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Phenol sulfur transferase deficiency

April 14, 2024

Phenol sulfur transferase deficiency, in short PST deficiency, is the lack or the reduced activity of the functional enzyme phenol sulfur transferase, which is crucial in the detoxification of mainly phenolic compounds by catalysing the sulfate conjugation of the hydroxyl groups in the toxic phenolic compounds to result in more hydrophilic forms for more efficient excretion. This metabolic disorder was first discovered in the late 1990s by Dr. Rosemary Waring during her researches with autistic children, which also made this deficiency commonly associated to the topics of autism. Mutations in the PST genes account for the genetic causes of the deficiency, of which single nucleotide polymorphism and methylation of promoters are two examples of mutations that respectively cause conformational abnormalities and diminished expressions to the enzyme, resulting in the reduced detoxification of phenolic compounds and regulation of phenolic neurotransmitter. The deficiency may cause symptoms like flushing, tachycardia, and depression, and be a risk factor for disorders like autism, migraine, and cancer, while it also limits the use of phenolic drugs in PST deficient patients. There is currently no drug available for treating PST deficiency. However, some people suffering from PST deficiency have found taking a digestive enzyme supplement containing Xylanase 10 minutes before eating to greatly reduce symptoms.

Phenol sulfur transferase edit

 
Sulfate conjugation catalyzed by PST, in which sulfuryl group from PAPS is transferred by PST to hydroxyl group of phenolic compounds.

Phenol sulfur transferase, in short PST or SULT1, is a subfamily of the enzyme cytosolic sulfotransferases (SULTs) consisting of at least 8 isoforms in humans[1] that catalyze the transfer of sulfuryl group from 3′-phosphoadenosine 5′-phosphosulfate (PAPS) to phenolic compounds,[2] resulting in more hydrophilic products that can be more easily expelled from tissues for excretion.[3] At high concentration, PST could also catalyze the sulfate conjugation of amino groups.[4] This enzyme subfamily, which exists in nearly all human tissues,[5] is important for the detoxification of phenol-containing xenobiotics or endogenous compounds,[6] including the biotransformation of neurotransmitters and drugs.[5] Its expression is controlled by the PST genes located on chromosomes 2, 4, and 16 depending on the isoform,[7] for example the genes for the predominant isoform throughout the body of human adults, SULT1A1,[8][9] which is highly heritable and variable between individuals,[10] and the most important one in the nervous system, SULT1A3,[11] are located on chromosome 16 at the position of 16p11.2 to 16p12.1.[12]

Discovery edit

PST deficiency was first discovered in the late 1990s by Dr. Rosemary Waring through a series of tests during her researches on the mechanisms and characteristics of sulfation in autistic children.[13] From the result of the test administering individuals with paracetamol, it was found that the level of sulfate conjugate in urine was significantly lower in the autistic individuals as compared to the non-autistic controls, which was caused by the decreased ability in the formation of sulfated metabolites.[14] The level of sulfate in plasma was also found to be significantly lower in autistic children, leading to a reduced activity of PST.[15] Therefore, she concluded that there was possibly a deficiency of PST in autistic children due to the reduction of sulfate in plasma as a substrate of PST.[13]

Pathophysiology edit

 
PST is a protein composed of long chain of amino acids in which the substitution of arginine by histidine at the position 213 due to the SULT1A1*2 polymorphism would cause the changes in biochemical properties and reduce the size of substrate binding site.[16]

Causes edit

PST deficiency can be caused by inherited mutations in the PST genes,[10] for example the SULT1A1*2 polymorphism, which is a single nucleotide polymorphism at the 638th base of the SULT1A1 gene from guanine to adenosine that causes the change of the 213th amino acid residue of the resultant SULT1A1 from arginine to histidine.[17][18] This mutation causes a conformational change in the enzyme, reducing the size of the binding site and altering the thermochemical properties, which halves the substrate binding affinity and enzyme thermostability,[19] and results in diminished enzymatic activity.[16]

The methylation at the distal and proximal promoters of the PST gens is another mutation that accounts for the deficiency, which causes a reduction in PST expression rather than conformational abnormalities. This prevents the binding of RNA polymerase, which therefore inhibits the mRNA expression of the gene for the production of PST, and finally results in PST deficiency.[20]

Disease-causing mechanisms edit

PST deficiency can directly cause diseases by the resulted phenol sulfoconjugation defect which reduces the removal of toxic phenolic compounds.[21]

In the liver, where PST serves as one of the important enzymes involved in detoxification, the reduced transcriptional and translational levels of the PST genes would lead to the accumulation of phenolic xenobiotics and cause liver diseases like hepatic steatosis and cirrhosis,[22] or even liver cancers like hepatocellular carcinoma when phenolic carcinogens are accumulated to trigger their developments.[23]

