Miscellaneous transport and binding events (Homo sapiens)

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13. Syeda R, Qiu Z, Dubin AE, Murthy SE, Florendo MN, Mason DE, Mathur J, Cahalan SM, Peters EC, Montal M, Patapoutian A.; ''LRRC8 Proteins Form Volume-Regulated Anion Channels that Sense Ionic Strength.''; PubMed Europe PMC Scholia
14. Zsurka G, Gregán J, Schweyen RJ.; ''The human mitochondrial Mrs2 protein functionally substitutes for its yeast homologue, a candidate magnesium transporter.''; PubMed Europe PMC Scholia
15. Debily MA, Marhomy SE, Boulanger V, Eveno E, Mariage-Samson R, Camarca A, Auffray C, Piatier-Tonneau D, Imbeaud S.; ''A functional and regulatory network associated with PIP expression in human breast cancer.''; PubMed Europe PMC Scholia
16. Russell ST, Russell ST, Zimmerman TP, Domin BA, Tisdale MJ.; ''Induction of lipolysis in vitro and loss of body fat in vivo by zinc-alpha2-glycoprotein.''; PubMed Europe PMC Scholia
17. Azim AC, Knoll JH, Beggs AH, Chishti AH.; ''Isoform cloning, actin binding, and chromosomal localization of human erythroid dematin, a member of the villin superfamily.''; PubMed Europe PMC Scholia
18. Sánchez LM, López-Otín C, Bjorkman PJ.; ''Biochemical characterization and crystalization of human Zn-alpha2-glycoprotein, a soluble class I major histocompatibility complex homolog.''; PubMed Europe PMC Scholia
19. Hassan MI, Bilgrami S, Kumar V, Singh N, Yadav S, Kaur P, Singh TP.; ''Crystal structure of the novel complex formed between zinc alpha2-glycoprotein (ZAG) and prolactin-inducible protein (PIP) from human seminal plasma.''; PubMed Europe PMC Scholia
20. Elmonem MA, Veys KR, Soliman NA, van Dyck M, van den Heuvel LP, Levtchenko E.; ''Cystinosis: a review.''; PubMed Europe PMC Scholia
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22. Citterio L, Tizzoni L, Catalano M, Zerbini G, Bianchi G, Barlassina C.; ''Expression analysis of the human adducin gene family and evidence of ADD2 beta4 multiple splicing variants.''; PubMed Europe PMC Scholia
23. Johnsen LB, Rasmussen LK, Petersen TE, Berglund L.; ''Characterization of three types of human alpha s1-casein mRNA transcripts.''; PubMed Europe PMC Scholia
24. Jézégou A, Llinares E, Anne C, Kieffer-Jaquinod S, O'Regan S, Aupetit J, Chabli A, Sagné C, Debacker C, Chadefaux-Vekemans B, Journet A, André B, Gasnier B.; ''Heptahelical protein PQLC2 is a lysosomal cationic amino acid exporter underlying the action of cysteamine in cystinosis therapy.''; PubMed Europe PMC Scholia
25. Voss FK, Ullrich F, Münch J, Lazarow K, Lutter D, Mah N, Andrade-Navarro MA, von Kries JP, Stauber T, Jentsch TJ.; ''Identification of LRRC8 heteromers as an essential component of the volume-regulated anion channel VRAC.''; PubMed Europe PMC Scholia
26. Qiu Z, Dubin AE, Mathur J, Tu B, Reddy K, Miraglia LJ, Reinhardt J, Orth AP, Patapoutian A.; ''SWELL1, a plasma membrane protein, is an essential component of volume-regulated anion channel.''; PubMed Europe PMC Scholia
27. Williams CJ, Pendleton A, Bonavita G, Reginato AJ, Hughes AE, Peariso S, Doherty M, McCarty DJ, Ryan LM.; ''Mutations in the amino terminus of ANKH in two US families with calcium pyrophosphate dihydrate crystal deposition disease.''; PubMed Europe PMC Scholia
