Distribution of microsomal glutathione transferase 1 in mammalian tissues - A predominant alternate first exon in human tissues

An extensive Northern blot analysis of microsomal glutathione transferase I in human and rat tissues was performed. When normalized against the glyceraldehyde-3-phosphate dehydrogenase or actin expression it was evident that the predominant expression occurs in liver and pancreas. An ontogenetic, as well as a functional, basis for the high levels in these two organs is possible. The relative expression levels in man ranged from: liver and pancreas (100%), to kidney prostate, colon (30-40%), heart, brain, lung, testis, ovary, small intestine (10-20%), placenta, skeletal muscle, spleen, thymus and peripheral blood leucocytes (1-10%). Liver-enriched expression was detected in human fetal tissues with lung and kidney displaying lower levels (10-20%). No transcripts could be detected in fetal brain or heart. When comparing the expression levels between rat and man it is apparent that human extrahepatic mRNA levels are much higher relative to liver. Rat microsomal glutathione transferase mRNA expression ranges from 0.2 to 10% that of liver, with adrenal, uterus, ovary and stomach displaying the highest levels of the organs tested. Based on these observations, and the fact that the enzyme is encoded by a highly conserved single-copy gene, it is suggested that microsomal glutathione transferase 1 performs essential functions vital to most mammalian cell types. We suggest that protection against oxidative stress constitutes one such function. Human expressed sequence tag (EST) characterization yielded four alternate mRNA transcripts with different 5'-ends (four alternate noncoding exons 1). The predominant exon (based on the observed EST frequency) revealed a tissue distribution similar to that obtained using the reading frame as probe. Thus, it appears that one exon preferentially gives rise to mature mRNA in the human tissues examined. This exon is different from the one reported in the original cDNA characterized.