In clinical neurochemistry, PST, in particular the SULT1A3 isoform, is responsible for the degradation of phenolic neurotransmitters such as dopamine and norepinephrine, and therefore is important in the regulation of neurotransmitters which would greatly affect neurological functions. Deficiency or down-regulation of SULT1A3 would cause the retention of neurotransmitter in synapses which affects brain functions including cognitive flexibility and associative learning.[11][24]

Clinical impact edit

Related disorders edit

Symptoms of PST deficiency are mainly resulted from the disruptions in multiple metabolic processes due to the accumulation of phenols in the body. Common symptoms include polydipsia, flushing, tachycardia, night sweats, and gastrointestinal problems such as diarrhoea.[13] Neurological and psychiatric disorders such as depression may also occur when regulation of phenolic neurotransmitters is disrupted.[25] PST deficiency is also a risk factor for various diseases including autism, migraine, and cancers.

Autism edit

It is suspected that mutations, including both microdeletion and microduplication, of the PST genes are the risk factors of autism spectrum disorder,[26] especially the mutation causing decreased SULT1A activity which is usually reported in autistic individuals.[1] Some studies have found that sulfotransferases like PST are involved in glycosylation, and therefore PST deficiency may cause impaired glycosylation, leading to dystroglycanopathies where severe abnormalities of the central nervous system including neuronal migration and cortical defects would occur, and finally result in autistic behaviours.[27] However, it is still unclear on whether PST deficiency is a cause of autism, or just a biomarker for the disorder.[28] Although recent researches have associated autism with the mutations in the position 16p11.2 on chromosome 16,[29][30] where the gene of the predominant PST isoform in the nervous system SULT1A3 exists,[11] due to the large number of gene in this region, PST deficiency resulted from the mutation there may not be a cause of autism but just a condition that is associated with the mutation of another gene which is causing autism.[31][28]

Migraine edit

PST deficiency in platelets is a risk factor of migraine.[32] It is believed that the reduced PST levels and activity raise the amount of unconjugated amines in the bloodstream and the central nervous system, resulting in a rise of catecholamine level which contributes to the occurrence of recurring headache in migraine.[33] It is also found that dietary intake of foods that are rich in amines may further lower the activity of PST and trigger more serious migraine symptoms.[33]

Cancers edit

It is controversial for whether PST deficiency increases or decreases the risk of cancers.[34] Although one major function of PST is to inactivate phenolic carcinogens, and therefore a deficiency of PST would reduce inactivation of carcinogens and result in a higher risk of cancer, some studies have also found that PST, specifically SULT1A1, is responsible for the toxification of dietary and environmental mutagens which would increase the risk of cancer, and therefore a decreased risk may be associated with the deficient state of SULT1A1.[19]

Pharmacological impacts edit

Drug metabolism of phenolic drugs, such as paracetamol and salicylamide, is greatly dependent on the phenol sulfoconjugation by PST, and therefore careful controls on the dosage forms, routes, rates, and duration of administration of those drugs are important for PST deficient patients to prevent accumulation of drugs in the body and depletion of PST for the sulfoconjugation of other xenobiotics and endogenous substances.[35] High dosage of nonsteroidal anti-inflammatory drugs (NSAIDs), such as aspirin, would also cause a short term inhibition to the activity of PST, and should be administered to PST deficient patients with caution to prevent further reduction in PST activity and accumulation of phenolic compounds which would result in adverse impacts.[14]

