9 exist mainly as a S100A8:S100A9 heterodimer which is termed calprotectin based on its role in innate immunity (Korndorfer IP et al. 2007). Calprotectin inhibits bacterial growth through chelation of extracellular manganese Mn(2+), zinc Zn(2+) and possibly iron Fe(2+) and thus restricts metal-ion availability during infection (Damo SM et al. 2013; Brophy MB et al. 2012, 2013; Hayden JA et al. 2013; Gagnon DM et al. 2015; Nakashige TG et al. 2015). Calprotectin exhibited antimicrobial activity for a broad range of Gram-positive and Gram-negative bacterial pathogens including Staphylococcus aureus, Staphylococcus epidermidis, Staphylococcus lugdunensis, Enterococcus faecalis, Acinetobacter baumannii, Pseudomonas aeruginosa, Escherichia coli, Shigella flexneri and Acinetobacter baumannii (Damo SM et al. 2013; Kehl-Fie TE et al. 2011; Nakashige TG et al. 2015).

Both S100A8 and S100A9 belong to the S100 family of helix-turn-helix (EF-hand) calcium Ca(2+)-binding proteins. S100 proteins are involved in a wide range of cellular functions (Donato R et al. 2013; Zackular JP et al. 2015; Vogl et al. 2007). Within cells, S100 proteins are involved in aspects of regulation of proliferation, differentiation, apoptosis, Ca(2+) homeostasis, inflammation and migration/invasion (Donato R et al. 2013). During infection, certain S100 proteins can be secreted or released by cells to act as damage-associated molecular patterns (DAMPs) and interact with pattern recognition receptors to modulate inflammatory responses (Foell D et al. 2007; Vogl et al. 2007). In addition, these inflammatory S100 proteins have antimicrobial function by sequestering essential transition metals from bacteria, preventing their growth (Zackular JP et al. 2015). The fundamental structural unit of S100 proteins is a highly integrated antiparallel dimer (Potts BC et al. 1995; Heizmann CW et al. 2002; Brodersen DE et al. 1999; Moroz OV et al. 2009; Gagnon DM et al. 2015). All S100 proteins form this structure as homodimers. S100A8 and S100A9 are unique among all members of the S100 family because they preferentially form a heterodimer. Calprotectin (S100A8:S100A9) and other S100 proteins are Ca(2+)-activated regulators (Brophy MB et al. 2012; Donato R et al. 2013). Inside the cell, where the basal level of Ca(2+) is in the nanomolar range, S100 proteins can serve as a sensor of Ca(2+)-mediated signals. In the extracellular milieu, S100 proteins are perpetually (Ca2+)-bound because Ca(2+) concentration is in the millimolar range. Ca(2+) is also known to stimulate formation of higher order oligomers of S100 proteins, including S100A8/S100A9 tetramers (Leukert N et al. 2006; Korndörfer IP et al. 2007). Upon dimerization S100A8 and S100A9 form two metal binding sites at the dimer interface, both of which can bind to Zn(2+) with high affinity (Kd Zn(2+) about 10e-9 M) (Damo SM et al. 2013; Brophy MB et al. 2013). A chelation of Mn(2+) involves a single binding site (Kd Mn(2+) around 10e-7 - 10e-8 M) (Damo SM et al. 2013; Hayden JA et al. 2013; Gagnon DM et al. 2015).

Thus, calprotectin S100A8:S100A9 inhibits bacterial growth by targeting transition metals and sequestering these metals in a process referred to as nutritional immunity.

R-HSA-6798489 (Reactome) Human S100A7 (known as psoriasin) is expressed in epidermal basal keratinocyte (Martinsson H et al. 2005). During keratinocyte differentiation in epidermis, S100A7 redistributes to the cell periphery suggesting that S100A7 is released from differentiated keratinocytes (Broome AM et al. 2003; Ruse M et al. 2003). Extracellular S100A7 can act as an antibacterial agent restricting growth of E.coli (Glaser R et al. 2005). When purified from human cells the antimicrobial activity of S100A7 can be reversed by the addition of zinc suggesting that S100A7 may inhibit microbial growth through zinc chelation (Glaser R et al. 2005). Additionally, S100A7 has been reported to kill by permeabilizing bacterial membranes (Michalek M et al. 2009). The killing activity of S100A7 showed pH-dependent target specificity (Michalek M et al. 2009). At neutral pH, the Gram-negative bacterium E. coli was killed apparently without compromising its membrane, whereas at low pH exclusively the Gram-positive bacterium B. megaterium was killed by permeabilization of its cytoplasmic membrane (Michalek M et al. 2009).

Structural studies revealed that S100A7 functions as (Ca2+)-bound homodimer, which can load two Zn2+ ions at symmetrically disposed sites across the dimer interface using residues His-86 and His-90 from one subunit and residues His-17 and Asp-24 from the other (Brodersen DE et al. 1999). Binding of Zn2+ is believed to stabilize the dimer and potentially mediate S100A7 function during infection (Brodersen DE et al. 1999).

S100A7 and its paralog, S100A7A (S100A15 or koebnerisin) display 93% sequence identity (Wolf R et al. 2011; Murray JI et al. 2012). Human S100A7A (S100A15) showed antimicrobial activity against E. coli (Büchau AS et al. 2007). Moreover, structural and solution binding studies revealed similar affinities of zinc ion for S100A7 and S100A7A (S100A15) (Murray JI et al. 2012). Though the Reactome project describes psoriacin (S100A7) and koebnerisin (S100A7A) as antimicrobial proteins with the metal-chelating properties, additional studies are needed to more fully define the contribution of S100A7 and S100A7A to nutritional immunity.

Particularly high expression of S100A7 and S100A7A was observed in inflamed psoriatic lesions, which are characterized by disturbed epidermal differentiation and inflammation (Madsen P et al. 1991). Circulating leukocytes (PBMCs) of patients with psoriasis produced increased levels of koebnerisin and psoriasin compared to healthy individuals (Batycka-Baran A et al. 2015). Both S100A proteins further acted as 'alarmins' on PBMC to induce proinflammatory cytokines implicated in the pathogenesis of psoriasis, such as IL-1beta, TNFalpha, IL6 and IL8 (Batycka-Baran A et al. 2015). However, inflammatory activities of S100A7 and S100A7A were found to serve distinct roles in epithelial homeostasis, inflammation, and cancer (Hattinger E et al. 2013; Wolf R et al. 2011; Murray JI et al. 2012). S100A7 signals through the receptor for advanced glycation products (RAGE) in a zinc-dependent manner, while S100A15 signals through a yet unidentified G-protein coupled receptor in a zinc-independent manner (Wolf R et al. 2011; Murray JI et al. 2012). Apart from inflammatory skin diseases an elevated exression of S100A7 was found in several epithelial cancers such as squamous cell carcinoma (SCC) of the skin, bladder, lung as well as in in situ ductal breast carcinoma (Celis JE et al. 1996; Al-Haddad S et al. 1999; Emberley ED et al. 2004; Moubayed N et al. 2007; Liu G et al. 2015; Qi Z et al. 2015).

R-HSA-6798528 (Reactome) S100A8 and S100A9 are calcium-binding regulators of inflammatory processes and immune response (also know as migration inhibitory factor-related proteins 8 (MRP8) and MRP14). S100A8 & S100A9 are constitutively expressed in neutrophils, myeloid-derived dendritic cells, platelets, osteoclasts and hypertrophic chondrocytes (Hessian PA et al. 1993; Kumar A et al. 2003; Healy AM et al. 2006; Schelbergen RF et al 2012). In contrast, these molecules are induced under inflammatory stimuli in monocytes/macrophages, microvascular endothelial cells, keratinocytes and fibroblasts (Hessian PA et al. 1993; Eckert RL et al. 2004; Viemann D et al. 2005; McCormick MM et al. 2005; Hsu K et al. 2005). S100A8 & S100A9 are known to have diverse functions including antimicrobial activities. During infectious processes S100A8 and S100A9 are delivered to the tissue abscess by recruited neutrophils. S100A8 & S100A9 exist mainly as a S100A8:S100A9 heterodimer which is termed calprotectin based on its role in innate immunity (Korndorfer IP et al. 2007). Calprotectin inhibits bacterial growth through chelation of extracellular manganese Mn(2+), zinc Zn(2+) and possibly iron Fe(2+) and thus restricts metal-ion availability during infection (Damo SM et al. 2013; Brophy MB et al. 2012, 2013; Hayden JA et al. 2013; Gagnon DM et al. 2015; Nakashige TG et al. 2015). Calprotectin exhibited antimicrobial activity for a broad range of Gram-positive and Gram-negative bacterial pathogens including Staphylococcus aureus, Staphylococcus epidermidis, Staphylococcus lugdunensis, Enterococcus faecalis, Acinetobacter baumannii, Pseudomonas aeruginosa, Escherichia coli, Shigella flexneri and Acinetobacter baumannii (Damo SM et al. 2013; Kehl-Fie TE et al. 2011; Nakashige TG et al. 2015).