28. Nürnberg P, Thiele H, Chandler D, Höhne W, Cunningham ML, Ritter H, Leschik G, Uhlmann K, Mischung C, Harrop K, Goldblatt J, Borochowitz ZU, Kotzot D, Westermann F, Mundlos S, Braun HS, Laing N, Tinschert S.; ''Heterozygous mutations in ANKH, the human ortholog of the mouse progressive ankylosis gene, result in craniometaphyseal dysplasia.''; PubMed Europe PMC Scholia
29. Zhou H, Clapham DE.; ''Mammalian MagT1 and TUSC3 are required for cellular magnesium uptake and vertebrate embryonic development.''; PubMed Europe PMC Scholia
30. Mongin AA.; ''Volume-regulated anion channel--a frenemy within the brain.''; PubMed Europe PMC Scholia
31. Anikster Y, Shotelersuk V, Gahl WA.; ''CTNS mutations in patients with cystinosis.''; PubMed Europe PMC Scholia
32. Joshi R, Gilligan DM, Otto E, McLaughlin T, Bennett V.; ''Primary structure and domain organization of human alpha and beta adducin.''; PubMed Europe PMC Scholia
33. Reichenberger E, Tiziani V, Watanabe S, Park L, Ueki Y, Santanna C, Baur ST, Shiang R, Grange DK, Beighton P, Gardner J, Hamersma H, Sellars S, Ramesar R, Lidral AC, Sommer A, Raposo do Amaral CM, Gorlin RJ, Mulliken JB, Olsen BR.; ''Autosomal dominant craniometaphyseal dysplasia is caused by mutations in the transmembrane protein ANK.''; PubMed Europe PMC Scholia
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35. Jentsch TJ, Lutter D, Planells-Cases R, Ullrich F, Voss FK.; ''VRAC: molecular identification as LRRC8 heteromers with differential functions.''; PubMed Europe PMC Scholia

History

External references

DataNodes

Name	Type	Database reference	Comment
ADD1	Protein	P35611 (Uniprot-TrEMBL)
ADD1:ADD2:DMTN	Complex	R-HSA-5226996 (Reactome)
ADD1:ADD2	Complex	R-HSA-420433 (Reactome)
ADD1:ADD3:DMTN	Complex	R-HSA-5226961 (Reactome)
ADD1:ADD3	Complex	R-HSA-5227016 (Reactome)
ADD2	Protein	P35612 (Uniprot-TrEMBL)
ADD3(2-706)	Protein	Q9UEY8 (Uniprot-TrEMBL)
ANKH	Protein	Q9HCJ1 (Uniprot-TrEMBL)
AZGP1	Protein	P25311 (Uniprot-TrEMBL)
AZGP1:PIP	Complex	R-HSA-5251992 (Reactome)
AZGP1	Protein	P25311 (Uniprot-TrEMBL)
CSN polymer		R-HSA-5340146 (Reactome)
CSN polymer:CaPO4	Complex	R-HSA-5340155 (Reactome)
CSN polymer		R-HSA-5340146 (Reactome)
CTNS	Protein	O60931 (Uniprot-TrEMBL)
CaPO4	Metabolite	CHEBI:77635 (ChEBI)
CaPO4	Metabolite	CHEBI:77635 (ChEBI)
Cl-	Metabolite	CHEBI:17996 (ChEBI)
CySS-	Metabolite	CHEBI:16283 (ChEBI)
DMTN	Protein	Q08495 (Uniprot-TrEMBL)
DMTN	Protein	Q08495 (Uniprot-TrEMBL)
H+	Metabolite	CHEBI:15378 (ChEBI)
I-	Metabolite	CHEBI:16382 (ChEBI)
I-, Cl-	Complex	R-ALL-8941540 (Reactome)
I-, Cl-	Complex	R-ALL-8941541 (Reactome)
L-Arg	Metabolite	CHEBI:32682 (ChEBI)
L-Arg,L-His,L-Lys	Complex	R-ALL-8932838 (Reactome)
L-Arg,L-His,L-Lys	Complex	R-ALL-8932842 (Reactome)
L-His	Metabolite	CHEBI:32513 (ChEBI)
L-Lys	Metabolite	CHEBI:32551 (ChEBI)
LRRC8A	Protein	Q8IWT6 (Uniprot-TrEMBL)
LRRC8B	Protein	Q6P9F7 (Uniprot-TrEMBL)
LRRC8C	Protein	Q8TDW0 (Uniprot-TrEMBL)
LRRC8D	Protein	Q7L1W4 (Uniprot-TrEMBL)
LRRC8E	Protein	Q6NSJ5 (Uniprot-TrEMBL)
MAGT1	Protein	Q9H0U3 (Uniprot-TrEMBL)
MMGT1	Protein	Q8N4V1 (Uniprot-TrEMBL)