References edit

  1. ^ a b Salman ED, Kadlubar SA, Falany CN (April 2009). "Expression and localization of cytosolic sulfotransferase (SULT) 1A1 and SULT1A3 in normal human brain". Drug Metabolism and Disposition. 37 (4): 706–9. doi:10.1124/dmd.108.025767. PMC 2680540. PMID 19171676.
  2. ^ Duffel MW, Marshal AD, McPhie P, Sharma V, Jakoby WB (2001). "Enzymatic aspects of the phenol (aryl) sulfotransferases". Drug Metabolism Reviews. 33 (3–4): 369–95. doi:10.1081/dmr-120001394. PMID 11768773. S2CID 1975310.
  3. ^ Dooley TP (February 1998). "Cloning of the human phenol sulfotransferase gene family: three genes implicated in the metabolism of catecholamines, thyroid hormones and drugs". Chemico-Biological Interactions. 109 (1–3): 29–41. doi:10.1016/S0009-2797(97)00118-X. PMID 9566731.
  4. ^ Coughtrie MW (July 1996). "Sulphation catalysed by the human cytosolic sulphotransferases--chemical defence or molecular terrorism?". Human & Experimental Toxicology. 15 (7): 547–55. doi:10.1177/096032719601500701. PMID 8818707. S2CID 10698535.
  5. ^ a b Weinshilboum R (March 1988). "Phenol sulfotransferase inheritance". Cellular and Molecular Neurobiology. 8 (1): 27–34. doi:10.1007/bf00712908. PMID 3042142. S2CID 27453493.
  6. ^ Sekura RD, Jakoby WB (July 1979). "Phenol sulfotransferases". The Journal of Biological Chemistry. 254 (13): 5658–63. doi:10.1016/S0021-9258(18)50465-8. PMID 447677.
  7. ^ Gamage N, Barnett A, Hempel N, Duggleby RG, Windmill KF, Martin JL, McManus ME (March 2006). "Human sulfotransferases and their role in chemical metabolism". Toxicological Sciences. 90 (1): 5–22. CiteSeerX 10.1.1.319.6099. doi:10.1093/toxsci/kfj061. PMID 16322073.
  8. ^ Chen G, Chen X (September 2003). "Arginine residues in the active site of human phenol sulfotransferase (SULT1A1)". The Journal of Biological Chemistry. 278 (38): 36358–64. doi:10.1074/jbc.M306045200. PMC 3118444. PMID 12867416.
  9. ^ Cook I, Wang T, Girvin M, Leyh TS (December 2016). "The structure of the catechin-binding site of human sulfotransferase 1A1". Proceedings of the National Academy of Sciences of the United States of America. 113 (50): 14312–14317. doi:10.1073/pnas.1613913113. PMC 5167148. PMID 27911811.
  10. ^ a b Yu X, Dhakal IB, Beggs M, Edavana VK, Williams S, Zhang X, et al. (December 2010). "Functional genetic variants in the 3'-untranslated region of sulfotransferase isoform 1A1 (SULT1A1) and their effect on enzymatic activity". Toxicological Sciences. 118 (2): 391–403. doi:10.1093/toxsci/kfq296. PMC 2984532. PMID 20881232.
  11. ^ a b c Darrah K, Wang T, Cook I, Cacace M, Deiters A, Leyh TS (February 2019). "Allosteres to regulate neurotransmitter sulfonation". The Journal of Biological Chemistry. 294 (7): 2293–2301. doi:10.1074/jbc.RA118.006511. PMC 6378965. PMID 30545938.
  12. ^ Dooley TP, Obermoeller RD, Leiter EH, Chapman HD, Falany CN, Deng Z, Siciliano MJ (November 1993). "Mapping of the phenol sulfotransferase gene (STP) to human chromosome 16p12.1-p11.2 and to mouse chromosome 7". Genomics. 18 (2): 440–3. doi:10.1006/geno.1993.1494. PMID 8288252.
  13. ^ a b c O'Reilly BA, Waring RH (1993). "Enzyme and sulphur oxidation deficiencies in autistic children with known food intolerances" (PDF). Journal of Orthomolecular Medicine. 8 (4): 198–200.
  14. ^ a b Alberti A, Pirrone P, Elia M, Waring RH, Romano C (August 1999). "Sulphation deficit in "low-functioning" autistic children: a pilot study". Biological Psychiatry. 46 (3): 420–4. doi:10.1016/s0006-3223(98)00337-0. PMID 10435209. S2CID 20942689.
  15. ^ Waring RH, Ngong JM, Klovrza L, Green S, Sharp H (1997). "Biochemical parameters in autistic children". Dev Brain Dysfunct. 10: 43–47. ISSN 1019-5815.
  16. ^ a b Dash R, Ali MC, Dash N, Azad MA, Hosen SM, Hannan MA, Moon IS (December 2019). "Structural and Dynamic Characterizations Highlight the Deleterious Role of SULT1A1 R213H Polymorphism in Substrate Binding". International Journal of Molecular Sciences. 20 (24): 6256. doi:10.3390/ijms20246256. PMC 6969939. PMID 31835852.
  17. ^ Fernández-Santander A, Novillo A, Gaibar M, Romero-Lorca A, Moral P, Sánchez-Cuenca D, et al. (August 2016). "Cytochrome and sulfotransferase gene variation in north African populations". Pharmacogenomics. 17 (13): 1415–23. doi:10.2217/pgs-2016-0016. PMID 27471773.
  18. ^ Liang G, Miao X, Zhou Y, Tan W, Lin D (May 2004). "A functional polymorphism in the SULT1A1 gene (G638A) is associated with risk of lung cancer in relation to tobacco smoking". Carcinogenesis. 25 (5): 773–8. doi:10.1093/carcin/bgh053. PMID 14688021.