Both S100A8 and S100A9 belong to the S100 family of helix-turn-helix (EF-hand) calcium Ca(2+)-binding proteins. S100 proteins are involved in a wide range of cellular functions (Donato R et al. 2013; Zackular JP et al. 2015; Vogl et al. 2007). Within cells, S100 proteins are involved in aspects of regulation of proliferation, differentiation, apoptosis, Ca(2+) homeostasis, inflammation and migration/invasion (Donato R et al. 2013). During infection, certain S100 proteins can be secreted or released by cells to act as damage-associated molecular patterns (DAMPs) and interact with pattern recognition receptors to modulate inflammatory responses (Foell D et al. 2007; Vogl et al. 2007). In addition, these inflammatory S100 proteins have antimicrobial function by sequestering essential transition metals from bacteria, preventing their growth (Zackular JP et al. 2015). The fundamental structural unit of S100 proteins is a highly integrated antiparallel dimer (Potts BC et al. 1995; Heizmann CW et al. 2002; Brodersen DE et al. 1999; Moroz OV et al. 2009; Gagnon DM et al. 2015). All S100 proteins form this structure as homodimers. S100A8 and S100A9 are unique among all members of the S100 family because they preferentially form a heterodimer. Calprotectin (S100A8:S100A9) and other S100 proteins are Ca(2+)-activated regulators (Brophy MB et al. 2012; Donato R et al. 2013). Inside the cell, where the basal level of Ca(2+) is in the nanomolar range, S100 proteins can serve as a sensor of Ca(2+)-mediated signals. In the extracellular milieu, S100 proteins are perpetually (Ca2+)-bound because Ca(2+) concentration is in the millimolar range. Ca(2+) is also known to stimulate formation of higher order oligomers of S100 proteins, including S100A8/S100A9 tetramers (Leukert N et al. 2006; Korndörfer IP et al. 2007). Upon dimerization S100A8 and S100A9 form two metal binding sites at the dimer interface, both of which can bind to Zn(2+) with high affinity (Kd Zn(2+) about 10e-9 M) (Damo SM et al. 2013; Brophy MB et al. 2013). A chelation of Mn(2+) involves a single binding site (Kd Mn(2+) around 10e-7 - 10e-8 M) (Damo SM et al. 2013; Hayden JA et al. 2013; Gagnon DM et al. 2015).

Thus, calprotectin S100A8:S100A9 inhibits bacterial growth by targeting transition metals and sequestering these metals in a process referred to as nutritional immunity.

R-HSA-6799959 (Reactome) Peptidoglycan recognition proteins (PGRPs or PGLYRPs) are innate immunity molecules that contain a conserved peptidoglycan‑binding type 2 amidase domain that is homologous to bacteriophage and bacterial type 2 amidases (Kang D et al. 1998; Liu C et al. 2001; Royet J and Dziarski R 2007; Royet J et al. 2011; Dziarski R et al. 2016). Mammals have a family of four PGRPs (PGLYRP1, 2, 3 & 4) that are differentially expressed in a cell-type or tissue-specific manner. Human PGLYRP3 and PGLYRP4 (also known as PGRP‑Ialpha and PGRP-Ibeta) are expressed in keratinocytes and epithelial cells and are found in the skin, eyes, salivary glands, throat, tongue, esophagus, stomach, and intestine (Liu C et al. 2001; Lu X et al. 2006). Like PGLYRP1, PGLYRP3 and PGLYRP4 are secreted as disulfide‑linked homodimers (Guan R et al. 2004, 2005; Lu X et al. 2006). However, PGLYRP3 and PGLYRP4 preferentially form heterodimers when coexpressed in the same cells (Lu X et al. 2006). PGLYRP3, PGLYRP4, and PGLYRP3:PGLYRP4 have Zn(2+)‑dependent bactericidal activity against both Gram‑positive and Gram‑negative bacteria at the physiological Zn(2+) concentrations found in serum, sweat, saliva, and other body fluids (Lu X et al. 2006; Wang M et al. 2007). PGLYRP3 and PGLYRP4 are also active against Chlamydia trachomatis (Bobrovsky P et al. 2016). Killing of both Gram-positive and Gram-negative bacteria by PGLYRP3 and PGLYRP4 is synergistically enhanced by antimicrobial peptides (phospholipase A2, alpha- and beta-defensins, and bactericidal permeability-increasing protein (BPI)) (Wang M et al. 2007). The bactericidal activity of PGRPs requires their N‑glycosylation, as deglycosylation with N‑glycosidase abolished their bactericidal activity against Bacillus subtilis, Staphylococcus aureus, and Escherichia coli (Lu X et al. 2006; Wang M et al. 2007).

PGRPs are thought to kill bacteria by interacting with cell wall peptidoglycan and by inducing lethal stress response in bacteria, as opposed to the hydrolysis of peptidoglycan or permeabilizing bacterial membranes seen with other antibacterial peptides (Lu X et al. 2006; Wang M et al. 2007; Cho S et al. 2007; Kashyap DR et al. 2011, 2014). In Gram‑positive bacteria, including B. subtilis, PGLYRP1, 3 & 4 were found to enter the bacterial cell wall at the site of daughter cell separation during cell division and to bind to cell wall peptidoglycan in the vicinity of the cell membrane (Kashyap DR et al. 2011). Binding of PGLYRP3 to peptidoglycan induces a structural change in PGLYRP3 that locks peptidoglycan in the protein's bindings groove (Guan R et al. 2006). However, this binding did not inhibit the extracellular transglycosylation or transpeptidation steps in peptidoglycan synthesis (Kashyap DR et al. 2011), which are well-known targets for bactericidal antibiotics. Instead, this interaction of PGRP proteins with peptidoglycan activated the B. subtilis envelope stress response two‑component system CssR‑CssS that detects and disposes of misfolded proteins exported out of bacterial cells. This activation resulted in bacterial membrane depolarization, cessation of intracellular peptidoglycan, protein, RNA, and DNA synthesis and production of toxic hydroxyl radicals, which were responsible for bacterial death (Kashyap DR et al. 2011). In Gram‑negative bacteria (E. coli), PGRPs were found to bind the bacterial outer membrane activating the functionally homologous CpxA‑CpxR two‑component system (Kashyap DR et al. 2011). Genome expression arrays, qRT‑PCR, and biochemical tests showed that PGLYRP3 & 4 kill both E. coli and B. subtilis by inducing oxidative, thiol, and metal stress (Kashyap DR et al. 2014).

