Sulfur amino acid metabolism (Homo sapiens)

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Bibliography

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2. Camacho-Vanegas O, Camacho SC, Till J, Miranda-Lorenzo I, Terzo E, Ramirez MC, Schramm V, Cordovano G, Watts G, Mehta S, Kimonis V, Hoch B, Philibert KD, Raabe CA, Bishop DF, Glucksman MJ, Martignetti JA.; ''Primate genome gain and loss: a bone dysplasia, muscular dystrophy, and bone cancer syndrome resulting from mutated retroviral-derived MTAP transcripts.''; PubMed Europe PMC Scholia
3. Feng C, Tollin G, Enemark JH.; ''Sulfite oxidizing enzymes.''; PubMed Europe PMC Scholia
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7. Steegborn C, Clausen T, Sondermann P, Jacob U, Worbs M, Marinkovic S, Huber R, Wahl MC.; ''Kinetics and inhibition of recombinant human cystathionine gamma-lyase. Toward the rational control of transsulfuration.''; PubMed Europe PMC Scholia
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9. Smeets A, Evrard C, Landtmeters M, Marchand C, Knoops B, Declercq JP.; ''Crystal structures of oxidized and reduced forms of human mitochondrial thioredoxin 2.''; PubMed Europe PMC Scholia
10. Kimura Y, Toyofuku Y, Koike S, Shibuya N, Nagahara N, Lefer D, Ogasawara Y, Kimura H.; ''Identification of H2S3 and H2S produced by 3-mercaptopyruvate sulfurtransferase in the brain.''; PubMed Europe PMC Scholia
11. Doyle JM, Schininà ME, Bossa F, Doonan S.; ''The amino acid sequence of cytosolic aspartate aminotransferase from human liver.''; PubMed Europe PMC Scholia
12. Wilson HL, Wilkinson SR, Rajagopalan KV.; ''The G473D mutation impairs dimerization and catalysis in human sulfite oxidase.''; PubMed Europe PMC Scholia
13. Tiranti V, Viscomi C, Hildebrandt T, Di Meo I, Mineri R, Tiveron C, Levitt MD, Prelle A, Fagiolari G, Rimoldi M, Zeviani M.; ''Loss of ETHE1, a mitochondrial dioxygenase, causes fatal sulfide toxicity in ethylmalonic encephalopathy.''; PubMed Europe PMC Scholia
14. Turner MA, Yuan CS, Borchardt RT, Hershfield MS, Smith GD, Howell PL.; ''Structure determination of selenomethionyl S-adenosylhomocysteine hydrolase using data at a single wavelength.''; PubMed Europe PMC Scholia
15. Szegedi SS, Castro CC, Koutmos M, Garrow TA.; ''Betaine-homocysteine S-methyltransferase-2 is an S-methylmethionine-homocysteine methyltransferase.''; PubMed Europe PMC Scholia
16. Holzerova E, Danhauser K, Haack TB, Kremer LS, Melcher M, Ingold I, Kobayashi S, Terrile C, Wolf P, Schaper J, Mayatepek E, Baertling F, Friedmann Angeli JP, Conrad M, Strom TM, Meitinger T, Prokisch H, Distelmaier F.; ''Human thioredoxin 2 deficiency impairs mitochondrial redox homeostasis and causes early-onset neurodegeneration.''; PubMed Europe PMC Scholia
17. Berger LC, Wilson J, Wood P, Berger BJ.; ''Methionine regeneration and aspartate aminotransferase in parasitic protozoa.''; PubMed Europe PMC Scholia
18. Aita N, Ishii K, Akamatsu Y, Ogasawara Y, Tanabe S.; ''Cloning and expression of human liver rhodanese cDNA.''; PubMed Europe PMC Scholia
19. Mato JM, Alvarez L, Ortiz P, Pajares MA.; ''S-adenosylmethionine synthesis: molecular mechanisms and clinical implications.''; PubMed Europe PMC Scholia
20. Wang H, Pang H, Bartlam M, Rao Z.; ''Crystal structure of human E1 enzyme and its complex with a substrate analog reveals the mechanism of its phosphatase/enolase activity.''; PubMed Europe PMC Scholia
21. Yang X, Hu Y, Yin DH, Turner MA, Wang M, Borchardt RT, Howell PL, Kuczera K, Schowen RL.; ''Catalytic strategy of S-adenosyl-L-homocysteine hydrolase: transition-state stabilization and the avoidance of abortive reactions.''; PubMed Europe PMC Scholia
22. Liu P, Ge X, Ding H, Jiang H, Christensen BM, Li J.; ''Role of glutamate decarboxylase-like protein 1 (GADL1) in taurine biosynthesis.''; PubMed Europe PMC Scholia
23. Li F, Feng Q, Lee C, Wang S, Pelleymounter LL, Moon I, Eckloff BW, Wieben ED, Schaid DJ, Yee V, Weinshilboum RM.; ''Human betaine-homocysteine methyltransferase (BHMT) and BHMT2: common gene sequence variation and functional characterization.''; PubMed Europe PMC Scholia
24. Oram SW, Ai J, Pagani GM, Hitchens MR, Stern JA, Eggener S, Pins M, Xiao W, Cai X, Haleem R, Jiang F, Pochapsky TC, Hedstrom L, Wang Z.; ''Expression and function of the human androgen-responsive gene ADI1 in prostate cancer.''; PubMed Europe PMC Scholia
25. Hildebrandt TM, Grieshaber MK.; ''Three enzymatic activities catalyze the oxidation of sulfide to thiosulfate in mammalian and invertebrate mitochondria.''; PubMed Europe PMC Scholia