  19. ^ a b Kotnis A, Kannan S, Sarin R, Mulherkar R (October 2008). "Case-control study and meta-analysis of SULT1A1 Arg213His polymorphism for gene, ethnicity and environment interaction for cancer risk". British Journal of Cancer. 99 (8): 1340–7. doi:10.1038/sj.bjc.6604683. PMC 2570530. PMID 18854828.
  20. ^ Kwon MS, Kim SJ, Lee SY, Jeong JH, Lee ES, Kang HS (January 2006). "Epigenetic silencing of the sulfotransferase 1A1 gene by hypermethylation in breast tissue". Oncology Reports. 15 (1): 27–32. doi:10.3892/or.15.1.27. PMID 16328031.
  21. ^ Kuchel O, Buu NT, Serri O (1982). "Sulfoconjugation of catecholamines, nutrition, and hypertension". Hypertension. 4 (5 Pt 2): III93-8. doi:10.1161/01.HYP.4.5_Pt_2.III93. PMID 7049935.
  22. ^ Yalcin EB, More V, Neira KL, Lu ZJ, Cherrington NJ, Slitt AL, King RS (September 2013). "Downregulation of sulfotransferase expression and activity in diseased human livers". Drug Metabolism and Disposition. 41 (9): 1642–50. doi:10.1124/dmd.113.050930. PMC 3876809. PMID 23775849.
  23. ^ Yeo M, Na YM, Kim DK, Kim YB, Wang HJ, Lee JA, et al. (January 2010). "The loss of phenol sulfotransferase 1 in hepatocellular carcinogenesis". Proteomics. 10 (2): 266–76. doi:10.1002/pmic.200900721. PMID 19904771. S2CID 206364501.
  24. ^ Goldstein DS, Swoboda KJ, Miles JM, Coppack SW, Aneman A, Holmes C, et al. (July 1999). "Sources and physiological significance of plasma dopamine sulfate". The Journal of Clinical Endocrinology and Metabolism. 84 (7): 2523–31. doi:10.1210/jcem.84.7.5864. PMID 10404831.
  25. ^ Pennings EJ, Van Kempen GM (October 1983). "Assay of phenol sulphotransferase in human blood". Clinica Chimica Acta; International Journal of Clinical Chemistry. 134 (1–2): 199–206. doi:10.1016/0009-8981(83)90197-3. PMID 6580977.
  26. ^ Weiss LA, Shen Y, Korn JM, Arking DE, Miller DT, Fossdal R, et al. (February 2008). "Association between microdeletion and microduplication at 16p11.2 and autism". The New England Journal of Medicine. 358 (7): 667–75. doi:10.1056/NEJMoa075974. PMID 18184952.
  27. ^ Dwyer CA, Esko JD (October 2016). "Glycan susceptibility factors in autism spectrum disorders". Molecular Aspects of Medicine. 51: 104–14. doi:10.1016/j.mam.2016.07.001. PMC 5556687. PMID 27418189.
  28. ^ a b Bjørklund G, Meguid NA, El-Ansary A, El-Bana MA, Dadar M, Aaseth J, et al. (December 2018). "Diagnostic and Severity-Tracking Biomarkers for Autism Spectrum Disorder". Journal of Molecular Neuroscience. 66 (4): 492–511. doi:10.1007/s12031-018-1192-1. PMID 30357679. S2CID 53027975.
  29. ^ Steinman KJ, Spence SJ, Ramocki MB, Proud MB, Kessler SK, Marco EJ, et al. (November 2016). "16p11.2 deletion and duplication: Characterizing neurologic phenotypes in a large clinically ascertained cohort". American Journal of Medical Genetics. Part A. 170 (11): 2943–2955. doi:10.1002/ajmg.a.37820. PMID 27410714. S2CID 2469192.
  30. ^ Angelakos CC, Watson AJ, O'Brien WT, Krainock KS, Nickl-Jockschat T, Abel T (April 2017). "Hyperactivity and male-specific sleep deficits in the 16p11.2 deletion mouse model of autism". Autism Research. 10 (4): 572–584. doi:10.1002/aur.1707. PMC 6201314. PMID 27739237.
  31. ^ Arbogast T, Ouagazzal AM, Chevalier C, Kopanitsa M, Afinowi N, Migliavacca E, et al. (February 2016). Barsh GS (ed.). "Reciprocal Effects on Neurocognitive and Metabolic Phenotypes in Mouse Models of 16p11.2 Deletion and Duplication Syndromes". PLOS Genetics. 12 (2): e1005709. doi:10.1371/journal.pgen.1005709. PMC 4752317. PMID 26872257.
  32. ^ Littlewood J, Glover V, Sandler M, Petty R, Peatfield R, Rose FC (May 1982). "Platelet phenolsulphotransferase deficiency in dietary migraine". Lancet. 1 (8279): 983–6. doi:10.1016/S0140-6736(82)91990-0. PMID 6122845. S2CID 39305175.
  33. ^ a b Alam Z, Coombes N, Waring RH, Williams AC, Steventon GB (November 1997). "Platelet sulphotransferase activity, plasma sulphate levels and sulphation capacity in patients with migraine and tension headache". Cephalalgia. 17 (7): 761–4. doi:10.1046/j.1468-2982.1997.1707761.x. PMID 9399006. S2CID 20415750.
  34. ^ Liu J, Zhao R, Ye Z, Frey AJ, Schriver ER, Snyder NW, Hebbring SJ (November 2017). "Relationship of SULT1A1 copy number variation with estrogen metabolism and human health". The Journal of Steroid Biochemistry and Molecular Biology. 174: 169–175. doi:10.1016/j.jsbmb.2017.08.017. PMC 5675753. PMID 28867356.
  35. ^ Levy G (July 1986). "Sulfate conjugation in drug metabolism: role of inorganic sulfate". Federation Proceedings. 45 (8): 2235–40. PMID 3459670.

