Thomas C. Wood

Sulfation and sulfotransferases 1: Sulfotransferase molecular biology: cDNAs and genes.

Sulfotransferase (ST) enzymes cata‐lyze the sulfate conjugation of many hormones, neu‐rotransmitters, drugs, and xenobiotic compounds. These reactions result in enhanced renal excretion of the sulfate‐conjugated reaction products, but they can also lead to the formation of “bioactivated” metabolites. ST enzymes are members of an emerging gene superfamily that presently includes phenol ST (PST), hydroxysteroid ST (HSST), and, in plants, flavonol ST (FST) “families,” members of which share at least 45% amino acid sequence iden‐tity. These families can be further subdivided into “subfamilies” that are at least 60% identical in amino acid sequence. For example, the PST family includes both PST and estrogen ST (EST) subfamilies. Amino acid sequence motifs exist within ST enzymes that are conserved throughout phylogeny. These signature sequences may be involved in the binding of 3 ‘‐phosphoadenosine‐5 ‘‐phosphosulfate, the cosubstrate for the sulfonation reaction. There are presently five known human cytosolic ST en‐zymes: an EST, an HSST, and three PSTs. cDNAs and genes for all of these enzymes have been cloned, and chromosomal localizations have been reported for all five genes. Genes for these human enzymes, as well as those of other mammalian cytosolic ST enzymes that have been cloned, show a high degree of structural homology, with conservation of the lo‐cations of most intron/exon splice junctions. Human ST enzyme expression varies among individuals. Functionally significant genetic polymorphisms for ST enzymes in humans have been reported, and other molecular genetic mechanisms that might be involved in the regulation of the expression of these enzymes are being explored. Knowledge of the mo‐lecular biology of cytosolic ST enzymes, when placed within a context provided by decades of biochemical research, promises to significantly enhance our understanding of the regulation of the sulfate conjugation of hormones, neurotransmitters, and drugs.—Weinshilboum, R. M., Otterness, D. M., Aksoy, I. A., Wood, T. C., Her, C., Rafto‐ gianis, R. B. Sulfotransferase molecular biology: cDNAs and genes. FASEB J. 11, 3‐14 (1997)

Human Arsenic Methyltransferase (AS3MT) Pharmacogenetics GENE RESEQUENCING AND FUNCTIONAL GENOMICS STUDIES

Arsenic contaminates ground water worldwide. Methylation is an important reaction in the biotransformation of arsenic. We set out to study the pharmacogenetics of human arsenic methyltransferase (AS3MT, previously CYT19). After cloning the human AS3MT cDNA, we annotated the human gene and resequenced its 5′-flanking region, exons, and splice junctions using 60 DNA samples from African-American (AA) and 60 samples from Caucasian-American (CA) subjects. We observed 26 single nucleotide polymorphisms (SNPs), including 3 non-synonymous cSNPs, as well as a variable number of tandem repeats in exon 1 within an area encoding the cDNA 5′-untranslated region. The nonsynonymous cSNPs included T860C (M287T) with frequencies of 10.8 and 10% in AA and CA subjects, respectively, as well as C517T (A173W) in one AA and C917T (T306I) in one CA sample. Haplotype analysis showed that Ile306 was linked to Thr287, so this double variant allozyme was also studied functionally. After expression in COS-1 cells and correction for transfection efficiency, the Trp173 allozyme displayed 31%, Thr287 350%, Ile306 4.8%, and Thr287/Ile306 6.2% of the activity of the wild type (WT) allozyme, with 20, 190, 4.4, and 7.9% of the level of WT immunoreactive protein, respectively. Apparent Km values for S-adenosyl-l-methionine were 4.6, 3.1, and 11 μm for WT, Trp173, and Thr287 allozymes, with Km values for sodium arsenite with the same allozymes of 11.8, 8.9, and 4.5μm. The Ile306 and Thr287/Ile306 allozymes expressed too little activity for inclusion in the substrate kinetic studies. Expression of reporter gene constructs for the 5′-flanking region and the variable number of tandem repeats in the 5′-untranslated region demonstrated cell line-dependent variation in reporter gene expression, with shorter repeats associated with increased transcription in HepG2 cells. These results raise the possibility that inherited variation in AS3MT may contribute to variation in arsenic metabolism and, perhaps, arsenic-dependent carcinogenesis in humans.