26. Kabuyama Y, Litman ES, Templeton PD, Metzner SI, Witze ES, Argast GM, Langer SJ, Polvinen K, Shellman Y, Chan D, Shabb JB, Fitzpatrick JE, Resing KA, Sousa MC, Ahn NG.; ''A mediator of Rho-dependent invasion moonlights as a methionine salvage enzyme.''; PubMed Europe PMC Scholia
27. Dominy JE, Simmons CR, Hirschberger LL, Hwang J, Coloso RM, Stipanuk MH.; ''Discovery and characterization of a second mammalian thiol dioxygenase, cysteamine dioxygenase.''; PubMed Europe PMC Scholia
28. Janosík M, Kery V, Gaustadnes M, Maclean KN, Kraus JP.; ''Regulation of human cystathionine beta-synthase by S-adenosyl-L-methionine: evidence for two catalytically active conformations involving an autoinhibitory domain in the C-terminal region.''; PubMed Europe PMC Scholia
29. Moeller BM, Crankshaw DL, Briggs J, Nagasawa HT, Patterson SE.; ''In-vitro mercaptopyruvate sulfurtransferase species comparison in humans and common laboratory animals.''; PubMed Europe PMC Scholia
30. Nagahara N, Li Q, Sawada N.; ''Do antidotes for acute cyanide poisoning act on mercaptopyruvate sulfurtransferase to facilitate detoxification?''; PubMed Europe PMC Scholia
31. Koike S, Kawamura K, Kimura Y, Shibuya N, Kimura H, Ogasawara Y.; ''Analysis of endogenous H2S and H2Sn in mouse brain by high-performance liquid chromatography with fluorescence and tandem mass spectrometric detection.''; PubMed Europe PMC Scholia
32. Leclerc D, Campeau E, Goyette P, Adjalla CE, Christensen B, Ross M, Eydoux P, Rosenblatt DS, Rozen R, Gravel RA.; ''Human methionine synthase: cDNA cloning and identification of mutations in patients of the cblG complementation group of folate/cobalamin disorders.''; PubMed Europe PMC Scholia
33. Kamatani N, Nelson-Rees WA, Carson DA.; ''Selective killing of human malignant cell lines deficient in methylthioadenosine phosphorylase, a purine metabolic enzyme.''; PubMed Europe PMC Scholia
34. Corrales FJ, Pérez-Mato I, Sánchez Del Pino MM, Ruiz F, Castro C, García-Trevijano ER, Latasa U, Martínez-Chantar ML, Martínez-Cruz A, Avila MA, Mato JM.; ''Regulation of mammalian liver methionine adenosyltransferase.''; PubMed Europe PMC Scholia
35. Nakamura H, Yatsuki J, Ubuka T.; ''Production of hypotaurine, taurine and sulfate in rats and mice injected with L-cysteinesulfinate.''; PubMed Europe PMC Scholia
36. Kimura H.; ''Hydrogen polysulfide (H2S n ) signaling along with hydrogen sulfide (H2S) and nitric oxide (NO).''; PubMed Europe PMC Scholia
37. Theissen U, Hoffmeister M, Grieshaber M, Martin W.; ''Single eubacterial origin of eukaryotic sulfide:quinone oxidoreductase, a mitochondrial enzyme conserved from the early evolution of eukaryotes during anoxic and sulfidic times.''; PubMed Europe PMC Scholia
38. Guion-Rain M-C, Portemer C, Chatagner F.; ''Rat liver cysteine sulfinate decarboxylase: purification, new appraisal of the molecular weight and determination of catalytic properties.''; PubMed Europe PMC Scholia
39. Chiku T, Padovani D, Zhu W, Singh S, Vitvitsky V, Banerjee R.; ''H2S biogenesis by human cystathionine gamma-lyase leads to the novel sulfur metabolites lanthionine and homolanthionine and is responsive to the grade of hyperhomocysteinemia.''; PubMed Europe PMC Scholia
40. Fiermonte G, Dolce V, Arrigoni R, Runswick MJ, Walker JE, Palmieri F.; ''Organization and sequence of the gene for the human mitochondrial dicarboxylate carrier: evolution of the carrier family.''; PubMed Europe PMC Scholia
41. Della Ragione F, Cartenì-Farina M, Gragnaniello V, Schettino MI, Zappia V.; ''Purification and characterization of 5'-deoxy-5'-methylthioadenosine phosphorylase from human placenta.''; PubMed Europe PMC Scholia
42. Martini F, Angelaccio S, Barra D, Pascarella S, Maras B, Doonan S, Bossa F.; ''The primary structure of mitochondrial aspartate aminotransferase from human heart.''; PubMed Europe PMC Scholia
43. Zhou SL, Gordon RE, Bradbury M, Stump D, Kiang CL, Berk PD.; ''Ethanol up-regulates fatty acid uptake and plasma membrane expression and export of mitochondrial aspartate aminotransferase in HepG2 cells.''; PubMed Europe PMC Scholia
44. Yadav PK, Yamada K, Chiku T, Koutmos M, Banerjee R.; ''Structure and kinetic analysis of H2S production by human mercaptopyruvate sulfurtransferase.''; PubMed Europe PMC Scholia
45. Kimura H.; ''Signaling molecules: hydrogen sulfide and polysulfide.''; PubMed Europe PMC Scholia
46. HIMWICH WA, SAUNDERS JP.; ''Enzymatic conversion of cyanide to thiocyanate.''; PubMed Europe PMC Scholia