April 14, 2024
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This article is an orphan as no other articles link to it Please introduce links to this page from related articles try the Find link tool for suggestions August 2020 Phenol sulfur transferase deficiency in short PST deficiency is the lack or the reduced activity of the functional enzyme phenol sulfur transferase which is crucial in the detoxification of mainly phenolic compounds by catalysing the sulfate conjugation of the hydroxyl groups in the toxic phenolic compounds to result in more hydrophilic forms for more efficient excretion This metabolic disorder was first discovered in the late 1990s by Dr Rosemary Waring during her researches with autistic children which also made this deficiency commonly associated to the topics of autism Mutations in the PST genes account for the genetic causes of the deficiency of which single nucleotide polymorphism and methylation of promoters are two examples of mutations that respectively cause conformational abnormalities and diminished expressions to the enzyme resulting in the reduced detoxification of phenolic compounds and regulation of phenolic neurotransmitter The deficiency may cause symptoms like flushing tachycardia and depression and be a risk factor for disorders like autism migraine and cancer while it also limits the use of phenolic drugs in PST deficient patients There is currently no drug available for treating PST deficiency However some people suffering from PST deficiency have found taking a digestive enzyme supplement containing Xylanase 10 minutes before eating to greatly reduce symptoms Contents 1 Phenol sulfur transferase 2 Discovery 3 Pathophysiology 3 1 Causes 3 2 Disease causing mechanisms 4 Clinical impact 4 1 Related disorders 4 1 1 Autism 4 1 2 Migraine 4 1 3 Cancers 4 2 Pharmacological impacts 5 ReferencesPhenol sulfur transferase edit nbsp Sulfate conjugation catalyzed by PST in which sulfuryl group from PAPS is transferred by PST to hydroxyl group of phenolic compounds Phenol sulfur transferase in short PST or SULT1 is a subfamily of the enzyme cytosolic sulfotransferases SULTs consisting of at least 8 isoforms in humans 1 that catalyze the transfer of sulfuryl group from 3 phosphoadenosine 5 phosphosulfate PAPS to phenolic compounds 2 resulting in more hydrophilic products that can be more easily expelled from tissues for excretion 3 At high concentration PST could also catalyze the sulfate conjugation of amino groups 4 This enzyme subfamily which exists in nearly all human tissues 5 is important for the detoxification of phenol containing xenobiotics or endogenous compounds 6 including the biotransformation of neurotransmitters and drugs 5 Its expression is controlled by the PST genes located on chromosomes 2 4 and 16 depending on the isoform 7 for example the genes for the predominant isoform throughout the body of human adults SULT1A1 8 9 which is highly heritable and variable between individuals 10 and the most important one in the nervous system SULT1A3 11 are located on chromosome 16 at the position of 16p11 2 to 16p12 1 12 Discovery editPST deficiency was first discovered in the late 1990s by Dr Rosemary Waring through a series of tests during her researches on the mechanisms and characteristics of sulfation in autistic children 13 From the result of the test administering individuals with paracetamol it was found that the level of sulfate conjugate in urine was significantly lower in the autistic individuals as compared to the non autistic controls which was caused by the decreased ability in the formation of sulfated metabolites 14 The level of sulfate in plasma was also found to be significantly lower in autistic children leading to a reduced activity of PST 15 Therefore she concluded that there was possibly a deficiency of PST in autistic children due to the reduction of sulfate in plasma as a substrate of PST 13 Pathophysiology edit nbsp PST is a protein composed of long chain of amino acids in which the substitution of arginine by histidine at the position 213 due to the SULT1A1 2 polymorphism would cause the changes in biochemical properties and reduce the size of substrate binding site 16 Causes edit PST deficiency can be caused by inherited mutations in the PST genes 10 for example the SULT1A1 2 polymorphism which is a single nucleotide polymorphism at the 638th base of the SULT1A1 gene from guanine to adenosine that causes the change of the 213th amino acid residue of the resultant SULT1A1 from arginine to