Alterations of pancreatic beta-cell mass and islet number due to Ins2-controlled expression of Cre recombinase: RIP-Cre revisited; part 2.

Tissue-specific disruption of genes by targeted expression of Cre recombinase in insulin-producing cells has been widely used to explore pathways involved in regulation of pancreatic beta-cell mass. One particular line of transgenic mice [B6.Cg-Tg(Ins2-cre)25Mgn/J], commonly called RIP-Cre, in which the expression of Cre recombinase is controlled by a short fragment of the rat insulin II gene promoter has been used on at least 20 genes in at least 27 studies. In the majority of these studies (15 out of 27) inactivation of the gene of interest was associated with alterations in islet architecture, islet mass, or pancreatic insulin content. We have tested the hypothesis that genomic integration or expression of Cre recombinase alone causes alterations of beta-cell mass by quantifying islet number and mass in RIP-Cre mice. We have observed a significant hypoplasia of beta-cells in young RIP-Cre mice, and a significant hyperplasia of islets in older RIP-Cre animals. These findings suggest that glucose intolerance and impaired insulin secretion previously described for younger RIP-Cre mice might be caused by transgene-associated islet hypoplasia, and that hyperplasia in older mice might reflect a compensatory response to transgene-related glucose intolerance.

Human cytosolic sulphotransferases: genetics, characteristics, toxicological aspects.

Cytosolic sulphotransferases transfer the sulpho moiety from the cofactor 5'-phosphoadenosine-3'-phosphosulphate (PAPS) to nucleophilic groups of xenobiotics and small endogenous compounds (such as hormones and neurotransmitters). This reaction often leads to products that can be excreted readily. However, other sulpho conjugates are strong electrophiles and may covalently bind with DNA and proteins. All known cytosolic sulphotransferases are members of an enzyme/gene superfamily termed SULT. In humans, 10 SULT genes are known. One of these genes encodes two different enzyme forms due to the use of alternative first exons. Different SULT forms substantially differ in their substrate specificity and tissue distribution. Genetic polymorphisms have been described for three human SULTs. Several allelic variants differ in functional properties, including the activation of promutagens. Only initial results are available from the analysis of SULT allele frequencies in different population groups, e.g. subjects suffering from specific diseases and corresponding controls.