47. Crompton M, Palmieri F, Capano M, Quagliariello E.; ''The transport of sulphate and sulphite in rat liver mitochondria.''; PubMed Europe PMC Scholia
48. Liu P, Torrens-Spence MP, Ding H, Christensen BM, Li J.; ''Mechanism of cysteine-dependent inactivation of aspartate/glutamate/cysteine sulfinic acid α-decarboxylases.''; PubMed Europe PMC Scholia
49. Zottola MA.; ''A partial exploration of the potential energy surfaces of SCN and HSCN: implications for the enzyme-mediated detoxification of cyanide.''; PubMed Europe PMC Scholia

History

External references

DataNodes

Name	Type	Database reference	Comment
2,3-DMPP	Metabolite	CHEBI:58828 (ChEBI)
2-Oxoacid	Metabolite	CHEBI:35179 (ChEBI)
2AET	Metabolite	CHEBI:17141 (ChEBI)
2OBUTA	Metabolite	CHEBI:30831 (ChEBI)
2OG	Metabolite	CHEBI:30915 (ChEBI)
2xHC-SQRDL(1-450)	Protein	Q9Y6N5 (Uniprot-TrEMBL)
2xHC-SQRDL(1-450)	Protein	Q9Y6N5 (Uniprot-TrEMBL)
3-Sulfinoalanine	Metabolite	CHEBI:16345 (ChEBI)
3MPYR	Metabolite	CHEBI:16208 (ChEBI)
4MTOBUTA	Metabolite	CHEBI:16723 (ChEBI)
ADI1	Protein	Q9BV57 (Uniprot-TrEMBL)
ADO	Protein	Q96SZ5 (Uniprot-TrEMBL)
ADO:Fe2+	Complex	R-HSA-6814156 (Reactome)
AHCY	Protein	P23526 (Uniprot-TrEMBL)
AHCY:NAD+ tetramer	Complex	R-HSA-174358 (Reactome)
APIP	Protein	Q96GX9 (Uniprot-TrEMBL)
APIP:Zn++	Complex	R-HSA-1237083 (Reactome)
ARD:Fe++	Complex	R-HSA-1237173 (Reactome)
ATP	Metabolite	CHEBI:15422 (ChEBI)
Acireductone	Metabolite	CHEBI:58795 (ChEBI)
Ade-Rib	Metabolite	CHEBI:16335 (ChEBI)
Ade	Metabolite	CHEBI:16708 (ChEBI)
AdoHcy	Metabolite	CHEBI:16680 (ChEBI)
AdoMet	Metabolite	CHEBI:15414 (ChEBI)
BET	Metabolite	CHEBI:17750 (ChEBI)
BHMT	Protein	Q93088 (Uniprot-TrEMBL)
BHMT2	Protein	Q9H2M3 (Uniprot-TrEMBL)
BHMT2:Zn2+ tetramer	Complex	R-HSA-5696826 (Reactome)
BHMT:Zn2+ tetramer	Complex	R-HSA-6798211 (Reactome)
CBS tetramer	Complex	R-HSA-1614610 (Reactome)
CDO1	Protein	Q16878 (Uniprot-TrEMBL)
CDO1:Fe2+	Complex	R-HSA-1614609 (Reactome)
CO2	Metabolite	CHEBI:16526 (ChEBI)
CSA	Metabolite	CHEBI:16345 (ChEBI)
CSAD	Protein	Q9Y600 (Uniprot-TrEMBL)
CSAD dimer	Complex	R-HSA-1655430 (Reactome)
CTH	Protein	P32929 (Uniprot-TrEMBL)
CTH tetramer:PXLP	Complex	R-HSA-1625212 (Reactome)
CoQ	Metabolite	CHEBI:46245 (ChEBI)
CysS-SQRDL(1-450)	Protein	Q9Y6N5 (Uniprot-TrEMBL)
CysS248-MPST	Protein	P25325 (Uniprot-TrEMBL)
CysS248-MPST:TXN2	Complex	R-HSA-9035480 (Reactome)
CysS248-MPST	Protein	P25325 (Uniprot-TrEMBL)
DMGLY	Metabolite	CHEBI:17724 (ChEBI)
E1:Mg++	Complex	R-HSA-1237166 (Reactome)
ENOPH1	Protein	Q9UHY7 (Uniprot-TrEMBL)
ETHE1	Protein	O95571 (Uniprot-TrEMBL)
ETHE1:2Zn2+	Complex	R-HSA-1614521 (Reactome)
FAD	Metabolite	CHEBI:16238 (ChEBI)
FMN	Metabolite	CHEBI:17621 (ChEBI)
Fe2+	Metabolite	CHEBI:18248 (ChEBI)
GADL1	Protein	Q6ZQY3 (Uniprot-TrEMBL)
GADL1:PXLP	Complex	R-HSA-6787755 (Reactome)
GOT1	Protein	P17174 (Uniprot-TrEMBL)
GOT1 dimer	Complex	R-HSA-70579 (Reactome)
GOT2 dimer	Complex	R-HSA-70594 (Reactome)
GSH	Metabolite	CHEBI:16856 (ChEBI)
GSSG	Metabolite	CHEBI:17858 (ChEBI)
H+	Metabolite	CHEBI:15378 (ChEBI)
H2O2	Metabolite	CHEBI:16240 (ChEBI)
H2O	Metabolite	CHEBI:15377 (ChEBI)
H2S	Metabolite	CHEBI:16136 (ChEBI)
HC-TXN2	Protein	Q99757 (Uniprot-TrEMBL)
HCN	Metabolite	CHEBI:18407 (ChEBI)
HCOOH	Metabolite	CHEBI:30751 (ChEBI)
HCYS	Metabolite	CHEBI:17230 (ChEBI)
HLAN	Metabolite	CHEBI:62856 (ChEBI)
HSCN	Metabolite	CHEBI:29200 (ChEBI)
HSO3-	Metabolite	CHEBI:17137 (ChEBI)
HTAU	Metabolite	CHEBI:16668 (ChEBI)
HTAUDH		R-HSA-1655455 (Reactome)
K+	Metabolite	CHEBI:29103 (ChEBI)
L-Cys	Metabolite	CHEBI:35235 (ChEBI)
L-Cystathionine	Metabolite	CHEBI:17482 (ChEBI)
L-Glu	Metabolite	CHEBI:29985 (ChEBI)
L-Lanthionine	Metabolite	CHEBI:21347 (ChEBI)
L-Met	Metabolite	CHEBI:57844 (ChEBI)
L-Ser	Metabolite	CHEBI:33384 (ChEBI)
L-amino acid	Metabolite	CHEBI:59869 (ChEBI)
MAL	Metabolite	CHEBI:30797 (ChEBI)
MAT1A	Protein	Q00266 (Uniprot-TrEMBL)
MAT1A multimers	Complex	R-HSA-174383 (Reactome)
MPST	Protein	P25325 (Uniprot-TrEMBL)
MRI1	Protein	Q9BV20 (Uniprot-TrEMBL)
MTAD	Metabolite	CHEBI:17509 (ChEBI)
MTAP	Protein	Q13126 (Uniprot-TrEMBL)
MTAP trimer	Complex	R-HSA-1237147 (Reactome)
MTR	Protein	Q99707 (Uniprot-TrEMBL)
MTRIBP	Metabolite	CHEBI:58533 (ChEBI)
MTRIBUP	Metabolite	CHEBI:58548 (ChEBI)
MTRR	Protein	Q9UBK8 (Uniprot-TrEMBL)
MTRR:MTR(MeCbl)	Complex	R-HSA-3149551 (Reactome)
MTRR:MTR(cob(I)alamin)	Complex	R-HSA-3149516 (Reactome)
MeCbl	Metabolite	CHEBI:28115 (ChEBI)
Mg2+	Metabolite	CHEBI:18420 (ChEBI)
MoCo (dioxyo)	Metabolite	CHEBI:25372 (ChEBI)
NAD+	Metabolite	CHEBI:15846 (ChEBI)
NAD+	Metabolite	CHEBI:15846 (ChEBI)