histidine 17 18 This mutation causes a conformational change in the enzyme reducing the size of the binding site and altering the thermochemical properties which halves the substrate binding affinity and enzyme thermostability 19 and results in diminished enzymatic activity 16 The methylation at the distal and proximal promoters of the PST gens is another mutation that accounts for the deficiency which causes a reduction in PST expression rather than conformational abnormalities This prevents the binding of RNA polymerase which therefore inhibits the mRNA expression of the gene for the production of PST and finally results in PST deficiency 20 Disease causing mechanisms edit PST deficiency can directly cause diseases by the resulted phenol sulfoconjugation defect which reduces the removal of toxic phenolic compounds 21 In the liver where PST serves as one of the important enzymes involved in detoxification the reduced transcriptional and translational levels of the PST genes would lead to the accumulation of phenolic xenobiotics and cause liver diseases like hepatic steatosis and cirrhosis 22 or even liver cancers like hepatocellular carcinoma when phenolic carcinogens are accumulated to trigger their developments 23 In clinical neurochemistry PST in particular the SULT1A3 isoform is responsible for the degradation of phenolic neurotransmitters such as dopamine and norepinephrine and therefore is important in the regulation of neurotransmitters which would greatly affect neurological functions Deficiency or down regulation of SULT1A3 would cause the retention of neurotransmitter in synapses which affects brain functions including cognitive flexibility and associative learning 11 24 Clinical impact editRelated disorders edit Symptoms of PST deficiency are mainly resulted from the disruptions in multiple metabolic processes due to the accumulation of phenols in the body Common symptoms include polydipsia flushing tachycardia night sweats and gastrointestinal problems such as diarrhoea 13 Neurological and psychiatric disorders such as depression may also occur when regulation of phenolic neurotransmitters is disrupted 25 PST deficiency is also a risk factor for various diseases including autism migraine and cancers Autism edit It is suspected that mutations including both microdeletion and microduplication of the PST genes are the risk factors of autism spectrum disorder 26 especially the mutation causing decreased SULT1A activity which is usually reported in autistic individuals 1 Some studies have found that sulfotransferases like PST are involved in glycosylation and therefore PST deficiency may cause impaired glycosylation leading to dystroglycanopathies where severe abnormalities of the central nervous system including neuronal migration and cortical defects would occur and finally result in autistic behaviours 27 However it is still unclear on whether PST deficiency is a cause of autism or just a biomarker for the disorder 28 Although recent researches have associated autism with the mutations in the position 16p11 2 on chromosome 16 29 30 where the gene of the predominant PST isoform in the nervous system SULT1A3 exists 11 due to the large number of gene in this region PST deficiency resulted from the mutation there may not be a cause of autism but just a condition that is associated with the mutation of another gene which is causing autism 31 28 Migraine edit PST deficiency in platelets is a risk factor of migraine 32 It is believed that the reduced PST levels and activity raise the amount of unconjugated amines in the bloodstream and the central nervous system resulting in a rise of catecholamine level which contributes to the occurrence of recurring headache in migraine 33 It is also found that dietary intake of foods that are rich in amines may further lower the activity of PST and trigger more serious migraine symptoms 33 Cancers edit It is controversial for whether PST deficiency increases or decreases the risk of cancers 34 Although one major function of PST is to inactivate phenolic carcinogens and therefore a deficiency of PST would reduce inactivation of carcinogens and result in a higher risk of cancer some studies have also found that PST specifically SULT1A1 is responsible for the toxification of dietary and environmental mutagens which would increase the risk of cancer and therefore a decreased risk may be associated with the deficient state of SULT1A1 19 Pharmacological impacts edit Drug metabolism of phenolic drugs such as paracetamol and