R-HSA-6799977 (Reactome) Peptidoglycan recognition proteins (PGRPs or PGLYRPs) are innate immunity molecules that contain a conserved peptidoglycan-binding type 2 amidase domain that is homologous to bacteriophage and bacterial type 2 amidases (Kang D et al. 1998; Liu C et al. 2001; Royet J and Dziarski R 2007; Royet J et al. 2011; Dziarski R et al. 2016). Mammals have a family of four PGRPs (PGLYRP1, 2, 3 & 4) that are differentially expressed in a cell-type or tissue-specific manner. PGLYRP2 (also known as PGRP-L) is constitutively produced in the liver and secreted into the blood (Liu C et al. 2001; Zhang Y et al. 2005; De Pauw P et al. 1995; Hoijer MA et al. 1996). PGLYRP2 expression can also be induced in the skin and intestine upon exposure to bacteria or pro-inflammatory cytokines (Wang H et al. 2005; Li X et al. 2006). Constitutive and inducible expression of PGLYRP2 in the liver and skin respectively required different transcription factors (Li X et al. 2006). PGLYRP2 is a (Zn2+)-dependent N-acetylmuramoyl-L-alanine amidase that hydrolyzes the amide bond between the MurNAc and L-alanine in bacterial cell wall peptidoglycan (Wang ZM et al. 2003; Zhang Y et al. 2005). The minimal peptidoglycan fragment hydrolyzed by PGLYRP2 is MurNAc-tripeptide (Wang ZM et al. 2003). Due to its amidase activity, human PGLYRP2 is thought to reduce inflammatory properties of bacterial peptidoglycan by cleaving it into biologically inactive fragments (Hoijer MA et al. 1997; Wang ZM et al. 2003; Royet J and Dziarski R 2007).
R-HSA-6799981 (Reactome) Peptidoglycan recognition proteins (PGRPs or PGLYRPs) are innate immunity molecules that contain a conserved peptidoglycan‑binding type 2 amidase domain that is homologous to bacteriophage and bacterial type 2 amidases (Kang D et al. 1998; Liu C et al. 2001; Royet J and Dziarski R 2007; Royet J et al. 2011; Dziarski R et al. 2016). Mammals have a family of four PGRPs (PGLYRP1, 2, 3 & 4) that are differentially expressed in a cell‑type‑ or tissue‑specific manner. PGLYRP2 (also known as PGRP-L) is constitutively expressed in the liver, from which it is secreted into blood as non-disulfide‑linked dimers (Liu C et al. 2001; Zhang Y et al. 2005; De Pauw P et al. 1995; Hoijer MA et al. 1996). PGLYRP2 expression can be also induced in the skin and intestine upon exposure to bacteria or pro-inflammatory cytokines (Wang H et al. 2005; Li X et al. 2006). The constitutive expression of PGLYRP2 in the liver and induced expression in epithelial cells is regulated by different transcription factors, the binding sequences for which are located in different regions of the pglyrp2 promoter (Li X et al. 2006). PGRP2 binds to bacterial cell wall peptidoglycan and functions as N‑acetylmuramoyl‑L‑alanine amidase that hydrolyzes the amide bond between the MurNAc and L‑alanine in peptidoglycan (Wang ZM et al. 2003; Zhang Y et al. 2005). The minimal peptidoglycan fragment hydrolyzed by PGLYRP2 is MurNAc-tripeptide (Wang ZM et al. 2003). PGLYRP2 has a conserved Zn(2+)‑binding site in the peptidoglycan‑binding groove, which is also present in bacteriophage type 2 amidases, and PGLYRP2 requires Zn(2+) for its amidase activity (Wang ZM et al. 2003). The amidase activity of mammalian PGLYRP2 is though to eliminate the pro‑inflammatory peptidoglycan and, therefore, prevent over‑activation of the immune system and excessive inflammation (Hoijer MA et al. 1997; Royet J and Dziarski R 2007). In addition to its amidase activity, PGLYRP2 also has antibacterial activity against both Gram-positive and Gram-negative bacteria and Chlamydia (Bobrovsky P et al. 2016), similar to PGLYRP1, PGLYRP3, and PGLYRP4 (Lu X et al. 2006; Wang M et al. 2007).
R-HSA-6801687 (Reactome) Cathelicidin (CAMP, LL-37 and hCAP), is a major protein in specific granules of neutrophils (Sorensen O et al. 1997). CAMP is also present in subpopulations of lymphocytes and monocytes, squamous epithelial cells and keratinocytes (Agerberth B et al. 2000; Frohm M et al. 1997; Frohm Nilsson M et al. 1999). CAMP is synthesized as preproprotein (Zanetti M et al. 1995). After removal of the signal peptide, CAMP(31-170) is stored in granules as an inactive proform (Sorensen OE et al. 2001). CAMP (31-170) was shown to be processed extracellularly to the active antimicrobial peptide LL-37 (CAMP(134-170)) by proteinase 3 (PRTN3) (Sorensen OE et al. 2001).
R-HSA-6801762 (Reactome) Regenerating islet-derived 3A (REG3A) is thought to recognize and kill its bacterial targets in two distinct steps (Mukherjee S et al. 2014). First, REG3A is secreted from epithelial cells as a soluble monomer that recognizes Gram-positive bacteria by binding to peptidoglycan carbohydrate via an EPN motif located in the long loop region (Lehotzky RE et al. 2010). Second, REG3A kills bacteria by oligomerizing in the bacterial membrane to form a hexameric membrane-penetrating pore that is predicted to induce uncontrolled ion efflux with subsequent osmotic lysis (Mukherjee S et al. 2014). The inhibitory N-terminus of REG3A propeptide hinders lipid binding and consequently suppresses pore formation until it is removed by trypsin after secretion into the intestinal lumen (Mukherjee S et al. 2009; 2014).
R-HSA-6801766 (Reactome) Regenerating islet-derived 3 (REG3) proteins belong to the family of C-type lectins (Cash HL et al. 2006a,b; Lehotzky RE et al. 2010). REG3A and REG3G are expressed in the intestine where they moodulate the host interactions with commensal and pathogenic gut bacteria. REG3 proteins bind the peptidoglycan moieties of bacteria inducing damage to the bacterial cell wall. The antibacterial activities of REG3 proteins are restricted to Gram-positive bacteria and are tightly controlled by an inhibitory N-terminal prosegment that is removed by trypsin in vivo (Cash HL et al. 2006; Mukherjee S et al. 2009; Medveczky P et al. 2009).
R-HSA-6801776 (Reactome) Structural studies of human REG3A by X-ray diffraction with electron microscopy suggest that REG3A binds to bacterial membrane phospholipids and kills bacteria by forming a hexameric membrane-permeabilizing pore (Mukherjee S et al. 2014).
R-HSA-6801808 (Reactome) Regenerating islet-derived 3 (REG3) proteins belong to the family of C-type lectins (Cash HL et al. 2006a,b; Lehotzky RE et al. 2010). REG3A and REG3G are induced and expressed in the intestine where they function as antibacterial peptides by targeting the peptidoglycan moieties of bacteria. NMR spectroscopy revealed that human REG3A lectin recognized the peptidoglycan carbohydrate backbone in a calcium-independent manner via a conserved “EPN� motif that is critical for bacterial killing (Lehotzky RE et al. 2010). The antibacterial activities of REG3 proteins are restricted to Gram-positive bacteria and are tightly controlled by an inhibitory N-terminal pro-segment that is removed by trypsin in vivo (Cash HL et al. 2006; Mukherjee S et al. 2009; Medveczky P et al. 2009).
R-HSA-6802999 (Reactome) Dermcidin (DCD) is constitutively expressed in eccrine sweat glands, secreted into sweat and transported to the epidermal surface where it is proteolytically processed giving rise to several truncated DCD peptides (Schittek B et al. 2001; Rieg S et al. 2006). The processed forms such as the anionic DCD(63-110) (DCD-1L) and DCD(63-109) (DCD-1) possess antimicrobial activity against Gram-positive (Staphylococcus aureus, Enterococcus faecalis, Staphylococcus epidermidis, Listeria monocytogenes) and Gram-negative bacteria (Escherichia coli, Pseudomonas putida, Salmonella typhimurium) as well as Candida albicans (Cipakova I et al. 2006; Lai YP et al. 2005; Schittek B et al. 2001; Steffen H et al. 2006; Vuong C et al. 2004). The antimicrobial activity of DCD(63-110) (DCD-1L) is maintained over a broad pH range and at high salt concentrations that resemble the conditions in human sweat (Schittek B et al. 2001). DCD(63-110) was reported to interact with negatively charged bacterial phospholipids which lead to (Zn2+)-dependent formation of oligomeric complexes in the bacterial membrane, which subsequently lead to ion channel formation resulting in membrane depolarization and bacterial cell death (Paulmann M et al. 2012; Song C et al. 2013).
R-HSA-6803047 (Reactome) Dermcidin peptides, DCD1(63-109) and DCD-1L(63-110), are anionic peptides with a net negative charge of -2 at physiological pH (Paulmann M et al. 2012). Despite its negative net charge, DCD peptides possess an amphiphilic structure due to its cationic N-terminal region (Ser1 to Lys23) and its anionic C-terminal part (Asp24 to Leu48). The cationic N-terminal part is mainly responsible for the binding of DCD to the negatively charged phospholipids.
R-HSA-6803060 (Reactome) A 47aa dermcidin (DCD)-derived peptide (DCD(63-109), also known as as DCD-1) is an antimicrobial peptide with a negative net charge and acidic pI (Schittek B 2012). Like other antimicrobially active DCD-derived peptides, DCD(63-109) is produced in human eccrine sweat through proteolytic processing of a 110-amino acid (aa) precursor protein (Schittek B et al. 2001; Rieg S et al. 2006). DCD-derived peptides are able to bind to the bacterial surface, however they do not exert their activity by permeabilizing bacterial membranes (Senyürek et al. 2009, Steffen H et al. 2006). The negative net charge of DCD(63-109) did not significantly affected the peptide binding to bacterial-mimetic membranes (Jung et al. 2010, Steffen et al. 2006; Senyurek et al. 2009). Spin-down assays of DCD(63-109) and other DCD peptides revealed that the affinity with which dermcidin binds to bacterial-mimetic membranes is primarily dependent on its amphipathic alpha-helical structure and its length (>30 residues)(Jung et al. 2010).

DCD(63-109) shows a broad spectrum of antimicrobial activity against Gram-positive (Staphylococcus aureus, Enterococcus faecalis, Staphylococcus epidermidis, Listeria monocytogenes) and Gram-negative bacteria (Escherichia coli, Pseudomonas putida, Salmonella typhimurium) as well as Candida albicans (Cipakova I et al. 2006, Lai YP et al. 2005, Schittek B et al. 2001, Steffen H et al. 2006, Vuong C et al. 2004). The activity of the DCD(63-109) was maintained over a broad pH range and in high salt concentrations that resembled the conditions in human sweat (Schittek B et al. 2001).

R-HSA-6803063 (Reactome) Ribonucleases (RNase) 3, 6 and 7, which belong to the RNase A superfamily and are secreted upon infection, interact with the components of the bacterial cell wall (Torrent M et al. 2010; Pulido D et al. 2016a, b).