NADH	Metabolite	CHEBI:16908 (ChEBI)
NH3	Metabolite	CHEBI:16134 (ChEBI)
O2	Metabolite	CHEBI:15379 (ChEBI)
PPi	Metabolite	CHEBI:29888 (ChEBI)
PXLP	Metabolite	CHEBI:18405 (ChEBI)
PXLP-CBS	Protein	P35520 (Uniprot-TrEMBL)
PXLP-GOT2	Protein	P00505 (Uniprot-TrEMBL)
PYR	Metabolite	CHEBI:32816 (ChEBI)
Pi	Metabolite	CHEBI:18367 (ChEBI)
QH2	Metabolite	CHEBI:17976 (ChEBI)
S2O3(2-)	Metabolite	CHEBI:16094 (ChEBI)
SLC25A10	Protein	Q9UBX3 (Uniprot-TrEMBL)
SMM	Metabolite	CHEBI:17728 (ChEBI)
SO3(2-)	Metabolite	CHEBI:17359 (ChEBI)
SO4(2-)	Metabolite	CHEBI:16189 (ChEBI)
SQR:FAD	Complex	R-HSA-1614651 (Reactome)
SQRDL(1-450)	Protein	Q9Y6N5 (Uniprot-TrEMBL)
SUOX	Protein	P51687 (Uniprot-TrEMBL)
TAU	Metabolite	CHEBI:15891 (ChEBI)
TSTD1	Protein	Q8NFU3 (Uniprot-TrEMBL)
TST	Protein	Q16762 (Uniprot-TrEMBL)
TXN2	Protein	Q99757 (Uniprot-TrEMBL)
TXN2	Protein	Q99757 (Uniprot-TrEMBL)
Zn2+	Metabolite	CHEBI:29105 (ChEBI)
cob(I)alamin	Metabolite	CHEBI:15982 (ChEBI)
heme	Metabolite	CHEBI:17627 (ChEBI)
holo-SUOX	Complex	R-HSA-1614636 (Reactome)
sulfanegen	Metabolite	CHEBI:138170 (ChEBI)
sulfite(2-)	Metabolite	CHEBI:17359 (ChEBI)

Annotated Interactions

Source	Target	Type	Database reference	Comment
	2,3-DMPP	Arrow	R-HSA-1237140 (Reactome)
2,3-DMPP			R-HSA-1237129 (Reactome)
	2-Oxoacid	Arrow	R-HSA-1237102 (Reactome)
2AET			R-HSA-6814153 (Reactome)
	2OBUTA	Arrow	R-HSA-1614583 (Reactome)
	2OBUTA	Arrow	R-HSA-1614631 (Reactome)
2OG			R-HSA-9012597 (Reactome)
2xHC-SQRDL(1-450)			R-HSA-1614665 (Reactome)
	3-Sulfinoalanine	Arrow	R-HSA-1614645 (Reactome)
3-Sulfinoalanine			R-HSA-1655443 (Reactome)
	3MPYR	Arrow	R-HSA-9012597 (Reactome)
3MPYR			R-HSA-9012721 (Reactome)
3MPYR			R-HSA-9013471 (Reactome)
3MPYR			R-HSA-9034756 (Reactome)
	4MTOBUTA	Arrow	R-HSA-1237119 (Reactome)
4MTOBUTA			R-HSA-1237102 (Reactome)
ADO:Fe2+		mim-catalysis	R-HSA-6814153 (Reactome)
AHCY:NAD+ tetramer		mim-catalysis	R-HSA-174401 (Reactome)
APIP:Zn++		mim-catalysis	R-HSA-1237140 (Reactome)
ARD:Fe++		mim-catalysis	R-HSA-1237119 (Reactome)
ATP			R-HSA-174391 (Reactome)
	Acireductone	Arrow	R-HSA-1237129 (Reactome)
Acireductone			R-HSA-1237119 (Reactome)
	Ade-Rib	Arrow	R-HSA-174401 (Reactome)
	Ade	Arrow	R-HSA-1237160 (Reactome)
AdoHcy			R-HSA-174401 (Reactome)
	AdoMet	Arrow	R-HSA-174391 (Reactome)
BET			R-HSA-1614654 (Reactome)
BHMT2:Zn2+ tetramer		mim-catalysis	R-HSA-5696838 (Reactome)
BHMT:Zn2+ tetramer		mim-catalysis	R-HSA-1614654 (Reactome)
CBS tetramer		mim-catalysis	R-HSA-1614524 (Reactome)
CDO1:Fe2+		mim-catalysis	R-HSA-1614645 (Reactome)
	CO2	Arrow	R-HSA-1655443 (Reactome)
	CO2	Arrow	R-HSA-6814165 (Reactome)
CSAD dimer		mim-catalysis	R-HSA-1655443 (Reactome)
CSA			R-HSA-6814165 (Reactome)
CTH tetramer:PXLP		mim-catalysis	R-HSA-1614567 (Reactome)
CTH tetramer:PXLP		mim-catalysis	R-HSA-1614583 (Reactome)
CTH tetramer:PXLP		mim-catalysis	R-HSA-1614591 (Reactome)
CTH tetramer:PXLP		mim-catalysis	R-HSA-1614614 (Reactome)
CTH tetramer:PXLP		mim-catalysis	R-HSA-1614631 (Reactome)
CoQ			R-HSA-1614665 (Reactome)
	CysS-SQRDL(1-450)	Arrow	R-HSA-1614665 (Reactome)
CysS-SQRDL(1-450)			R-HSA-1614605 (Reactome)
CysS-SQRDL(1-450)			R-HSA-1614618 (Reactome)
	CysS248-MPST:TXN2	Arrow	R-HSA-9035227 (Reactome)
CysS248-MPST:TXN2			R-HSA-9035484 (Reactome)
	CysS248-MPST	Arrow	R-HSA-9034756 (Reactome)
CysS248-MPST			R-HSA-9035227 (Reactome)
	DMGLY	Arrow	R-HSA-1614654 (Reactome)
E1:Mg++		mim-catalysis	R-HSA-1237129 (Reactome)
ETHE1:2Zn2+		mim-catalysis	R-HSA-1614605 (Reactome)
GADL1:PXLP		mim-catalysis	R-HSA-6814165 (Reactome)
GOT1 dimer		mim-catalysis	R-HSA-1237102 (Reactome)
GOT2 dimer		mim-catalysis	R-HSA-9012597 (Reactome)
GSH			R-HSA-1655879 (Reactome)
	GSSG	Arrow	R-HSA-1655879 (Reactome)
	H+	Arrow	R-HSA-1237129 (Reactome)
	H+	Arrow	R-HSA-1614605 (Reactome)
	H+	Arrow	R-HSA-1655453 (Reactome)
	H+	Arrow	R-HSA-5696838 (Reactome)
	H+	Arrow	R-HSA-6814153 (Reactome)
H+			R-HSA-1614665 (Reactome)
H+			R-HSA-1655879 (Reactome)
	H2O2	Arrow	R-HSA-1614544 (Reactome)
	H2O	Arrow	R-HSA-1237140 (Reactome)
	H2O	Arrow	R-HSA-1614524 (Reactome)
H2O			R-HSA-1237129 (Reactome)
H2O			R-HSA-1614544 (Reactome)
H2O			R-HSA-1614583 (Reactome)
H2O			R-HSA-1614605 (Reactome)
H2O			R-HSA-1614614 (Reactome)
H2O			R-HSA-1614631 (Reactome)
H2O			R-HSA-1655453 (Reactome)
H2O			R-HSA-174391 (Reactome)
H2O			R-HSA-174401 (Reactome)
	H2S	Arrow	R-HSA-1614567 (Reactome)
	H2S	Arrow	R-HSA-1614591 (Reactome)
	H2S	Arrow	R-HSA-1614614 (Reactome)
	H2S	Arrow	R-HSA-1614631 (Reactome)
	H2S	Arrow	R-HSA-1655879 (Reactome)
	H2S	Arrow	R-HSA-9035484 (Reactome)