salicylamide is greatly dependent on the phenol sulfoconjugation by PST and therefore careful controls on the dosage forms routes rates and duration of administration of those drugs are important for PST deficient patients to prevent accumulation of drugs in the body and depletion of PST for the sulfoconjugation of other xenobiotics and endogenous substances 35 High dosage of nonsteroidal anti inflammatory drugs NSAIDs such as aspirin would also cause a short term inhibition to the activity of PST and should be administered to PST deficient patients with caution to prevent further reduction in PST activity and accumulation of phenolic compounds which would result in adverse impacts 14 References edit a b Salman ED Kadlubar SA Falany CN April 2009 Expression and localization of cytosolic sulfotransferase SULT 1A1 and SULT1A3 in normal human brain Drug Metabolism and Disposition 37 4 706 9 doi 10 1124 dmd 108 025767 PMC 2680540 PMID 19171676 Duffel MW Marshal AD McPhie P Sharma V Jakoby WB 2001 Enzymatic aspects of the phenol aryl sulfotransferases Drug Metabolism Reviews 33 3 4 369 95 doi 10 1081 dmr 120001394 PMID 11768773 S2CID 1975310 Dooley TP February 1998 Cloning of the human phenol sulfotransferase gene family three genes implicated in the metabolism of catecholamines thyroid hormones and drugs Chemico Biological Interactions 109 1 3 29 41 doi 10 1016 S0009 2797 97 00118 X PMID 9566731 Coughtrie MW July 1996 Sulphation catalysed by the human cytosolic sulphotransferases chemical defence or molecular terrorism Human amp Experimental Toxicology 15 7 547 55 doi 10 1177 096032719601500701 PMID 8818707 S2CID 10698535 a b Weinshilboum R March 1988 Phenol sulfotransferase inheritance Cellular and Molecular Neurobiology 8 1 27 34 doi 10 1007 bf00712908 PMID 3042142 S2CID 27453493 Sekura RD Jakoby WB July 1979 Phenol sulfotransferases The Journal of Biological Chemistry 254 13 5658 63 doi 10 1016 S0021 9258 18 50465 8 PMID 447677 Gamage N Barnett A Hempel N Duggleby RG Windmill KF Martin JL McManus ME March 2006 Human sulfotransferases and their role in chemical metabolism Toxicological Sciences 90 1 5 22 CiteSeerX 10 1 1 319 6099 doi 10 1093 toxsci kfj061 PMID 16322073 Chen G Chen X September 2003 Arginine residues in the active site of human phenol sulfotransferase SULT1A1 The Journal of Biological Chemistry 278 38 36358 64 doi 10 1074 jbc M306045200 PMC 3118444 PMID 12867416 Cook I Wang T Girvin M Leyh TS December 2016 The structure of the catechin binding site of human sulfotransferase 1A1 Proceedings of the National Academy of Sciences of the United States of America 113 50 14312 14317 doi 10 1073 pnas 1613913113 PMC 5167148 PMID 27911811 a b Yu X Dhakal IB Beggs M Edavana VK Williams S Zhang X et al December 2010 Functional genetic variants in the 3 untranslated region of sulfotransferase isoform 1A1 SULT1A1 and their effect on enzymatic activity Toxicological Sciences 118 2 391 403 doi 10 1093 toxsci kfq296 PMC 2984532 PMID 20881232 a b c Darrah K Wang T Cook I Cacace M Deiters A Leyh TS February 2019 Allosteres to regulate neurotransmitter sulfonation The Journal of Biological Chemistry 294 7 2293 2301 doi 10 1074 jbc RA118 006511 PMC 6378965 PMID 30545938 Dooley TP Obermoeller RD Leiter EH Chapman HD Falany CN Deng Z Siciliano MJ November 1993 Mapping of the phenol sulfotransferase gene STP to human chromosome 16p12 1 p11 2 and to mouse chromosome 7 Genomics 18 2 440 3 doi 10 1006 geno 1993 1494 PMID 8288252 a b c O Reilly BA Waring RH 1993 Enzyme and sulphur oxidation deficiencies in autistic children with known food intolerances PDF Journal of Orthomolecular Medicine 8 4 198 200 a b Alberti A Pirrone P Elia M Waring RH Romano C August 1999 Sulphation deficit in low functioning autistic children a pilot study Biological Psychiatry 46 3 420 4 doi 10 1016 s0006 3223 98 00337 0 PMID 10435209 S2CID 20942689 Waring RH Ngong JM Klovrza L Green S Sharp H 1997 Biochemical parameters in autistic children Dev Brain Dysfunct 10 43 47 ISSN 1019 5815 a b Dash R Ali MC Dash N Azad MA Hosen SM Hannan MA Moon IS December 2019 Structural and Dynamic Characterizations Highlight the Deleterious Role of SULT1A1 R213H Polymorphism in Substrate Binding International Journal of Molecular Sciences 20 24 6256 doi 10 3390 ijms20246256 PMC 6969939 PMID 31835852 Fernandez Santander A Novillo A Gaibar M Romero Lorca A Moral P Sanchez Cuenca D et al August 2016 Cytochrome and sulfotransferase gene variation in north African populations Pharmacogenomics 17 13 1415 23 doi 10 2217 pgs 2016 