RNase A family is a vertebrate-specific gene family (Goo SM & Cho S 2013). Members of RNase A family share specific elements of sequence homology, a unique disulfide-bonded tertiary structure, and the ability to hydrolyze polymeric RNA (Beintema JJ & Kleineidam RG 1998; Rosenberg HF 2008). Eight catalytically active members are found in humans: RNase1 (pancreatic RNase), RNase2 (eosinophil derived neurotoxin/EDN), RNase3 (eosinophil cationic protein/ECP), RNase4, RNase5 (angiogenin), RNase6, RNase7 (skin-derived RNase), and RNase8 (divergent paralog of RNase7) (Sorrentino S 2010). Analysis of human genome sequence has revealed the existence of five additional RNases named as RNases 9-13, although they appear to lose enzymatic activity (Devor EJ et al. 2004; Castella S et al. 2004; Cho S et al. 2005). All human RNase A family members encode relatively small polypeptides of 14 to 16kDa containing signal peptides of 20 to 28 amino acids for protein secretion. Mature RNases contain 6 to 8 cysteine residues that are crucial to hold the overall tertiary structure (Sorrentino S 2010). Apart from the ribonuclease activity the RNase A family members have been implicated in a wide variety of biological actions including antipathogen and immunomodulatory activities (Harder J & Schroder JM 2002; Rudolph B et al. 2006; Boix E et al. 2008; Boix and Nogués, 2007; Spencer JD et al. 2011; Becknell B et al. 2015; Rosenberg HF 2015). Evidence of antimicrobial properties displayed by distantly related members ascribed to the family an ancestral role in host defence (Pizzo E & D’Alessio G 2007; Rosenberg HF et al. 2008).

RNase3, RNase6 and RNase7 have been identified as the most potent human antibacterial ribonucleases with a broad antimicrobial action against Gram-positive and Gram-negative bacteria (Pulido D et al. 2013, 2016; Zhang J et al. 2003; Boix E et al. 2008; Torrent M et al. 2010). Mutagenesis analysis revealed that ribonuclease-inactive RNase7 protein exhibited similar anti-microbial activity against P. aeruginosa, E. faecium and E. coli as the wild-type protein suggesting that RNase7 may kill bacteria independently of its ribonuclease catalytic activity (Huang YC et al. 2007; Koten B et al. 2009). Similar results were reported on microbicidal effect of ribonuclease-inactive RNase3 and 6 proteins against S. aureus (Rosenberg HF 1995; Pulido D et al. 2016a). Being cationic proteins with a high pI, RNase3, 6 and 7 interact with anionic components of biological membranes (Zhang J et al. 2003; Boix E et al. 2008; Torrent M et al. 2010; Boix E et al. 2012; Pulido D et al. 2016a). RNase3, 6 and 7 present, respectively, a high number of either Arg, His or Lys surface-exposed residues that may contribute to their distinct bactericidal mechanisms of action (Torrent M et al. 2010; Prats-Ejarque G et al. 2016). RNase3 displays a membrane disruption capacity that is dependent on both surface exposed hydrophobic and cationic residues. RNase3 can bind and partially insert into the lipid bilayers, promoting its aggregation and final lysis, following a carpet-like mechanism. The RNase3 agglutination process precedes the bacterial death and lysis event. The antimicrobial properties of the RNase6 are comparable to its RNase3 homolog and correlate to the bacterial cell damage and agglutination activities (Pulido D et al. 2016a). In contrast, RNase7 has no significant membrane aggregation capacity (Torrent M et al. 2010). RNase7 binds and permeabilizes the bacterial membrane displaying a much higher leakage capacity compared to RNase3 (Torrent M et al. 2010; Huang YC et al. 2007). Membrane permeabilization by RNase7 required four clustered lysine residues but no catalytic residues (Huang YC et al. 2007). Binding to PGN and LPS has been reported for RNases 3 and 7 (Torrent M et al. 2010; Pulido D et al. 2016b). Studies using a battery of progressively truncated LPS-defective E. coli strains correlated the LPS interaction with the protein cell agglutination and bactericidal activities (Pulido D et al. 2012). Further work indicated that RNase3 and RNase 6 high cell agglutination activity towards Gram negative species is retained by their respective N-terminus peptides (Torrent M et al. 2012, 2013; Pulido D et al. 2016c). In particular, the RNase3 N-terminus encompasses a specific patch (Y33-R36) required for LPS binding and an hydrophobic aggregation prone region (A8-I16) that mediates the protein self amyloid- like aggregation and promotes the cell death.

R-HSA-6803104 (Reactome) DCD peptide is initially monomeric when secreted in human sweat. In presence of a negatively charged bacterial membrane the cationic N-terminus of DCD gets attracted electrostatically (Paulmann M et al. 2012). Upon interaction with the bacterial membrane a change in the secondary structure from random coil to an alpha-helical conformation is induced. DCD-1(L) self-assembles into a higher oligomeric state which is stabilized by zinc ions. Subsequently, by oligomerization DCD is able to form ion channels in the bacterial membrane resulting in bacterial cell death ( (Paulmann M et al. 2012; Song C et al. 2013; Burian M & Schittek B 2015).
R-HSA-6803545 (Reactome) Copper is an essential cofactor of key metabolic enzymes (Linder MC & Hazegh-Azam M 1996). Under normal conditions, the biosynthetic incorporation of copper into secreted and plasma membrane-bound proteins requires activity of the copper-transporting P1B-type ATPases (Cu-ATPases), ATP7A and ATP7B (Camakaris J et al. 1999; La Fontaine S & Mercer JF 2007; Lutsenko S et al. 2007). The Cu-ATPases also export excess copper from the cell and thus critically contribute to the homeostatic control of copper (Camakaris J et al. 1999; La Fontaine S & Mercer JF 2007). However, during bacterial infection phagocytic cells accumulate copper Cu(I) in cytoplasmic vesicles that partially fuse with the phagolysosome, attacking invading microbes with toxic levels of Cu (Festa RA & Thiele DJ 2012). The accumulation of Cu(I) in the phagosome may be dependent upon the trafficking of ATP7A to the membranes of these vesicles (Fu Y et al. 2014). Silencing of ATP7A expression in mouse RAW264.7 macrophages attenuated bacterial killing, suggesting a role for ATP7A-dependent copper transport in the bactericidal activity of macrophages (White C et al. 2009). Copper toxicity targets iron-sulfur containing proteins via iron displacement from solvent-exposed iron-sulfur clusters (Macomber L & Imlay JA 2009; Chillappagari S et al. 2010; Djoko KY & McEwan AG 2013). Copper resistance has been shown to be required for virulence in two animal models of mycobacterial infection (Wolschendorf F et al. 2011; Shi X et al. 2014).

Mutations in the gene encoding ATP7A results in a severe copper-deficiency known as Menkes disease (Kaler SG 2011).

R-HSA-6804527 (Reactome) Intelectin-1 (INTL1) is a 120-kDa secretory lectin that recognizes multiple glycan epitopes found exclusively on microbes: beta-linked D-galactofuranose (beta-Galf), D-phosphoglycerol-modified glycans, heptoses, D-glycero-D-talo-oct-2-ulosonic acid (KO) and 3-deoxy-D-manno-oct-2-ulosonic acid (KDO) (Tsuji S et al. 2001; Wesener DA et al. 2015). These glycan residues are widely distributed in bacteria, including S. pneumoniae, Proteus mirabilis, Proteus vulgaris, Yersinia pestis and K. pneumoniae (Wesener DA et al. 2015). The 1.6-A-resolution crystal structure of human INTL1 complexed with beta-Galf suggests that INTL1 binds its carbohydrate ligands bearing terminal 1,2-diols through calcium ion-dependent coordination (Wesener DA et al. 2015).

Secreted INTL1 functions as a disulfide-linked trimer (Tsuji S et al., 2001; Tsuji S et al., 2007; Wesener DA et al., 2015).

R-HSA-6806732 (Reactome) Cationic protein granulysin (GNLY) is produced by activated human cytotoxic T lymphocytes (CTL) and natural killer (NK) cells (Pena SV et al. 1997; Stenger S et al. 1998; Ogawa K et al. 2003). GNLY can target extracellular and intracelullar pathogens. It is believed that the electrostatic interaction between the cationic GNLY and the negatively charged microbial cell surface increases the ability of GNLY to fold into amphipathic conformation which can disrupt microbial membranes resulting in cytolysis by osmotic shock (Wang Z et al. 2000; Ernst WA et al. 2000; Anderson DH et al. 2003; Barman H et al. 2006).

GNLY is synthesized as a 15-kDa molecule and then proteolytically cleaved at the amino and carboxyl termini to produce a 9-kDa form (Pena SV et al. 1997; Hanson DA et al. 1999). The 9 -kDa form of GNLY is confined to cytolytic granules that are directionally released by receptor-mediated granule exocytosis following target cell recognition (Hanson DA et al. 1999; Clayberger C et al 2012). In contrast, the 15-kDa form is constitutively secreted from distinct granules that lack perforin and granzyme (Clayberger C et al 2012). The 9-kDa GNLY exhibits cytolytic activity on the numerous microbes ranging from extracellular and intracellular bacteria to fungi and parasite (Stenger S et al. 1998; Ernst WA et al. 2000). GNLY kills Mycobacterium tuberculosis, the causative agent in tuberculosis and Plasmodium falciparum, a cause of malaria (Stenger S et al. 1998; Farouk SE et al. 2004). Alongside its ability to kill bacteria, fungi, and parasites, GNLY can block viral replication and trigger apoptosis in infected cells (Hata A et al. 2001).