H2S			R-HSA-1614665 (Reactome)
	HC-TXN2	Arrow	R-HSA-9035484 (Reactome)
HCN			R-HSA-9013198 (Reactome)
HCN			R-HSA-9013471 (Reactome)
HCN			R-HSA-9013533 (Reactome)
	HCOOH	Arrow	R-HSA-1237119 (Reactome)
HCYS		Arrow	R-HSA-1614567 (Reactome)
	HCYS	Arrow	R-HSA-174401 (Reactome)
HCYS			R-HSA-1614524 (Reactome)
HCYS			R-HSA-1614567 (Reactome)
HCYS			R-HSA-1614631 (Reactome)
HCYS			R-HSA-1614654 (Reactome)
HCYS			R-HSA-174374 (Reactome)
HCYS			R-HSA-5696838 (Reactome)
	HLAN	Arrow	R-HSA-1614567 (Reactome)
	HSCN	Arrow	R-HSA-9013198 (Reactome)
	HSCN	Arrow	R-HSA-9013471 (Reactome)
	HSCN	Arrow	R-HSA-9013533 (Reactome)
HSO3-			R-HSA-9012721 (Reactome)
	HTAU	Arrow	R-HSA-1655443 (Reactome)
	HTAU	Arrow	R-HSA-6814153 (Reactome)
	HTAU	Arrow	R-HSA-6814165 (Reactome)
HTAUDH		mim-catalysis	R-HSA-1655453 (Reactome)
HTAU			R-HSA-1655453 (Reactome)
	L-Cys	Arrow	R-HSA-1614583 (Reactome)
L-Cys		Arrow	R-HSA-1614591 (Reactome)
L-Cys			R-HSA-1614591 (Reactome)
L-Cys			R-HSA-1614614 (Reactome)
L-Cys			R-HSA-1614645 (Reactome)
L-Cys			R-HSA-9012597 (Reactome)
	L-Cystathionine	Arrow	R-HSA-1614524 (Reactome)
L-Cystathionine			R-HSA-1614583 (Reactome)
	L-Glu	Arrow	R-HSA-9012597 (Reactome)
	L-Lanthionine	Arrow	R-HSA-1614591 (Reactome)
	L-Met	Arrow	R-HSA-1237102 (Reactome)
	L-Met	Arrow	R-HSA-1614654 (Reactome)
	L-Met	Arrow	R-HSA-174374 (Reactome)
	L-Met	Arrow	R-HSA-5696838 (Reactome)
L-Met			R-HSA-174391 (Reactome)
	L-Ser	Arrow	R-HSA-1614614 (Reactome)
L-Ser			R-HSA-1614524 (Reactome)
L-amino acid			R-HSA-1237102 (Reactome)
	MAL	Arrow	R-HSA-1614546 (Reactome)
MAL			R-HSA-1614546 (Reactome)
MAT1A multimers		mim-catalysis	R-HSA-174391 (Reactome)
	MPST	Arrow	R-HSA-9035484 (Reactome)
MPST			R-HSA-9034756 (Reactome)
MPST		mim-catalysis	R-HSA-9012721 (Reactome)
MPST		mim-catalysis	R-HSA-9013471 (Reactome)
MPST		mim-catalysis	R-HSA-9013533 (Reactome)
MPST		mim-catalysis	R-HSA-9034756 (Reactome)
MRI1		mim-catalysis	R-HSA-1237096 (Reactome)
MRI1		mim-catalysis	R-HSA-1299507 (Reactome)
MTAD			R-HSA-1237160 (Reactome)
MTAP trimer		mim-catalysis	R-HSA-1237160 (Reactome)
	MTRIBP	Arrow	R-HSA-1237160 (Reactome)
	MTRIBP	Arrow	R-HSA-1299507 (Reactome)
MTRIBP			R-HSA-1237096 (Reactome)
	MTRIBUP	Arrow	R-HSA-1237096 (Reactome)
MTRIBUP			R-HSA-1237140 (Reactome)
MTRIBUP			R-HSA-1299507 (Reactome)
MTRR:MTR(MeCbl)			R-HSA-174374 (Reactome)
MTRR:MTR(MeCbl)		mim-catalysis	R-HSA-174374 (Reactome)
	MTRR:MTR(cob(I)alamin)	Arrow	R-HSA-174374 (Reactome)
NAD+			R-HSA-1655453 (Reactome)
	NADH	Arrow	R-HSA-1655453 (Reactome)
	NH3	Arrow	R-HSA-1614583 (Reactome)
	NH3	Arrow	R-HSA-1614631 (Reactome)
O2			R-HSA-1237119 (Reactome)
O2			R-HSA-1614544 (Reactome)
O2			R-HSA-1614605 (Reactome)
O2			R-HSA-1614645 (Reactome)
O2			R-HSA-6814153 (Reactome)
	PPi	Arrow	R-HSA-174391 (Reactome)
	PYR	Arrow	R-HSA-9012721 (Reactome)
	PYR	Arrow	R-HSA-9013471 (Reactome)
	PYR	Arrow	R-HSA-9013533 (Reactome)
	PYR	Arrow	R-HSA-9034756 (Reactome)
	Pi	Arrow	R-HSA-1237129 (Reactome)
	Pi	Arrow	R-HSA-174391 (Reactome)
Pi			R-HSA-1237160 (Reactome)
	QH2	Arrow	R-HSA-1614665 (Reactome)
			R-HSA-1237096 (Reactome)	Equilibrium between 5'-methylthio ribose-1-phosphate and 5'-methylthio ribulose-1-phosphate is catalyzed by 5'-methylthio ribose-1-phosphate isomerase. (Kabuyama et al, 2009)
			R-HSA-1237102 (Reactome)	In the last step MOB gets transaminated to methionine. The reaction was confirmed in yeast, where several transaminases catalyze it, which appears to be also the case in rat. At the moment, the human enzymes involved are unknown but due to homology to the respective enzyme in the parasite Crithidia fasciculata we feel supported to state that human GOT is probably one of the involved transaminases. (Berger et al, 2001)
			R-HSA-1237119 (Reactome)	Acireducone (1,2-Dihydroxy-3-oxo-5'-methylthiopentene) is oxidized using acireductone dioxygenase and dioxygen. There are two reactions possible, dependent on the metal cofactor: the alternative product 3-methylthiopropionate using nickel was confirmed in Klebsiella. In eukaryotes using iron(II) the result is 4-methylthio-2-oxobutanoate (MOB). (Ju et al, 2006)
			R-HSA-1237129 (Reactome)	Acireductone synthase (also: enolase-phosphatase E1) catalyzes the dephosphorylation and conversion to enolate of 2,3-dioxo-5'-methylthiopentane-1-phosphate, yielding acireductone. (Wang et al, 2005)
			R-HSA-1237140 (Reactome)	The human enzyme with 5'-methylthio ribulose-1-phosphate isomerase activity is probably produced from the APIP gene, according to its orthology with the yeast Mde1p enzyme.
