Low prevalence of connexin-40 gene variants in atrial tissues and blood from atrial fibrillation subjects

Abstract Background The atrial gap junction protein connexin-40 (Cx40) has been implicated to play an important role in atrial conduction and development of atrial fibrillation (AF). However, the frequency of Cx40 mutations in AF populations and their impact on Cx40 expression remains unclear. In this study, we sought to identify polymorphisms in the Cx40 gene GJA5, investigate the potential functional role of these polymorphisms, and determine their allelic frequencies. The prevalence of nonsynonymous Cx40 mutations in blood and atrial tissue was also compared to mutation frequencies reported in prior studies. Methods We conducted direct sequencing of the GJA5 coding and 3′ UTR regions in blood samples from 91 lone AF subjects and 67 atrial tissue-derived samples from a lone cohort, a mixed AF cohort, and several transplant donors. Reporter gene transfection and tissue allelic expression imbalance assays were used to assess the effects of a common insertion/deletion polymorphism on Cx40 mRNA stability and expression. Results We identified one novel synonymous SNP in blood-derived DNA from a lone AF subject. In atrial tissue-derived DNA from lone and mixed AF subjects, we observed one novel nonsynonymous SNP, one rare previously reported synonymous SNP, and one novel 3′ UTR SNP. A previously noted 25 bp insertion/deletion polymorphism in the 3′ UTR was found to be common (minor allele frequency = 0.45) but had no effect on Cx40 mRNA stability and expression. The observed prevalence of nonsynonymous Cx40 mutations in atrial tissues derived from lone AF subjects differed significantly (p = 0.03) from a prior atrial tissue study reporting a high mutation frequency in a group of highly selected young lone AF subjects. Conclusions Our results suggest that Cx40 coding SNPs are uncommon in AF populations, although rare mutations in this gene may certainly lead to AF pathogenesis. Furthermore, a common insertion/deletion polymorphism in the Cx40 3′ UTR does not appear to play a role in modulating Cx40 mRNA levels

Specific binding of a designed pyrrolidine abasic site analog to multiple DNA glycosylases

In the base excision DNA repair pathway, DNA glycosylases recognize damaged bases in DNA and catalyze their excision through hydrolysis of the N-glycosidic bond. Attempts to understand the structural basis for DNA damage recognition by DNA glycosylases have been hampered by the short-lived association of these enzymes with their DNA substrate. To overcome this problem, we have employed an approach involving the design and synthesis of inhibitors that form stable complexes with DNA glycosylases, which can then be studied biochemically and structurally. We have previously reported that double-stranded DNA containing a pyrrolidine abasic site analog (PYR) forms an extremely stable complex with the DNA glycosylase AlkA and potently inhibits the reaction catalyzed by the enzyme (Scharer, O. D., Ortholand, J.-Y., Ganesan, A., Ezaz-Nikpay, R., and Verdine, G. L. (1995) J. Am. Chem. Sec. 117, 6623-6624). Here we investigate the interaction of this inhibitor with a variety of additional DNA glycosylases. With the exception of uracil DNA glycosylase all the glycosylases tested bind specifically to PYR containing oligonucleotides. By comparing the interaction of DNA glycosylases with PYR and the structurally related tetrahydrofuran abasic site analog, we assess the importance of the positively charged ammonium group of the pyrrolidine in binding to the active site of these enzymes. Such a general inhibitor of DNA glycosyases provides a valuable tool to study stable complexes of these enzymes bound to substrate-like moleculesclos