Besides its direct antimicrobial activity, GNLY shows tumoricidal activity by inducing apoptosis in tumor cells. Both 9-kDA and 15-kDA forms of GNLY may also function as chemoattractants for T lymphocytes, monocytes and other inflammatory cells and activates the expression of a number of cytokines (Deng A et al. 2005; Castiello L et al. 2011).

R-HSA-6807144 (Reactome) Histatins (HTNs) is a family of small histidine-rich peptides (18-28 mol%) that present in the saliva and secreted by parotid, sub-mandibular and sub-lingual salivary glands (Oppenheim FG et al. 1988; Troxler RF 1990; Gornowicz A et al. 2014). The members of HTN family are structurally related peptides of which histatin 1 and 3 are full-length proteins encoded by closely related loci of two distinct genes, HTN1 and HTN3 (Oppenheim FG et al. 1988; Troxler RF 1990; Sabatini LM et al 1993). The smaller peptides are generated by proteolytic cleavage of parent HTN1 and HTN3 proteins by salivary proteases during secretion (Troxler RF 1990; Castagnola M et al. 2004).

HTNs exhibited antibacterial activity in vitro against various bacteria, including S. mutans, P. gingivalis, A. actinomycetemcomitans, P. aeruginosa and St. aureus (MacKay BJ et al. 1984; Murakami Y et al. 1991; Payne JB et al. 1991; Nishikata MH et al. 1991; Sajjan US et al. 2001; Murakami Y et al. 2002; Giacometti A et al. 2005; Welling MM et al. 2007). HTNs were also active against complex mixtures of bacteria, such as those present in saliva and plaque (Helmerhorst EJ et al. 1999). The antibacterial activity of HTNs is thought to rely on electrostatic interactions of cationic HTNs with anionic phospholipids, such as phosphatidylglycerol and cardiolipin on the bacterial cell surface (De Smet K & Contreras R 2005). HTNs have also been shown to possess a fungicidal activity (Oppenheim FG et al. 1988; Troxler RF 1990). HTN5 (a product of HTN3 gene) is the most potent among all histatin family members with regard to its antifungal activity against C.albicans and C.neoformans (Xu T et al. 1991; Tsai H & Bobek LA 1997; Helmerhorst EJ et al. 2001).

R-HSA-6807565 (Reactome) The antimicrobial protein granulysin (GNLY) is secreted from activated human cytotoxic T lymphocytes (CTL) and natural killer (NK) cells (Pena SV et al. 1997; Stenger S et al. 1998; Hanson DA et al. 1999; Ogawa K et al. 2003). The cationic GNLY binds to negatively charged surfaces found in bacteria causing defects in membranes of extracellular and intracellular pathogs (Stenger S et al. 1998; Ernst WA et al. 2000; Barman H et al. 2006). While showing strong antimicrobial activity, GNLY does not permeabilize cell membranes with eukaryotic lipid composition (Barman H et al. 2006). GNLY bound to lipid rafts or phospholipid on eukaryotic cell membranes can be internalized by lipid rafts and delivered to the early sorting endosomes which afterwards fuse with bacteria-containing phagosomes, where the GNLY-mediated lysis of bacteria is induced (Walch M et al. 2005, 2007). GNLY may require perforin as a cofactor to enter the host cells (Stenger S et al. 1998) However, it was also suggested that perforin promotes GNLY-mediated bacteriolysis not by the formation of stable pores that allow passive diffusion of GNLS but rather by an increase in endosome-phagosomes fusion triggered by an intracellular Ca(2+) rise (Walch M et al. 2007).
R-HSA-6807578 (Reactome) Granulysin (GNLY), an antimicrobial protein, is produced by activated human cytotoxic T lymphocytes (CTL) and natural killer (NK) cells (Pena SV et al. 1997; Stenger S et al. 1998; Ogawa K et al. 2003). GNLY is synthesized as a 15-kDa molecule and then proteolytically cleaved at the amino and carboxyl termini to produce a 9-kDa form (Pena SV et al. 1997; Hanson DA et al. 1999). The 9 -kDa form of GNLY is confined to cytolytic granules that are directionally released by receptor-mediated granule exocytosis following target cell recognition (Hanson DA et al. 1999; Clayberger C et al 2012). In contrast, the 15-kDa form is constitutively secreted from distinct granules that lack perforin and granzyme (Clayberger C et al 2012). The secreted 9-kDa GNLY is active against a range of intracellular pathogens, such as Listeria innocua, Mycobacterium tuberculosis and Trypanosoma cruzi (Stenger S et al. 1998; Walch M et al. 2005). The secreted GNLY is thought to bind to lipid rafts in eukaryotic cell membranes, where it is taken up and delivered to the early sorting endosomes which afterwards fuse with bacteria-containing phagosomes, where the GNLY-mediated lysis of bacteria is induced (Stenger S et al. 1998; Barman H et al. 2006; Walch M et al. 2005, 2007). Perforin is thought to promote GNLY-mediated bacteriolysis by an increase in endosome-phagosomes fusion triggered by an intracellular Ca(2+) rise (Walch M et al. 2007). However, it was also suggested that GNLY may require perforin as a cofactor to enter the host cells (Stenger S et al. 1998).

It is believed that the electrostatic interaction between the cationic GNLY and the negatively charged microbial cell surface increases the ability of GNLY to fold into amphipathic conformation which can disrupt microbial membranes resulting in cytolysis by osmotic shock (Wang Z et al. 2000; Ernst WA et al. 2000; Anderson DH et al. 2003; Barman H et al. 2006).

R-HSA-6807581 (Reactome) Histatins (HTNs) is a family of small, histidine-rich (18-28 mol%), cationic peptides that present in the saliva and secreted by parotid, submandibular and sub-lingual salivary glands (Oppenheim FG et al. 1988; Troxler RF et al. 1990; Hu S et al. 2005; Gornowicz A et al. 2014). Histatins 1, 3, and 5 are the most abundant peptides (Flora B et al. 2001; Gusman H et al. 2004; Hardt M et al. 2005). Histatin 1 and 3 are encoded by the HTN1 and HTN3 gene respectively (Sabatini LM et al 1993). Other histatin peptides are proteolytic derivatives of HTN1 and HTN3 (Troxler RF et al. 1990; Castagnola M et al. 2004; Messana I et al. 2008; Sun X et al. 2009). HTN3(20-43), a proteolytic product of histatin 3, is known as histatine 5.

The functional role of HTNs peptides in vivo involves prevention of the oral overgrowth of Candida albicans in oropharyngeal candidiasis (Jainkittivong A et al. 1998; Khan SA et al. 2013). HTNs display candidacidal and candidastatic activities in vitro against Candida albicans, Candida glabrata, Candida dubliniensis, Candida krusei, Saccharomyces cerevisiae, Cryptococcus neoformans and Neurospora crassa (Tsai H & Bobek LA 1997, 1998; Oppenheim FG et al. 1988; Xu T et al. 1991; Rayhan R et al. 1992; Helmerhorst EJ et al. 1999; van't Hof W et al. 2000; Fitzgerald DH et al. 2003). Histatin 5 shows the highest anticandicidal activity of the family in vitro at physiological concentrations found in saliva (15–50 microM) (Xu T et al. 1991). The candidacidal activity of histatin 5 results from a multistep molecular mechanism involving the recognition and binding of the peptide to the yeast cell wall proteins Ssa1/2p followed by the peptide internalization (Edgerton M et al. 1998; Li XS et al. 2003; Sun JN et al. 2008). Histatin 5 internalization is required for fungicidal activity in Candida species (Li XS et al. 2006; Jang WS et al. 2010). Ultimately, histatin 5 is transported into the cell through the fungal polyamine transporters Dur3 and Dur31 in an energy-dependent process (Kumar R et al. 2011; Tati S et al. 2013). Histatin 5- mediated killing involves interaction with the fungal mitochondrial membrane (Helmerhorst EJ et al. 1999; Gyurko C et al. 2000; 2001). Interference with mitochondrial respiratory machinery can lead to generation of reactive oxygen species (ROS) and ATP release (Helmerhorst EJ et al. 2001; Gyurko C et al. 2000; 2001). The killing of C. albicans is accompanied by the release of intracellular potassium ions and the Trk1 potassium channel is critical (Pollock JJ et al. 1984; Baev D et al 2004; Vylkova S et al. 2006). Histatine 5 has also been shown to bind various metals in saliva namely, Zn, Cu, Fe and Ni that can modulate the peptide candidacidal properties (Melino S et al. 1999; 2014; Puri S et al. 2015).

R-HSA-6807585 (Reactome) Bactericidal permeability-increasing protein (BPI) is a 57-kDa cationic antimicrobial protein that is present principally in the azurophilic granules of polymorphonuclear leukocytes (Elsbach P 1998). BPI has both heparin- and LPS-binding capacity and displays anti-inflammatory activity and direct bactericidal action toward Gram-negative bacteria (Ooi CE et al. 1991; Weiss J et al. 1992; Levy O et al. 2000). Direct bactericidal activity and lipopolysaccharide neutralization are mediated by the N-terminal part of the protein, whereas the C-terminal region has been shown to opsonize bacteria (Iovine NM et al. 1997; Elsbach P & Weiss J 1998).

