Exonic versus intronic SNPs: contrasting roles in revealing the population genetic differentiation of a widespread bird species.

Recent years have seen considerable progress in applying single nucleotide polymorphisms (SNPs) to population genetics studies. However, relatively few have attempted to use them to study the genetic differentiation of wild bird populations and none have examined possible differences of exonic and intronic SNPs in these studies. Here, using 144 SNPs, we examined population genetic differentiation in the saker falcon (Falco cherrug) across Eurasia. The position of each SNP was verified using the recently sequenced saker genome with 108 SNPs positioned within the introns of 10 fragments and 36 SNPs in the exons of six genes, comprising MHC, MC1R and four others. In contrast to intronic SNPs, both Bayesian clustering and principal component analyses using exonic SNPs consistently revealed two genetic clusters, within which the least admixed individuals were found in Europe/central Asia and Qinghai (China), respectively. Pairwise D analysis for exonic SNPs showed that the two populations were significantly differentiated and between the two clusters the frequencies of five SNP markers were inferred to be influenced by selection. Central Eurasian populations clustered in as intermediate between the two main groups, consistent with their geographic position. But the westernmost populations of central Europe showed evidence of demographic isolation. Our work highlights the importance of functional exonic SNPs for studying population genetic pattern in a widespread avian species.

[Functional characterization of two novel splicing mutations in glucokinase gene in monogenic diabetes MODY2].

Two novel mutations in glucokinase (GCK) gene-G to C substitution at -1 position of intron 7 acceptor splice site (c. 864-1G>C) and synonymous substitution c. 666C>G (GTC>GTG, p.V222V) in exon 6--were identified in patients with monogenic diabetes MODY2 (Maturity Onset Diabetes of Young). GCK minigenes with these mutations were constructed. Analysis of splicing products upon transfection of minigenes into human embryonic cell line HEK293 has shown that each of these nucleotide substitutions impair normal splicing. Mutation c.864-1G>C blocks the usage of normal acceptor site which activates cryptic acceptor splice sites within intron 7 and generates aberrant RNAs containing the portions ofintron 7. Synonymous substitution c.666C>G creates novel donor splice site in exon 6 that leads to formation of defective GCK mRNA with deletion of 16 nucleotides of exon 6. Analysis of in vitro splicing of minigenes confirms the inactivating action of novel mutations on glucokinase expression.