			R-HSA-1237160 (Reactome)	MTA phosphorylase catalyzes the cleavage of adenine from S-methylthioadenosine (MTA) and subsequent phosphorylation of the product, yielding 5'-methylthio ribose-1-phosphate (Kamatani et al. 1981). The active form of the enzyme is a homotrimer (Della Ragione et al. 1985). Mutations in the gene are associated with a rare bone dysplasia and cancer syndrome, DMS-MFH (Camacho-Vanegas et al. 2012).
			R-HSA-1299507 (Reactome)	Equilibrium between 5'-methylthio ribose-1-phosphate and 5'-methylthio ribulose-1-phosphate is catalyzed by 5'-methylthio ribose-1-phosphate isomerase. (Kabuyama et al, 2009)
			R-HSA-1614524 (Reactome)	The first step of homocysteine conversion to cysteine is catalyzed by cystathionine beta-lyase, which adds a serine molecule to the substrate. The enzyme is a tetramer with two heme molecules as cofactor (Janosik et al. 2001).
			R-HSA-1614544 (Reactome)	Sulfite oxidase oxidizes sulfite to sulfate which is among the most important macronutrients in cells and the fourth most abundant anion in human plasma (300 micromolar). The enzyme has a molybdenum-molybdopterin cofactor (MoCo) bound (Wilson et al. 2006, Feng et al. 2007).
			R-HSA-1614546 (Reactome)	Sulfate leaves the mitochondrion with the help of the dicarboxylate carrier, via antiport with malate (Crompton et al. 1974, Fiemont et al. 1999)
			R-HSA-1614567 (Reactome)	Excess homocysteine will change the enzymatic activity of CBS such that other reactions than transsulfuration take place. In these reactions, oxobutanoate, lanthionine, and homolanthionine are produced by cystathionine gamma-lyase (CTH) (Chiku et al. 2009, Steegborn et al. 1999)
			R-HSA-1614583 (Reactome)	Cystathionine is cleaved to cysteine, oxobutanoate, and ammonia by the alpha,gamma-elimination activity of cystathionine gamma-lyase (CTH) (Chiku et al. 2009, Steegborn et al. 1999).
			R-HSA-1614591 (Reactome)	Excess homocysteine will change the enzymatic activity of CBS such that other reactions than transsulfuration take place. In these reactions, oxobutanoate, lanthionine, and homolanthionine are produced by cystathionine gamma-lyase (CTH) (Chiku et al. 2009, Steegborn et al. 1999)
			R-HSA-1614605 (Reactome)	The sulfur dioxygenase ETHE1 converts persulfides to sulfite. Loss of this activity leads to the rare ethylmalonyl encephalopathy where the body can no longer detoxify H2S (Tiranti et al, 2009).
			R-HSA-1614614 (Reactome)	alpha,beta-elimination activity of cystathionine-gamma-lyase (CTH) replaces the sulfur in cysteine with oxygen from water, resulting in serine and toxic hydrogen sulfide, which is further oxidized in mitochondria (Chiku et al. 2009, Steegborn et al. 1999).
			R-HSA-1614618 (Reactome)	The main reaction catalyzed by rhodanase is not the name-giving detoxification of cyanide to thiocyanate, but the transfer of a sulfur atom from SQR-S-SH onto sulfite yielding thiosulfate during sulfide oxidation. The activity of human rhodanase was inferred from the rat orthologue by Hildebrandt & Grieshaber, 2008.
			R-HSA-1614631 (Reactome)	Excess homocysteine will change the enzymatic activity of CBS such that other reactions than transsulfuration take place. In these reactions, oxobutanoate, lanthionine, and homolanthionine are produced by cystathionine gamma-lyase (CTH) (Chiku et al. 2009, Steegborn et al. 1999)
			R-HSA-1614645 (Reactome)	Oxidation of the thiol moiety of cysteine yields sulfinoalanine, which itself is processed to hypotaurine by an as of yet uncharacterized enzyme in humans . Whether further oxidation of hypotaurine to taurine needs an enzyme is unknown at present (Ye et al. 2007).
			R-HSA-1614654 (Reactome)	Remethylation of homocysteine (HCYS) to methionine (L-Met) can also proceed by using betaine (BET) as a methyl donor, which is oxidised to dimethylglycine (DMGLY). This reaction is also part of choline catabolism, thereby providing a link to folate-dependent, one-carbon metabolism (Li et al. 2008).
			R-HSA-1614665 (Reactome)	When SQR is in the oxidized state, it can bind hydrogen sulfide as persulfide to one of its own cysteine residue, the electrons being transferred to ubiquinone. After that the additional sulfur is dioxygenated by another enzyme (ETHE1). The activity of human SQR was deduced from the orthologue in Arenicola marina (Theissen et al. 2003, Hildebrandt & Grieshaber 2008).
			R-HSA-1655443 (Reactome)	Cysteine sulfinic acid decarboxylase (CSAD) mediates the decarboxylase of 3-sulfinoalanine to produce hypotuarine. CSAD functions as a homodimer and requires pyridoxal phosphate as a cofactor. Purification, characterisation and activity of CSAD has been determined from rat liver (Guion-Rain et al. 1975).
			R-HSA-1655453 (Reactome)	The as yet uncharacterised human enzyme hypotaurine dehydrogenase mediates the oxidation of hypotaurine to produce taurine. All studies to date have been performed predominantly in rat (Nakamura et al. 2006).
			R-HSA-1655879 (Reactome)	Thiosulfate is able to transfer its sulfur atom to glutathione, a reaction investigated in yeast (Chauncey & Westley 1983). Recombinant human thiosulfate sulfurtransferase/rhodanese-like domain-containing protein 1 (TSTD1 aka KAT1) (and its yeast equivalent RDL1) catalyse a predicted thiosulfate-dependent conversion of glutathione (GSH) to glutathione disulfide (GSSG) (Melideo et al. 2014).
			R-HSA-174374 (Reactome)	A methyl group from 5-methyltetrahydrofolate is transferred to homocysteine (HCYS) via a meCbl intermediate, forming methionine (L-Met) (Leclerc et al. 1996).
			R-HSA-174391 (Reactome)	S-adenosylmethionine (AdoMet, SAM) is an essential metabolite in all cells. AdoMet is a precursor in the synthesis of polyamines. Methionine adenosyltransferases (MAT) catalyse the only known AdoMet biosynthetic reaction from methionine (L-Met) and ATP. In mammalian tissues, three different forms of MAT (MAT I, MAT III and MAT II) have been identified that are the product of two different genes (MAT1A and MAT2A). MAT1A binds 1 K+ and 2 Mg2+ (or Co2+, not shown here) in tetrameric or dimeric form (Corrales et al. 2002, Mato et al. 1997).
			R-HSA-174401 (Reactome)	Adenosylhomocysteinase (AHCY) is a tetrameric, NAD+-bound, cytosolic protein that regulates all adenosylmethionine-(AdoMet) dependent transmethylations by hydrolysing the feedback inhibitor adenosylhomocysteine (AdoHcy) to homocysteine (HCYS) and adenosine (Ade-Rib) (Turner et al. 1998, Yang et al. 2003).