Antineutrophil cytoplasmic autoantibodies against BPI (BPI-ANCA) have been found in diseases of different etiologies, such as cystic fibrosis, TAP deficiency or inflammatory bowel diseases (Walmsley RS et al. 1997; Schultz H et al. 2004; Schinke S et al. 2004; Aichele D et al. 2006). The presence of BPI-ANCA has been shown to correlate with the chronic or profuse exposure of the host to Gram-negative bacteria and their endotoxin (Aebi C et al. 2000; Carlsson M et al. 2003; Schultz H et al. 2003; Schultz H 2007).

R-HSA-6808566 (Reactome) Chromogranin A (CHGA) belongs to the granin family of acidic proteins enclosed in secretory vesicles of nervous, endocrine and immune cells. The proteolytic cleveages of specific CHGA sequences by the pro-hormone convertases generate bioactive fragments that exert a broad spectrum of regulatory activities by influencing the endocrine, cardiovascular and immune systems and affect glucose and calcium homeostasis (Helle KB et al. 2007; Aslam R et al. 2012; D'amico MA et al. 2014; Aung G et al. 2011; Tota B et al. 2014).

Several CHGA-derived peptides such as vasostatin-1 (CHGA(19-94) ) and catestatin (CHGA(370-390)) display antimicrobial activities against bacteria, fungi and yeasts (Lugardon K et al. 2000; Briolat J et al. 2005; Radek KA et al. 2008; Aslam R et al. 2013; Shooshtarizadeh P et al. 2010). These peptides are found in biological fluids involved in defence mechanisms (human serum and saliva) and in supernatants of stimulated human neutrophils (Lugardon K et al. 2000; Briolat J et al. 2005). In addition, catestatin (CHGA(370-390) exhibits antimicrobial activity against skin pathogens suggesting a function in cutaneous antimicrobial defense (Radek KA et al. 2008). Biophysical and structural analysis of human catestatin and bovine cateslytin suggests that cationic CHGA-derived peptides interact with anionic phospholipids on the bacterial surface (Sugawara M et al. 2010; Jean-Francois F et al. 2008). However, It remains to be clarified whether catestatin functions as a pore-forming or cell-penetrating agent.

R-HSA-6809521 (Reactome) BPI fold-containing (BPIF) proteins (known as PLUNC (palate, lung and nasal epithelium clone) proteins) are expressed largely in the respiratory tract of air-breathing vertebrates (Bingle CD et al. 2011). Due to both the presence at host-pathogen interface and sequence/structural similarities to members of a lipid-transfer protein family such as bactericidal/permeability-increasing (BPI) and lipopolysaccharide-binding (LBP) proteins, the BPIF family of proteins are predicted to have host-protective functions (Bingle CD & Craven CJ 2002, 2003; Beamer et al. 1997; Bingle CD et al. 2004; 2011). Although the BPIF proteins are thought to have the ability to bind to and transfer lipid molecules, their biological antimicrobial properties have yet to be elucidated (Bingle CD & Craven CJ 2003; ).

BPIFs are subdivided into two groups, the long (BPIFB or LPLUNC) and short (BPIFA or SPLUNC) proteins. The BPIFB (LPLUNC) proteins have sequence and structure homology to both the LPS-binding N-terminus and the C-terminus of BPI, which is responsible for its opsonization activity, and BPIFA (SPLUNC) have homology to only the N-terminal half of BPI (....). It is proposed that the BPIF proteins may function in an antimicrobial manner, however, showed a high degree of conservation of genomic organization and of exon sizes. all show the same conservation of two cysteine residues which form a critical disulphide bond (Beamer et al. 1997) The function of the BPIF family of proteins has yet to be elucidated, but due to their predicted structure and their similarity in gene location to known LPS binding proteins, BPI and LBP, it is proposed that they function in an antimicrobial manner may function in the innate immune system, against gram negative bacterial LPS, either by acting directly against bacteria in a bactericidal manner, initiating an immune response or as an anti-toxin, by reducing the inflammatory response.All members of this family appear to have the ability to bind to and transfer lipid molecules (Bingle and Craven, 2003). BPIFA1 (SPLUNC1) is secreted in the epithelium of the upper airways, where it coats the surface of the epithelium and cilia, but significantly greater expression is seen in the submucosal cells and ducts of glands associated with the upper airways (Campos MA et al. 2004; Di YP et al. 2003; Bingle L et al. 2005; Bingle L & Bingle CD 2011). BPIFA1 is considered to contribute to mucosa immunity protecting the upper airway from infections. The antibacterial properties BPIFA1 have been demonstrated with regard to Staphylococcus aureus, Streptococcus, Pseudomonas, Mycoplasma pneumonia and Klebsiella pneumonia (Di YP 2011; Gally F et al. 2011; Tsou YA et al. 201; Liu Y et al. 2013). It is also considered to have antibiofilm functionality through its ability to modulate surface tension of airway fluids (Gakhar L et al. 2010; Bartlett JA et al. 2011; Liu Y et al. 2013). In addition, BPIFA1 negatively regulates epithelial sodium channel (ENaC) function, affecting the height of the airway surface liquid, which is essential for adequate mucociliary clearance (Garcia-Caballero A et al. 2009; Hobbs CA et al. 2013; Tarran R & Redinbo MR 2014). Furthermore, BPIFA1 also shows immunomodulatory properties in different mouse models of acute airway inflammations (). The high level of BPIFA1 present in the airways under basal conditions fluctuating rapidly in response to environmental stress and upon airway inflammation. The fluctuations in the BPIFA1 levels are thought to help the local milieu in optimizing protective functions in the airways (Bingle L et al. 2007; Britto CJ and Cohn L 2015). SPLUNC2 is expressed in serous cells of the major salivary glands and in minor mucosal glands mainly secreted from the upper airway.

R-HSA-6810643 (Reactome) Epididymal protease inhibitor (EPPIN) is an androgen-regulated sperm-binding protein (Yenugu S et al. 2004). EPPIN is expressed specifically in the testis and epididymis (Richardson RT et al. 2001). EPPIN coats the surface of human testicular and epididymal spermatozoa as part of a protein complex containing lactotransferrin (LTF) and clusterin (CLU) (Wang Z et al. 2007; Paasch U et al. 2011). During ejaculation, semenogelin 1 (SEMG1) binds to EPPIN in the complex (Wang Z et al. 2005; 2007; O'Rand MG et al, 2009; 2011; Silva EJ et al. 2012). The components of the complex, EPPIN, LTF and SEMG1-derived peptides have been shown to possess microbicidal activity. EPPIN exhibited dose- and time-dependent antibacterial activity against E. coli (Yenugu S et al. 2004). While the activity of EPPIN was relatively insensitive to salt, it was completely lost on reduction and alkylation of Cys residues of EPPIN, indicating the importance of disulfide bonds (Yenugu S et al. 2004). Furthermore, EPPIN was able to induce morphological alterations of E. coli membranes as shown by scanning electron microscopy and measuring bacterial respiratory electron transport (Yenugu S et al. 2004; McCrudden MT et al. 2008). LTF is a multifunctional protein that is best known for its ability to bind iron, which eventually led to the discovery of its antibacterial activity. In addition, LTF has demonstrated potent antiviral, antifungal and antiparasitic activity towards a broad spectrum of species (Legrand D et al. 2008). SEMG1-derived peptides were found in the cationic fraction of seminal plasma and showed high levels of antibacterial activity against E. coli and B. megaterium (Bourgeon F et al. 2004; Edstrom AM et al. 2008). The EPPIN protein complex provides antimicrobial activity on the sperm surface. In addition, the binding of SEMG1 to EPPIN during ejaculation inhibits sperm progressive motility, possibly by disturbing the regulation of intracellular pH, resulting in the loss of calcium (O'Rand MG et al, 2009; O'Rand MG & Widgren EE 2012). In parallel, EPPIN inhibits the digestion of SEMG1 by the serine protease prostate specific antigen (PSA), which results in the modulation of semen liquefaction, further prolonging the inhibitory effects of SEMG1 on sperm motility (Wang Z et al. 2005; Wang ZJ et al. 2008; Silva EJ et al. 2013).

EPPIN has two potential protease inhibitory domains: a whey acid protein (WAP)-type four disulfide core (WFDC) domain and a Kunitz domain (Richardson RT et al. 2001; McCrudden MT et al. 2008). While both domains of EPPIN are involved in the protein's antibacterial activity, only the Kunitz domain is required for selective protease inhibition (McCrudden MT et al. 2008).