MRS2	Protein	Q9HD23 (Uniprot-TrEMBL)
Mg2+	Metabolite	CHEBI:18420 (ChEBI)
NIPA1	Protein	Q7RTP0 (Uniprot-TrEMBL)
NIPA2	Protein	Q8N8Q9 (Uniprot-TrEMBL)
NIPAL1	Protein	Q6NVV3 (Uniprot-TrEMBL)
NIPAL2	Protein	Q9H841 (Uniprot-TrEMBL)
NIPAL3	Protein	Q6P499 (Uniprot-TrEMBL)
NIPAL4	Protein	Q0D2K0 (Uniprot-TrEMBL)
NIPAs	Complex	R-HSA-5336426 (Reactome)
PIP	Protein	P12273 (Uniprot-TrEMBL)
PIP	Protein	P12273 (Uniprot-TrEMBL)
PPi	Metabolite	CHEBI:29888 (ChEBI)
PQLC2	Protein	Q6ZP29 (Uniprot-TrEMBL)
TUSC3(1-348)	Protein	Q13454 (Uniprot-TrEMBL)
VRAC heteromer	Complex	R-HSA-8941515 (Reactome)

Annotated Interactions

Source	Target	Type	Database reference	Comment
	ADD1:ADD2:DMTN	Arrow	R-HSA-5226979 (Reactome)
ADD1:ADD2			R-HSA-5226979 (Reactome)
	ADD1:ADD3:DMTN	Arrow	R-HSA-5226999 (Reactome)
ADD1:ADD3			R-HSA-5226999 (Reactome)
ANKH		mim-catalysis	R-HSA-5226964 (Reactome)
	AZGP1:PIP	Arrow	R-HSA-5252072 (Reactome)
AZGP1			R-HSA-5252072 (Reactome)
	CSN polymer:CaPO4	Arrow	R-HSA-5340124 (Reactome)
CSN polymer			R-HSA-5340124 (Reactome)
CTNS		mim-catalysis	R-HSA-5340130 (Reactome)
CaPO4			R-HSA-5340124 (Reactome)
	CySS-	Arrow	R-HSA-5340130 (Reactome)
CySS-			R-HSA-5340130 (Reactome)
DMTN			R-HSA-5226979 (Reactome)
DMTN			R-HSA-5226999 (Reactome)
	H+	Arrow	R-HSA-5340130 (Reactome)
H+			R-HSA-5340130 (Reactome)
	I-, Cl-	Arrow	R-HSA-8941543 (Reactome)
I-, Cl-			R-HSA-8941543 (Reactome)
	L-Arg,L-His,L-Lys	Arrow	R-HSA-8932851 (Reactome)
L-Arg,L-His,L-Lys			R-HSA-8932851 (Reactome)
MAGT1		mim-catalysis	R-HSA-5339538 (Reactome)
MMGT1		mim-catalysis	R-HSA-5336454 (Reactome)
MRS2		mim-catalysis	R-HSA-5336466 (Reactome)
	Mg2+	Arrow	R-HSA-5336453 (Reactome)
	Mg2+	Arrow	R-HSA-5336454 (Reactome)
	Mg2+	Arrow	R-HSA-5336466 (Reactome)
	Mg2+	Arrow	R-HSA-5339528 (Reactome)
	Mg2+	Arrow	R-HSA-5339538 (Reactome)
Mg2+			R-HSA-5336453 (Reactome)
Mg2+			R-HSA-5336454 (Reactome)
Mg2+			R-HSA-5336466 (Reactome)
Mg2+			R-HSA-5339528 (Reactome)
Mg2+			R-HSA-5339538 (Reactome)
NIPAs		mim-catalysis	R-HSA-5336453 (Reactome)
PIP			R-HSA-5252072 (Reactome)
	PPi	Arrow	R-HSA-5226964 (Reactome)
PPi			R-HSA-5226964 (Reactome)
PQLC2		mim-catalysis	R-HSA-8932851 (Reactome)
			R-HSA-5226964 (Reactome)	Progressive ankylosis protein homolog (ANKH) is a putative transmembrane pyrophosphate (PPi) transport channel protein found in osteoblasts of various bones. It mediates the transport of cytosolic PPi to the extracellular matrix. Abnormal transport of PPi is implicated in familial calcium pyrophosphate dihydrate deposition (CPPD) disease. There are two forms of CPPD disease: CCAL1 and CCAL2. Defects in ANKH can cause chondrocalcinosis (CCAL2; MIM:118600), a chronic condition in which PPi crystals deposit in the joint fluid, cartilage, and periarticular tissues and there is calcium deposition in articular cartilage (Pendleton et al. 2002, Williams et al. 2002, Williams et al. 2003). Defects in ANKH can also cause craniometaphyseal dysplasia, autosomal dominant (CMDD; MIM:123000), an osteochondrodysplasia characterised by progressive thickening and increased mineral density of craniofacial bones and abnormal modelling of metaphyses in long bones (Nurnberg et al. 2001, Reichenberger et al. 2001).