			R-HSA-5696838 (Reactome)	L-homocysteine (LHCYS) is derived from L-methionine (L-Met) and can either be remethylated to reform L-Met or take part in cysteine biosynthesis via the trans-sulfuration pathway. LHCYS remethylation can occur by the action of two enzymes; cobalamin-dependent methionine synthase and betaine-homocysteine methyltransferase, using methyltetrahydrofolate and betaine respectively as methyl donors. A third enzyme, S-methylmethionine-homocysteine S-methyltransferase (BHMT2), can use S-methylmethionine (SMM) as the methyl donor to methylate LHCYS and reform L-Met. BHMT2 is a tetrameric, cytosolic enzyme that requires one Zn2+ ion per subunit as cofactor (Szegedi et al. 2008).
			R-HSA-6814153 (Reactome)	Cysteine metabolism to its sulfoxidation end-products is dependent upon two iron-dependent enzymes that are the only known mammalian thiol dioxygenases. These two thiol dioxygenases are cysteine dioxygenase (CDO) and 2-aminoethanethiol dioxygenase (ADO, cysteamine dioxygenase ). Both of these thiol dioxygenases are essential for hypotaurine and taurine biosynthesis. ADO adds molecular oxygen to the sulfhydryl group of 2-aminoethanethiol (2AET, cysteamine) to form the sulfinic acid hypotaurine (HTAU) (Dominy et al. 2007).
			R-HSA-6814165 (Reactome)	Acidic amino acid decarboxylase GADL1 (GADL1) can decarboxylate acidic amino acids such as cysteine sulfinic acid (CSA) to form hypotaurine (HTAU) (Liu et al. 2012, 2013).
			R-HSA-9012597 (Reactome)	Hydrogen sulfide (H2S) produced endogenously has been established as the third gaseous signaling molecule, a smooth muscle relaxant and a neuroprotectant (Kimura 2011a, 2011b). Three human enzyme systems produce H2S in the brain, retina and vascular endothelial cells. 3-mercaptopyruvate sulphurtransferase (MPST, aka 3MST) in conjunction with cysteine (aspartate) aminotransferase (CAT, aka GOT2) is decribed here. The first step is the reversible transamination between L-cysteine (L-Cys) and 2-oxoglutarate (2OG, aka alpha-ketoglutarate) to form 3-methylpyruvate (3MPYR) and glutamate (Glu) catalysed by GOT2. Two forms of human aspartate aminotransferase (GOT) enzymes exist; cytosolic (GOT1) and mitochondrial (GOT2). Both are dimeric proteins requiring pyridoxal phosphate for activity. Human GOT2 (Zhou et al. 1998) possesses the same catalytic activity as its rat counterpart (Ubuka et al. 1978).
			R-HSA-9012721 (Reactome)	Hydrogen sulfide (H2S) produced endogenously has been established as the third gaseous signaling molecule, a smooth muscle relaxant and a neuroprotectant (Kimura 2011a, 2011b). Three enzyme systems produce H2S in the brain, retina and vascular endothelial cells (Shibuya et al. 2009a, 2009b, Mikami et al. 2011). 3-mercaptopyruvate sulphurtransferase (MPST, aka 3MST) in conjunction with cysteine (aspartate) aminotransferase (CAT, aka GOT2) is decribed here. In the second step, 3-mercaptopyruvate sulfurtransferase (MPST aka 3MST) mediates the transfer of a sulfur atom from 3-methylpryuvate (3MPYR) to hydrogensulfite (HSO3-) to form thiosulfate (S2O3(2-)) and pyruvate (PYR) (Yadav et al. 2013).
			R-HSA-9013198 (Reactome)	Cyanide is a potent metabolic poison, a major component of which is binding to and inhibition of cytochrome c oxidase (cytochrome a3), resulting in the rapid inhibition of oxidative phosphorylation (Hall & Rumack 1986). As a result, cells can't utilise oxygen, giving rise to central nervous system, cardiovascular and respiratory dysfunction that can result in permanent neurological defects and, in severe cases, death. At body's pH, cyanide exists mainly in the undissociated form hydrogen cyanide (HCN) which can cross cellular and subcellular membranes such as the blood brain barrier and mitochondrial membranes. Cyanide intoxication can occur after smoke inhalation, industrial exposure, ingestion of cyanogenic substances and cyanogenic food sources such as cassava. Antidotes for HCN poisoning cases include HCN binders, sulfur donors that convert HCN to the less toxic thiosulfate and competitors for HCN enzymatic binding sites such as NO (Petrikovics et al. 2015). Two pathways in mammals are able to detoxify cyanide as thiocyanate via transfer of a sulfur atom: thiosulfate sulfurtransferase (TST aka rhodanese) in mitochondria and 3-mercaptopyruvate sulfurtransferase (MPST aka 3MST) in cytosol and mitochondria. TST can act to detoxify HCN by transsulfuration, that is mediating the transfer of a sulfur atom from thiosulfate (S2O3(2-)) to HCN to form the less toxic thiocyanic acid (HSCN) (Himwich & Saunders 1948, Aita et al. 1997, Zottola 2009). HSCN can be excreted in urine via the kidneys (Hamel 2011).
			R-HSA-9013471 (Reactome)	Cyanide is a potent metabolic poison which binds to and inhibits cytochrome c oxidase (cytochrome a3), resulting in the rapid inhibition of oxidative phosphorylation (Hall & Rumack 1986). As a result, cells can't utilise oxygen, giving rise to central nervous system, cardiovascular and respiratory dysfunction that can result in permanent neurological defects and, in severe cases, death. At body's pH, cyanide exists mainly in the undissociated form hydrogen cyanide (HCN) which can cross cellular and subcellular membranes such as the blood brain barrier and mitochondrial membranes. Although humans aren't typically exposed to toxic levels of cyanide, cyanide intoxication can occur after smoke inhalation, industrial exposure, ingestion of cyanogenic substances and cyanogenic food sources such as cassava. Antidotes for HCN poisoning cases include HCN binders, sulfur donors that convert HCN to the less toxic thiosulfate and competitors for HCN enzymatic binding sites such as NO (Nagahara et al. 1999, Petrikovics et al. 2015). Two pathways in mammals are able to detoxify cyanide as thiocyanate via transfer of a sulfur atom: thiosulfate sulfurtransferase (TST aka rhodanese) in mitochondria and 3-mercaptopyruvate sulfurtransferase (MPST aka 3MST) in cytosol and mitochondria. MPST mediates the transfer of a sulfur atom from 3-methylpryuvate (3MPYR) to HCN to form the less toxic thiocyanic acid (HSCN) (Himwich & Saunders 1948, Zottola 2009, Moeller et al. 2017). HSCN can be excreted in urine via the kidneys (Hamel 2011). Although the primary role of MPST is not cyanide detoxification, a large body of animal data has demonstrated cyanide is rapidly converted to thiocyanate in vivo when 3MPYR is administered, even in species with low MPST activity (Brenner et al. 2010, Belani et al. 2012).