R-HSA-6810724 (Reactome) Peptidase inhibitor 3 (PI3) is a low-molecular-weight protein produced by epithelial and immune cells (Pfundt R et al. 1996; Molhuizen HO et al. 1993; Sallenave et al. 1994). It is secreted as a 9.9 kDa precursor protein PI3(23-117) (known as trappin-2 or pre-elafin) that contains an N-terminal 38 amino acids domain (named cementoin) and a C-terminal 57-residue domain with the whey acidic protein (WAP) structure (Nara K et al. 1994). Mature PI3 (elafin) is a 6 kDa generated via proteolytic processing of PI3(23-117), primarily by the mast cell-derived protease tryptase (Guyot N et al. 2005). Both 6kDa and 9.9 kDa proteins of PI3 possess an antimicrobial function (Baranger K et al. 2008). The antimicrobial activity of PI3 is thought to depend on its cationic nature which allows PI3 to interact with and disrupt the membranes of target organisms (Baranger K et al. 2008). In vitro, PI3 protected human cells against two major respiratory pathogens, the Gram-negative Pseudomonas aeruginosa and Gram-positive Staphylococcus aureus (Simpson AJ et al. 1999; 2001). In vivo, PI3 also protected murine lungs against the injurious effects of both bacterial pathogens (Simpson AJ et al. 2001; McMichael JW et al. 2005). In addition to the above-mentioned pathogens PI3 showed bactericidal activity in vitro against Klebsiella pneumoniae, Haemophilus influenzae, Streptococcus pneumoniae, Mycobacterium tuberculosis and Branhamella catarrhalis (Meyer-Hoffert U et al. 2003; Baranger K et al. 2008; Gomez SA et al. 2009). Furthermore PI3 possesses potent fungicidal activity against Aspergillus fumigatus and Candida albicans, which have preferential tropism for human lung tissue and other mucosae (Baranger K et al. 2008). PI3 has also been shown to possess antiviral activity against human immunodeficiency virus (HIV) and herpes simplex virus 2 (HSV2) (McNeely TB et al. 1995, 1997; Iqbal SM et al. 2009; Ghosh M et al. 2010; Drannik AG et al. 2013). The mechanism of antiviral activity remains to be clarified. Besides microbicidal activity, PI3 proteins can function as inhibitors of peptidase activity of human neutrophil elastase and proteinase 3 through the WAP domain. The antipeptidase activity of PI3 is thought to control excessive inflammation and tissue damage (Nara K et al 1994; Moreau T et al. 2008). The antipeptidase activity of the precursor protein of PI3(23-117)(trappin-2) was also found to prevent proliferation of P. aeruginosa by inhibiting bacterial serine peptidase (Bellemare A et al. 2008; 2010). However, another study showed that PI3 exerted its antibacterial effects through mechanisms independent from its intrinsic antiprotease capacity and suggested that the cationic nature of PI3 peptides is responsible for its bactericidal activity (Baranger K et al. 2008).

PI3 is constitutively expressed in a number of epithelial barriers that are constantly exposed to foreign antigens and pathogens, including skin, airway, and intestinal mucosa (Pfundt R et al. 1996). PI3 can be transcriptionally upregulated at various sites of inflammation by LPS or pro-inflammatory cytokines such as IL1B and TNF (Sallenave JM et al. 1994; Alkemade JA et al. 1994; Pfundt R et al. 2000, Simpson AJ et al. 2001).

R-HSA-6813626 (Reactome) Liver-expressed antimicrobial peptide 2 (LEAP2) is a cationic peptide, which is believed to have a protective function against bacterial infection (Krause A et al. 2003; Henriques ST et al. 2010; Hocquellet A et al. 2010). LEAP2, originally isolated from human blood, is expressed predominantly in the liver but is also produced by a wide range of other tissues and organs, including the kidney and the intestinal tract (Krause A et al. 2003; Howard A et al. 2010).

Structural analysis of LEAP2 revealed a compact central core stabilized by two disulfide bonds between Cys17-28 and Cys23-33 and a network of hydrogen bonds (Henriques ST et al. 2010; Hocquellet A et al. 2010). The central core of LEAP2 contains the majority of the arginine and lysine residues, which are clustered to form an extended, positively-charged patch on the surface of the molecule (Henriques ST et al. 2010). The terminal segments of LEAP2 are relatively unstructured and contain the majority of the hydrophobic residues (Henriques ST et al. 2010). Membrane-affinity studies show that LEAP2 membrane binding is governed by electrostatic attractions, which are sensitive to ionic strength. Truncation studies found that the C-terminal region of LEAP2 is irrelevant for both membrane binding and antimicrobial activity, whereas the N-terminal (hydrophobic domain) and core regions (cationic domain) are essential (Henriques ST et al. 2010).

LEAP2 showed antimicrobial activity against Bacillus subtilis at low ionic strength (Henriques ST et al. 2010). The inability of LEAP2 to inhibit B. subtilis growth at physiologically relevant salt concentration is consistent with a proposed electrostatic contribution to membrane binding (Henriques ST et al. 2010). Other bacteria such as Gram-positive Bacillus megaterium, Staphylococcus carnosus, Micrococcus luteus and Gram-negative Neisseria cinerea are also sensitive to treatment with LEAP2 (Krause A et al. 2003). Furthermore, the native and reduced forms of LEAP2 show similar membrane affinity and antimicrobial activities; this suggests that disulfide bonds are not essential for bactericidal activity (Henriques ST et al. 2010; Hocquellet A et al. 2010). LEAP2 did not affect the growth of Escherichia coli and S. aureus at physiological or low ionic strength (Henriques ST et al. 2010). LEAP2 was found to be inactive against Pseudomonas fluorescens (Krause A et al. 2003). The antimicrobial potential of LEAP2 against E. coli, B. subtilis, B. megaterium, and M. luteus was significantly lower than that of cathelicidin LL37 (Hocquellet A et al. 2010). Further study is needed to clarify the antimicrobial activity of LEAP2.

LEAP2 is highly conserved throughout vertebrates, particularly in mammals suggesting that LEAP2 has additional physiological functions that remain to be elucidated (Krause A et al. 2003; Zhang YA et al. 2004; Townes CL et al. 2009; Henriques ST et al. 2010).

R-HSA-6813659 (Reactome) Polymorphonuclear neutrophils (PMNs) are the most abundant circulating blood leukocytes that are rapidly recruited to sites of infection by host- and/or pathogen-derived components. PMNs provide the first-line defense against infection killing invading pathogens and resolving the inflammation they cause (Kobayashi SD et al. 2005). Activated neutrophils are known to release a variety of molecules, including the neutrophil serine proteases such as neutrophil elastase (ELINE), proteinase 3 (PRTN3) and cathepsin G (CTSG) (Garwicz D et al. 2005). Neutrophil serine proteases contribute to antimicrobial defense by
  • attacking membrane-associated (E. coli) or capsule proteins (S.pneumonia), which leads to loss of membrane integrity (Belaaouaj A et al. 2000; Standish AJ & Weiser JN 2009)
  • processing host immune proteins to generate antimicrobial peptides that can directly kill bacteria (Sorensen OE et al. 2001)
  • targeting and inactivating bacterial virulence factors to attenuate bacteria (Weinrauch Y et al. 2002; Lopez-Boado YS et al. 2004)

R-HSA-8862300 (Reactome) Human lysozyme (LYZ), also known as 1,4-beta-N-acetylmuramidase C, is found in human secretions such as tears, milk, mucus and saliva (Surna A et al. 2009; Minami J et al. 2015; Sahin O et al. 2016; Masschalck B & Michiels CW. 2003). LYZ functions primarily as a bacteriolytic agent by catalyzing hydrolysis of (1->4)-beta-linkages between N-acetylmuramic acid and N-acetyl-D-glucosamine residues in the bacterial cell wall peptidoglycan (Schindler M et al. 1977; Surna A et al. 2009). Nonenzymatic bactericidal activity of LYZ has been documented as well and is generally associated with the cationic properties of LYZ (Ito Y et al. 1997; Nash JA et al. 2006). LYZ acts against both Gram-positive and Gram-negative bacteria such as Peptostreptococcus micros, Eubacterium nodatum, Eikenella corrodens, Fusobacterium periodontium and Campylobacter rectus (Laible & Germaine 1985, Surna A et al. 2009; Tenovuo J 2002).
R-HSA-8862320 (Reactome) Lysozyme (LYZ), also known as 1,4-beta-N-acetylmuramidase C, is a host hydrolytic enzyme with muramidase activity that hydrolyzes (1->4)-beta-linkages between N-acetylmuramic acid and N-acetyl-D-glucosamine residues in the bacterial cell wall peptidoglycan (Schindler M et al. 1977; Surna A et al. 2009). LYZ acts against both gram-positive and gram-negative bacteria such as Peptostreptococcus micros, Eubacterium nodatum, Eikenella corrodens, Fusobacterium periodontium and Campylobacter rectus (Surna A et al. 2009; Tenovuo J 2002). The muramidase activity of LYZ is thought to be more effective against Gram-positive bacteria with their peptidoglycan layer exposed to the extracellular milieu. The detailed mechanism by which LYZ hydrolyses its substrate is described for hen egg-white lysozyme (HEWL) (Blake CC et al. 1967; Vocadlo DJ et al. 2001).

Many pathogens such as Streptococcus pneumoniae have evolved lysozyme resistance to prevent peptidoglycan hydrolysis. The primary mechanism for lysozyme resistance in both Gram-positive and Gram-negative organisms appears to be direct modification of peptidoglycan; however, modification of other cell wall-linked components, such as teichoic acid, may also contribute to resistance (Amano K & Williams JC 1983; Bera A et al. 2005; Pushkaran AC et al. 2015).