			R-HSA-5226979 (Reactome)	Alpha-adducin (ADD1 aka ADDA) (Joshi et al. 1991) is a ubiquitously expressed, membrane-cytoskeletal protein that can promote the assembly of the spectrin-actin network. It is functional in a heterodimeric form, in complex with either a beta (ADD2 aka ADDB) (Khan et al. 2008) or a gamma (ADD3 aka ADDL) subunit (Citterio et al. 2003). Either complex is able to bind dematin (DMTN) (Azim et al. 1995), a membrane-cytoskeletal protein that can induce F-actin bundles formation and stabilization. It can also bind the erythrocyte membrane glucose transporter 1 (SLC2A1 aka GLUT1), and hence stabilise the spectrin-actin network to the erythrocytic plasma membrane (Khan et al. 2008).
			R-HSA-5226999 (Reactome)	Alpha-adducin (ADD1 aka ADDA) (Joshi et al. 1991) is a ubiquitously expressed, membrane-cytoskeletal protein that can promote the assembly of the spectrin-actin network. It is functional in a heterodimeric form, in complex with either a beta (ADD2 aka ADDB) (Khan et al. 2008) or a gamma (ADD3 aka ADDL) subunit (Citterio et al. 2003). Either complex is able to bind dematin (DMTN) (Azim et al. 1995), a membrane-cytoskeletal protein that can induce F-actin bundles formation and stabilization. It can also bind the erythrocyte membrane glucose transporter 1 (SLC2A1 aka GLUT1), and hence stabilise the spectrin-actin network to the erythrocytic plasma membrane (Khan et al. 2008).
			R-HSA-5252072 (Reactome)	Zinc-alpha-2-glycoprotein (AZGP1) (Sanchez et al. 1997), a 41 kDa protein secreted in many bodily fluids, is thought to stimulate lipolysis and be the cause of the excessive fat loss seen in cancer cachexia (Russell et al. 2004). AZGP1 is able to bind prolactin-inducible protein (PIP) (Myal et al. 1991), another secreted protein overexpressed in certain breast cancers (Hassan et al. 2008, Debily et al. 2009).
			R-HSA-5336453 (Reactome)	Magnesium (Mg2+) is required for the catalytic activity of numerous metalloenzymes within a variety of subcellular organelles. Magnesium transporters NIPA1, 2, 3, 4 (NIPA1,2,3,4) and NIPA-like proteins 2 and 2 (NIPAL2 and 3) can act as Mg2+ transporters. They may also transport other divalent cations such as Fe2+, Mn2+ and Ba2+ but to a lesser extent than Mg2+. Human NIPA1 mediates Mg2+ uptake when expressed in Xenopus oocytes (Goytain et al. 2007). The other NIPA members are included as candidates based on NIPA1 function.
			R-HSA-5336454 (Reactome)	Magnesium (Mg2+) is required for the catalytic activity of numerous metalloenzymes within a variety of subcellular organelles. Membrane magnesium transporter 1 (MMGT1) mediates the uptake of Mg2+ across the Golgi membrane. The human MMGT1 function is inferred from mouse experiments using the orthologous Mmgt1 and 2 (Goytain & Quamme 2008). MMGT1 is also found on the ER membrane as a component of the ER membrane protein complex (EMC) which functions to degrade incorrectly folded or assembled proteins by a ubiquitin- and proteasome-dependent process known as ER-associated degradation (ERAD). MMGT1 is not implicated in this function of protein quality control (Christianson et al. 2011).
			R-HSA-5336466 (Reactome)	Magnesium (Mg2+) is required for the catalytic activity of numerous metalloenzymes within a variety of subcellular organelles. Magnesium transporter MRS2 homolog, mitochondrial (MRS2) mediates the influx of Mg2+ into the mitochondrial matrix (Zsurka et al. 2001). MRS2 is located on the inner mitochondrial membrane and its expression in yeast with a Mrs2-1 knock-out mutant partly restores mitochondrial magnesium concentrations that are otherwise much reduced (Zsurka et al. 2001).
