A human derived SSADH coding variant is replacing the ancestral allele shared with primates.

BACKGROUND: A growing number of reports describe markers with high frequencies of the ancestral alleles in Africa, contrasting with high frequencies and possibly fixation of derived variants out of Africa. Such a pattern can be explained by either neutral or non-neutral processes. AIM: The study examined worldwide frequencies of two non-synonymous variants in NAD(+)-dependent succinic semialdehyde dehydrogenase (SSADH), in a search for possible signatures of natural selection favouring the derived alleles. SUBJECTS AND METHODS: The typing of 1574 subjects were compiled, representing 60 populations from all continents. SSADH haplotype frequencies were correlated across 52 populations to those of 260 single nucleotide polymorphism (SNP) markers deposited in the CEPH database and of markers reported to be under positive Darwinian selection. RESULTS: In the world population, the c.538C variant is proceeding to replace the ancestral c.538T, shared with primates. The overall population differentiation is within the normal range. A significant correlation was also found between the frequencies of the derived alleles in SSADH and Microcephalin (MCPH1), which showed concerted changes worldwide and, at least in Asian populations, also on a restricted geographical scale. CONCLUSION: The analysis of robust correlations based on a large panel of populations is potentially able to identify clusters of genomic regions or genes showing co-evolution of the frequencies of derived alleles.

SSADH variation in primates: intra- and interspecific data on a gene with a potential role in human cognitive functions.

In the present study we focus on the nucleotide and the inferred amino acid variation occurring in humans and other primate species for mitochondrial NAD(+)-dependent succinic semialdehyde dehydrogenase, a gene recently supposed to contribute to cognitive performance in humans. We determined 2527 bp of coding, intronic, and flanking sequences from chimpanzee, bonobo, gorilla, orangutan, gibbon, and macaque. We also resequenced the entire coding sequence on 39 independent chromosomes from Italian families. Four variable coding sites were genotyped in additional populations from Europe, Africa, and Asia. A test for constancy of the nonsynonymous vs. synonymous rates of nucleotide changes revealed that primates are characterized by largely variable d(N)/d(S) ratios. On a background of strong conservation, probably controlled by selective constraints, the lineage leading to humans showed a ratio increased to 0.42. Human polymorphic levels fall in the range reported for other genes, with a pattern of frequency and haplotype structure strongly suggestive of nonneutrality. The comparison with the primate sequences allowed inferring the ancestral state at all variable positions, suggesting that the c.538(C) allele and the associated functional variant is indeed a derived state that is proceeding to fixation. The unexpected pattern of human polymorphism compared to interspecific findings outlines the possibility of a recent positive selection on some variants relevant to new cognitive capabilities unique to humans.