LYZ is found in many human secretions such as tears, milk, mucus and saliva (Surna A et al. 2009; Minami J et al. 2015; Sahin O et al. 2016; Masschalck B & Michiels CW. 2003).

R-HSA-8862771 (Reactome) Human group IIA secreted phospholipase A2 (PLA2G2A, sPLA2-IIA) is an acute phase protein that is induced in the serum under inflammatory conditions (Crowl RM et al. 1991; Lindbom J et al. 2002). PLA2G2A is a highly cationic protein with a positive charge globally distributed over the protein surface (Wery LP et al. 1991; Scott DL et al. 1994; Birts CN et al. 2010). The structure supports two functions of the protein
  • An antibacterial role where the enzyme catalyzes the calcium-dependent hydrolysis of phospholipids in the bacterial membranes causing leakage of cell content (Buckland AG et al. 2000a,b; Foreman-Wykert AK et al. 1999; Beers SA et al. 2002; Nevalainen TJ et al. 2008)
  • A proposed non-catalytic role in which PLA2G2A forms supramolecular aggregates with anionic phospholipid vesicles or debris (Bezzine S et al. 2002; Birts CN et al. 2008). These aggregates are then internalized via interactions with cell surface heparin sulphate proteoglycans and macropinocytosis for disposal by macrophages.

PLA2G2A shows bactericidal activity against various bacterial pathogens, in particular, against gram-positive bacteria such as Micrococcus luteus, Listeria innocua and Staphylococcus aureus though the sensitivity varies greatly between species (Buckland AG et al. 2000b; Beers SA et al. 2002; Koprivnjak T et al. 2002).

R-HSA-8948027 (Reactome) Human ribonucleases (RNase) 3, 6 and 7, which belong to the RNase A superfamily and are secreted upon infection, interact with the bacterial cell membrane (Torrent M et al. 2010; Pulido D et al. 2016a, b).

RNase A family is a vertebrate-specific gene family (Goo SM & Cho S 2013). Members of RNase A family share specific elements of sequence homology, a unique disulfide-bonded tertiary structure, and the ability to hydrolyze polymeric RNA (Beintema JJ & Kleineidam RG 1998; Rosenberg HF 2008). Eight catalytically active members are found in humans: RNase1 (pancreatic RNase), RNase2 (eosinophil derived neurotoxin/EDN), RNase3 (eosinophil cationic protein/ECP), RNase4, RNase5 (angiogenin), RNase6, RNase7 (skin-derived RNase), and RNase8 (divergent paralog of RNase7) (Sorrentino S 2010). Analysis of human genome sequence has revealed the existence of five additional RNases named as RNases 9-13, although they appear to lose enzymatic activity (Devor EJ et al. 2004; Castella S et al. 2004; Cho S et al. 2005). All human RNase A family members encode relatively small polypeptides of 14 to 16kDa containing signal peptides of 20 to 28 amino acids for protein secretion. Mature RNases contain 6 to 8 cysteine residues that are crucial to hold the overall tertiary structure (Sorrentino S 2010). Apart from the ribonuclease activity the RNase A family members have been implicated in a wide variety of biological actions including antipathogen and immunomodulatory activities (Harder J & Schroder JM 2002; Rudolph B et al. 2006; Boix E et al. 2008; Boix and Nogués, 2007; Spencer JD et al. 2011; Becknell B et al. 2015; Rosenberg HF 2015). Evidence of antimicrobial properties displayed by distantly related members ascribed to the family an ancestral role in host defence (Pizzo E & D’Alessio G 2007; Rosenberg HF et al. 2008).

RNase3, RNase6 and RNase7 have been identified as the most potent human antibacterial ribonucleases with a broad antimicrobial action against Gram-positive and Gram-negative bacteria (Pulido D et al. 2013, 2016; Zhang J et al. 2003; Boix E et al. 2008; Torrent M et al. 2010). Mutagenesis analysis revealed that ribonuclease-inactive RNase7 protein exhibited similar anti-microbial activity against P. aeruginosa, E. faecium and E. coli as the wild-type protein suggesting that RNase7 may kill bacteria independently of its ribonuclease catalytic activity (Huang YC et al. 2007; Koten B et al. 2009). Similar results were reported on microbicidal effect of ribonuclease-inactive RNase3 and 6 proteins against S. aureus (Rosenberg HF 1995; Pulido D et al. 2016a). Being cationic proteins with a high pI, RNase3, 6 and 7 interact with anionic components of biological membranes (Zhang J et al. 2003; Boix E et al. 2008; Torrent M et al. 2010; Boix E et al. 2012; Pulido D et al. 2016a). RNase3, 6 and 7 present, respectively, a high number of either Arg, His or Lys surface-exposed residues that may contribute to their distinct bactericidal mechanisms of action (Torrent M et al. 2010; Prats-Ejarque G et al. 2016). RNase3 displays a membrane disruption capacity that is dependent on both surface exposed hydrophobic and cationic residues. RNase3 can bind and partially insert into the lipid bilayers, promoting its aggregation and final lysis, following a carpet-like mechanism. The RNase3 agglutination process precedes the bacterial death and lysis event. The antimicrobial properties of the RNase6 are comparable to its RNase3 homolog and correlate to the bacterial cell damage and agglutination activities (Pulido D et al. 2016a). In contrast, RNase7 has no significant membrane aggregation capacity (Torrent M et al. 2010). RNase7 binds and permeabilizes the bacterial membrane displaying a much higher leakage capacity compared to RNase3 (Torrent M et al. 2010; Huang YC et al. 2007). Membrane permeabilization by RNase7 required four clustered lysine residues but no catalytic residues (Huang YC et al. 2007). Binding to PGN and LPS has been reported for RNases 3 and 7 (Torrent M et al. 2010; Pulido D et al. 2016b). Studies using a battery of progressively truncated LPS-defective E. coli strains correlated the LPS interaction with the protein cell agglutination and bactericidal activities (Pulido D et al. 2012). Further work indicated that RNase3 and RNase 6 high cell agglutination activity towards Gram negative species is retained by their respective N-terminus peptides (Torrent M et al. 2012, 2013; Pulido D et al. 2016c). In particular, the RNase3 N-terminus encompasses a specific patch (Y33-R36) required for LPS binding and an hydrophobic aggregation prone region (A8-I16) that mediates the protein self amyloid- like aggregation and promotes the cell death.

REG3A

hexamer:anionic

phospholipid
ArrowR-HSA-6801762 (Reactome)
REG3A(27-175)/REG3G(27-175)R-HSA-6801766 (Reactome)
REG3A(27-37)/REG3G(27-37)ArrowR-HSA-6801766 (Reactome)
REG3A(38-175), REG3G(38-175):peptidoglycanArrowR-HSA-6801808 (Reactome)
REG3A(38-175), REG3G(38-175)ArrowR-HSA-6801766 (Reactome)
REG3A(38-175), REG3G(38-175)R-HSA-6801808 (Reactome)
REG3A(38-175):anionic phospholipidsArrowR-HSA-6801776 (Reactome)
REG3A(38-175):anionic phospholipidsR-HSA-6801762 (Reactome)
REG3A(38-175)R-HSA-6801776 (Reactome)
RNASE3,RNASE7,RNASE6,(RNASE8)R-HSA-6803063 (Reactome)
RNASE3,RNASE7,RNASE6,(RNASE8)R-HSA-8948027 (Reactome)
RNASEs 3,6,7,(8):LPS,PGNArrowR-HSA-6803063 (Reactome)
RNASEs

3,6,7,(8):anionic

phospholipids
ArrowR-HSA-8948027 (Reactome)
S100A7, S100A7A:Ca2+:Zn2+ArrowR-HSA-6798489 (Reactome)
S100A7, S100A7A:Ca2+R-HSA-6798489 (Reactome)
S100A8:S100A9:Ca2+:Mn2+:Na+ArrowR-HSA-6798528 (Reactome)
S100A8:S100A9:Ca2+:Zn2+ArrowR-HSA-6798474 (Reactome)
S100A8:S100A9:Ca2+R-HSA-6798474 (Reactome)
S100A8:S100A9:Ca2+R-HSA-6798528 (Reactome)
SLC11A1mim-catalysisR-HSA-435171 (Reactome)
SSA1,SSA2R-HSA-6807581 (Reactome)
Trypsin 2, 3mim-catalysisR-HSA-6801766 (Reactome)
Zn2+ArrowR-HSA-6789072 (Reactome)
Zn2+ArrowR-HSA-6799959 (Reactome)
Zn2+ArrowR-HSA-6799977 (Reactome)
Zn2+R-HSA-6798474 (Reactome)
Zn2+R-HSA-6798489 (Reactome)
Zn2+R-HSA-6803104 (Reactome)
betaGlcNAcArrowR-HSA-8862320 (Reactome)
unknown peptidasemim-catalysisR-HSA-6803060 (Reactome)

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