			R-HSA-5339528 (Reactome)	Magnesium (Mg2+) is required for the catalytic activity of numerous metalloenzymes within a variety of subcellular organelles. Tumor suppressor candidate 3 (TUSC3) is expressed in most non-lymphoid cells and tissues and is an essential protein in Mg2+ uptake into cells (Zhou & Clapham 2009).
			R-HSA-5339538 (Reactome)	Magnesium (Mg2+) is required for the catalytic activity of numerous metalloenzymes within a variety of subcellular organelles. Magnesium transporter protein 1 (MAGT1) is ubiquitously expressed in all human tissues and is upregulated by low Mg2+ concentrations. It is an essential protein in Mg2+ uptake into cells (Zhou & Clapham 2009, Goytain & Quamme 2005).
			R-HSA-5340124 (Reactome)	In milk, caseins (CSNs) interact with calcium phosphate (CaPO4), forming large stable colloidal particles called micelles. These micelles make it possible to maintain a supersaturated CaPO4 concentration in milk, providing the newborn with sufficient calcium phosphate for the mineralisation of calcified tissues. Human alpha-S1-casein (CSN1S1) is able to bind CaPO4 in milk. CSN1S1 forms a disulfide cross-linked heteropolymer with kappa-casein (CSN3), another CSN that is thought to stabilise micelle formation and thus preventing casein precipitation in milk (Brignon et al. 1985, Rasmussen et al. 1995, Johnson et al. 1995).
			R-HSA-5340130 (Reactome)	Cystinosin (CTNS) is an integral lysosomal membrane protein which can transport L-cystine (CySS-, the oxidative product of two cysteine molecules linked via a disulfide bond) together with H+ out of lysosomes. CySS- is a component of hair, skin and nails. Defects in CTNS cause cystinosis, lysosomal storage-type diseases due to defective transport of CySS- across the lysosomal membrane (Town et al. 1998, Anikster et al. 1999; review Elmonem et al. 2016). Patients with cystinosis frequently exhibit blond hair and a fair complexion, suggesting an involvement in melanogenesis. Chiaverini et al. show CTNS is also localised to melanosomes. CTNS silencing led to a 75% reduction of melanin synthesis, caused by a degradation of tyrosinase (the enzyme responsible for melanin biosynthesis), thereby identifying a role for CTNS in melanogenesis (Chiaverini et al. 2012).
			R-HSA-8932851 (Reactome)	Lysosomal amino acid transporter 1 homolog (PQLC2) is a lysosomal membrane-associated protein that mediates the efflux of the cationic amino acids L-Arg, L-His and L-Lys from the lysosomal lumen to the cytosol, contributing to their homeostasis in cells. PQLC2 belongs to a family of heptahelical membrane proteins, together with the founding member cystinosin, the lysosomal cystine exporter defective in cystinosis. The family are characterised by a duplicated motif termed the PQ loop (Jezegou et al. 2012).
			R-HSA-8941543 (Reactome)	Maintaining a constant cell volume in response to extracellular or intracellular osmotic changes is critical for cellular homeostasis. The volume-regulated anion channel (VRAC), localised on the plasma membrane, plays a key role in this process. VRAC is proposed to be a heterohexamer composed of an essential subunit, the volume-regulated anion channel subunit LRRC8A (SWELL1) (Qiu et al. 2014, Voss et al. 2014) and any one of four other LRRC8s; LRRC8B, LRRC8C, LRRC8D and LRRC8E (Syeda et al. 2016, Mongin 2016). The resulting diverse hexameric channels that can form are thought to produce diverse physiological roles for VRAC (Jentsch et al. 2016). VRAC mediates the so-called swelling-induced Cl- current (ICl, swell) which is primarily carried by Cl- but can also be other ions and small organic osmolytes. Indeed, VRAC has highest affinity for I- followed by Cl-. It counters cell swelling by causing a regulatory volume decrease (RVD) through ion and osmolyte efflux followed by release of osmotically-obligated water.
TUSC3(1-348)		mim-catalysis	R-HSA-5339528 (Reactome)
VRAC heteromer		mim-catalysis	R-HSA-8941543 (Reactome)