			R-HSA-9013533 (Reactome)	Cyanide is a potent metabolic poison which binds to and inhibits cytochrome c oxidase (cytochrome a3), resulting in the rapid inhibition of oxidative phosphorylation (Hall & Rumack 1986). As a result, cells can't utilise oxygen, giving rise to central nervous system, cardiovascular and respiratory dysfunction that can result in permanent neurological defects and, in severe cases, death. At body's pH, cyanide exists mainly in the undissociated form hydrogen cyanide (HCN) which can cross cellular and subcellular membranes such as the blood brain barrier and mitochondrial membranes. Although humans are not typically exposed to cyanide, cyanide intoxication can occur after smoke inhalation, industrial exposure, ingestion of cyanogenic substances and cyanogenic food sources such as cassava. Antidotes for HCN poisoning cases include HCN binders, sulfur donors that convert HCN to the less toxic thiosulfate and competitors for HCN enzymatic binding sites such as NO (Petrikovics et al. 2015). Two pathways in mammals are able to detoxify cyanide as thiocyanate via transfer of a sulfur atom: thiosulfate sulfurtransferase (TST aka rhodanese) in mitochondria and 3-mercaptopyruvate sulfurtransferase (MPST aka 3MST) in cytosol and mitochondria. 3MPYR has been investigated for the potential treatment of HCN poisoning but its half life is very short, being rapidly metabolised when given intravenously (Nagahara & Sawada 2003). Also, it is a metabolite of cysteine metabolism but cysteine is present in low amounts in the brain and heart, limiting the ability of MPST to be effective in acute HCN poisoning. The pro-drug sulfanegen is the hemithioacetal cyclic dimer of 3MPYR and has been demonstrated to be effective against HCN poisoning in animal studies (Brenner et al. 2010, Belani et al. 2012). Sulfanegen provides the sulfur atom for the transsulfuration of HCN by MPST (Belani et al. 2012). HSCN can be excreted in urine via the kidneys (Hamel 2011). In a mass exposure scenario (such as terrorism or industrial accident), a rapidly-acting antidote that can be administered quickly to a large number of people is essential; sulfanegen can be rapidly administered by intramuscular injection (Patterson et al. 2016).
			R-HSA-9034756 (Reactome)	Hydrogen polysulfides (H2Sn, where n>=2) are also endogenously produced by 3-mercaptopyruvate sulfurtransferase (MPST aka 3MST) directly from 3-mercaptopyruvate (3MPYR) generated by cysteine (aspartate) aminotransferase (GOT2) (Kimura et al. 2013, Kimura et al. 2015, Koike et al. 2017). Where n=2, the H2S2 species is called hydrogen persulfide (aka disulfane). MPST can release either H2S or H2Sn depending on the interaction with thioredoxin. When there is strong interaction with thioredoxin, H2S is released. 3MST receives sulfur from 3MPYR to persulfurate (oxidise) cysteine-248 residue of its reaction centre. H2S2 is the dominant form produced with H2S3 detected at lower concentrations in cells or tissues. Up to H2S35 may exist (Steudel 2003), but under physiological conditions, when n reaches 8, it forms a crown shape and precipitates. H2Sn activate transient receptor potential ankyrin 1 (TRPA1) channels (Kimura et al. 2013), facilitate translocation of nuclear factor like-2 (NRF2) to the nucleus by modifying its binding partner kelch-like ECH-associated protein 1 (KEAP1) (Koike et al. 2013), regulates the activity of the tumor suppressor phosphatase and tensin homolog (PTEN) (Greiner et al. 2013), and reduces blood pressure by activating protein kinase G1a (Stubbert et al. 2014). Another persulfurated molecule, cysteine persulfide, which may be involved in the regulation of cellular redox homeostasis, is also produced by MPST (Kimura et al. 2017).
			R-HSA-9035227 (Reactome)	A polysulfur chain may be produced at the catalytic site of CysS248-MPST. H2Sn is released after CysS248-MPST binds mitochondrial thioredoxin (TXN2) (Smeets et al. 2005, Yadav et al. 2013, Holzerova et al. 2016). The length of the sulfur chain released from MPST may vary depending on the availability of thioredoxin (Kimura 2016). When the interaction between MPST and thioredoxin is strong, the shorter form H2S can be released.
			R-HSA-9035484 (Reactome)	A polysulfur chain may be produced at the catalytic site of CysS248-MPST. H2Sn is released after CysS248-MPST binds mitochondrial thioredoxin (TXN2) (Smeets et al. 2005, Yadav et al. 2013, Holzerova et al. 2016). The length of the sulfur chain released from MPST may vary depending on the availability of thioredoxin (Kimura 2016). When the interaction between MPST and thioredoxin is strong, the shorter form H2S can be released. Thioredoxin is now in the oxidised, disulfide form (HC-TXN2) and can be reduced by thioredoxin reductase in the presence of NADPH (Smeets et al. 2005, Yadav et al. 2013).
	S2O3(2-)	Arrow	R-HSA-1614618 (Reactome)
	S2O3(2-)	Arrow	R-HSA-9012721 (Reactome)
S2O3(2-)			R-HSA-1655879 (Reactome)
S2O3(2-)			R-HSA-9013198 (Reactome)
SLC25A10		mim-catalysis	R-HSA-1614546 (Reactome)
SMM			R-HSA-5696838 (Reactome)
	SO3(2-)	Arrow	R-HSA-9013198 (Reactome)
	SO4(2-)	Arrow	R-HSA-1614544 (Reactome)
	SO4(2-)	Arrow	R-HSA-1614546 (Reactome)
SO4(2-)			R-HSA-1614546 (Reactome)
SQR:FAD		mim-catalysis	R-HSA-1614665 (Reactome)
	SQRDL(1-450)	Arrow	R-HSA-1614605 (Reactome)
	SQRDL(1-450)	Arrow	R-HSA-1614618 (Reactome)
	TAU	Arrow	R-HSA-1655453 (Reactome)
TSTD1		mim-catalysis	R-HSA-1655879 (Reactome)
TST		mim-catalysis	R-HSA-1614618 (Reactome)
TST		mim-catalysis	R-HSA-9013198 (Reactome)
TXN2			R-HSA-9035227 (Reactome)
holo-SUOX		mim-catalysis	R-HSA-1614544 (Reactome)
sulfanegen			R-HSA-9013533 (Reactome)
	sulfite(2-)	Arrow	R-HSA-1614605 (Reactome)
	sulfite(2-)	Arrow	R-HSA-1655879 (Reactome)
sulfite(2-)			R-HSA-1614544 (Reactome)
sulfite(2-)			R-HSA-1614618 (Reactome)