0016 PMID 27471773 Liang G Miao X Zhou Y Tan W Lin D May 2004 A functional polymorphism in the SULT1A1 gene G638A is associated with risk of lung cancer in relation to tobacco smoking Carcinogenesis 25 5 773 8 doi 10 1093 carcin bgh053 PMID 14688021 a b Kotnis A Kannan S Sarin R Mulherkar R October 2008 Case control study and meta analysis of SULT1A1 Arg213His polymorphism for gene ethnicity and environment interaction for cancer risk British Journal of Cancer 99 8 1340 7 doi 10 1038 sj bjc 6604683 PMC 2570530 PMID 18854828 Kwon MS Kim SJ Lee SY Jeong JH Lee ES Kang HS January 2006 Epigenetic silencing of the sulfotransferase 1A1 gene by hypermethylation in breast tissue Oncology Reports 15 1 27 32 doi 10 3892 or 15 1 27 PMID 16328031 Kuchel O Buu NT Serri O 1982 Sulfoconjugation of catecholamines nutrition and hypertension Hypertension 4 5 Pt 2 III93 8 doi 10 1161 01 HYP 4 5 Pt 2 III93 PMID 7049935 Yalcin EB More V Neira KL Lu ZJ Cherrington NJ Slitt AL King RS September 2013 Downregulation of sulfotransferase expression and activity in diseased human livers Drug Metabolism and Disposition 41 9 1642 50 doi 10 1124 dmd 113 050930 PMC 3876809 PMID 23775849 Yeo M Na YM Kim DK Kim YB Wang HJ Lee JA et al January 2010 The loss of phenol sulfotransferase 1 in hepatocellular carcinogenesis Proteomics 10 2 266 76 doi 10 1002 pmic 200900721 PMID 19904771 S2CID 206364501 Goldstein DS Swoboda KJ Miles JM Coppack SW Aneman A Holmes C et al July 1999 Sources and physiological significance of plasma dopamine sulfate The Journal of Clinical Endocrinology and Metabolism 84 7 2523 31 doi 10 1210 jcem 84 7 5864 PMID 10404831 Pennings EJ Van Kempen GM October 1983 Assay of phenol sulphotransferase in human blood Clinica Chimica Acta International Journal of Clinical Chemistry 134 1 2 199 206 doi 10 1016 0009 8981 83 90197 3 PMID 6580977 Weiss LA Shen Y Korn JM Arking DE Miller DT Fossdal R et al February 2008 Association between microdeletion and microduplication at 16p11 2 and autism The New England Journal of Medicine 358 7 667 75 doi 10 1056 NEJMoa075974 PMID 18184952 Dwyer CA Esko JD October 2016 Glycan susceptibility factors in autism spectrum disorders Molecular Aspects of Medicine 51 104 14 doi 10 1016 j mam 2016 07 001 PMC 5556687 PMID 27418189 a b Bjorklund G Meguid NA El Ansary A El Bana MA Dadar M Aaseth J et al December 2018 Diagnostic and Severity Tracking Biomarkers for Autism Spectrum Disorder Journal of Molecular Neuroscience 66 4 492 511 doi 10 1007 s12031 018 1192 1 PMID 30357679 S2CID 53027975 Steinman KJ Spence SJ Ramocki MB Proud MB Kessler SK Marco EJ et al November 2016 16p11 2 deletion and duplication Characterizing neurologic phenotypes in a large clinically ascertained cohort American Journal of Medical Genetics Part A 170 11 2943 2955 doi 10 1002 ajmg a 37820 PMID 27410714 S2CID 2469192 Angelakos CC Watson AJ O Brien WT Krainock KS Nickl Jockschat T Abel T April 2017 Hyperactivity and male specific sleep deficits in the 16p11 2 deletion mouse model of autism Autism Research 10 4 572 584 doi 10 1002 aur 1707 PMC 6201314 PMID 27739237 Arbogast T Ouagazzal AM Chevalier C Kopanitsa M Afinowi N Migliavacca E et al February 2016 Barsh GS ed Reciprocal Effects on Neurocognitive and Metabolic Phenotypes in Mouse Models of 16p11 2 Deletion and Duplication Syndromes PLOS Genetics 12 2 e1005709 doi 10 1371 journal pgen 1005709 PMC 4752317 PMID 26872257 Littlewood J Glover V Sandler M Petty R Peatfield R Rose FC May 1982 Platelet phenolsulphotransferase deficiency in dietary migraine Lancet 1 8279 983 6 doi 10 1016 S0140 6736 82 91990 0 PMID 6122845 S2CID 39305175 a b Alam Z Coombes N Waring RH Williams AC Steventon GB November 1997 Platelet sulphotransferase activity plasma sulphate levels and sulphation capacity in patients with migraine and tension headache Cephalalgia 17 7 761 4 doi 10 1046 j 1468 2982 1997 1707761 x PMID 9399006 S2CID 20415750 Liu J Zhao R Ye Z Frey AJ Schriver ER Snyder NW Hebbring SJ November 2017 Relationship of SULT1A1 copy number variation with estrogen metabolism and human health The Journal of Steroid Biochemistry and Molecular Biology 174 169 175 doi 10 1016 j jsbmb 2017 08 017 PMC 5675753 PMID 28867356 Levy G July 1986 Sulfate conjugation in drug metabolism role of inorganic sulfate Federation Proceedings 45 8 2235 40 PMID 3459670 Retrieved from https en wikipedia org w index php title Phenol sulfur transferase deficiency amp oldid 1209980259, wikipedia, wiki, book, books, library,

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