The 49a,f haplotype 11 is a new marker of the EU19 lineage that traces migrations from northern regions of the Black Sea

Previous studies on human Y-chromosome polymorphisms in the European populations highlighted the high frequency of the 49a,f/TaqI haplotype 11 and of the Eu19 (M17) lineage in Eastern Europe. To better understand the origin and the evolution of the Eu19, and its relationship with 49a,f Ht11, this study surveyed 2,235 individuals (mainly from Europe and the Middle East) for the 49a,f Ht11 and for many biallelic markers defining the Eu19 lineage. As previously described, the highest frequency of Eu19 was found in Eastern Europe. All the Eu19 Y-chromosomes turned out to be 49a,f Ht11 or its derivatives, the distribution of which suggests that the Eu19/49a,f Ht11 emerged in Ukraine, probably in a Palaeolithic population. Thereafter, the spread of this lineage toward Europe, Asia, and India occurred at different waves over a few thousands years. At present this seems to indicate the influence of the Ukraine Palaeolithic groups in the gene pool of modern populations. For the first time it is possible to make inferences about the evolution of some haplotypes of the 49a,f system. In spite of its unknown molecular base, this is one of the first most informative polymorphisms of the Y chromosome

Mitochondrial DNA polymorphisms in Italy. II. Molecular analysis of new and rare morphs from Sardinia and Rome

A molecular analysis of morphs found in a previous survey of mtDNA restriction enzyme polymorphisms in Italy revealed that different site changes can give similar patterns and that the same mutation can yield variant morphs for apparently unrelated enzymes. 1. Alternative site variations were found to yield restriction fragment patterns resembling HpaI morph 4, HaeII morph 5 and AvaII morph 2. 2. A strong association was observed between the BamHI morph 3 (gain of site a) and the AvaII morph 9 and its derivatives (loss of site d). This association appears to result from an A to G transition at base pair (bp) 13,368 which simultaneously creates a new BamHI site and abolishes an AvaII site. On the other hand, the loss of the AvaII site d, which in Italy was only found in the above-mentioned association, does not always produce a new BamHI site, as observed in other Caucasian groups. Similarly, the BamHI morph 2 (gain of site b) was always found to be associated with AvaII morphs lacking site f. An A to G transition at bp 16,391 was shown to account for both changes. As in the previous case, the converse is not true. Hence, these data show that AvaII sites d and f were lost in more than one way and one of these seems to be typical of Caucasians. 3. The variation producing BamHI-3/AvaII-9 and derivatives is preferentially associated with MspI morph 4 but this is not a product of a shared mutation. Hence, this association must be the result of the linkage disequilibrium due to the maternal inheritance of mtDNA and lack of recombination. 4. The high frequency of the combination BamHI-3/AvaII-9 and derivatives with MspI-4 found in Italy (29 subjects out of 229 analysed) can best be explained by diffusion of the relevant haplotype rather than by repeated mutational events. 5. The phylogeny trees of all mtDNA morphs so far described and of mtDNA types in Caucasians have been revised taking into account both the inter- and the intra-morph heterogeneity detected by this analysis

MtDNA polymorphisms in a sample of Czechoslovaks and in two groups of Italians

Mitochondrial DNA (mtDNA) variation was investigated in a group of 185 unrelated individuals (64 Czechoslovaks, 99 Northern and 28 Central Italians) using total blood DNA and the six restriction enzymes HpaI, BamHI, HaeII, MspI, AvaII and HincII. Among the 25 patterns (morphs) found, two morphs for HaeII, one for MspI and one for AvaII were new and each was represented by a single individual from Northern Italy. They account for four of the five new types encountered in this survey, being the fifth type characterized by the presence of the very rare morph HaeII-13. The populations analysed confirm the Caucasoid characteristics of certain polymorphisms. A review of the European data available so far is reported

Genetic studies on the Senegal population. I. Mitochondrial DNA polymorphisms

The mtDNA of 186 Senegalese, mainly Wolof and Peuls, were analyzed by means of six restriction enzymes: HpaI, BamHI, HaeII, MspI, AvaII, and HincII. Two of the HpaI, one of the HaeII, two of the MspI, and one of the AvaII morphs had not been described before. The only enzymes which enabled Wolof and Peuls to be differentiated were HincII and, to a lesser extent, HaeII. Important differences emerge in the comparison of Senegalese with Bantu of South Africa and with Bushmen, the only other Africans who, as far as we know, were studied for the same genetic markers. Though Senegalese mtDNAs display typical African features (presence and frequency of HpaI morph 3 and high incidence of AvaII morph 3), the distribution of MspI and AvaII patterns markedly differentiates Senegalese from the others. The phylogeny of mtDNA types in Africa well portrays how the three African groups are clearly distinguishable genetic entities. Bushmen lie at one end of the range of variability, Senegalese being at the other end but still fairly closely related to Bantu. The information provided by individual restriction enzymes to the distinction among the three major ethnic groups is reviewed and discussed

Genetic evidence for an exit of Homo sapiens sapiens from Africa via East Africa.

The out-of-Africa scenario has hitherto provided little evidence for the precise route by which modern humans left Africa. Two major routes of dispersal have been hypothesized: one through North Africa into the Levant, documented by fossil remains, and one through Ethiopia along South Asia, for which little, if any, evidence exists3. Mitochondrial DNA (mtDNA) can be used to trace maternal ancestry. The geographic distribution and variation of mtDNAs can be highly informative in defining potential range expansions and migration routes in the distant past. The mitochondrial haplogroup M, first regarded as an ancient marker of East-Asian origin, has been found at high frequency in India and Ethiopia, raising the question of its origin. (A haplogroup is a group of haplotypes that share some sequence variations.) Its variation and geographical distribution suggest that Asian haplogroup M separated from eastern-African haplogroup M more than 50,000 years ago. Two other variants (489C and 10873C) also support a single origin of haplogroup M in Africa. These findings, together with the virtual absence of haplogroup M in the Levant and its high frequency in the South-Arabian peninsula, render M the first genetic indicator for the hypothesized exit route from Africa through eastern Africa/western India. This was possibly the only successful early dispersal event of modern humans out of Africa

Genetic studies on the Tharu population of Nepal: restriction endonuclease polymorphisms of mithocondrial DNA

7sinonenoneBrega A; Gardella R; Semino O; Morpurgo G; Astaldi Ricotti GB; Wallace DC; Santachiara Benerecetti ASBrega, A; Gardella, Rita; Semino, O; Morpurgo, G; Astaldi Ricotti, Gb; Wallace, Dc; Santachiara Benerecetti, A

mtDNA and Y-chromosome polymorphisms in four Native American populations from southern Mexico

MtDNA sequence variation was examined in 60 Native Americans (Mixtecs from the Alta, Mixtecs from the Baja, Valley Zapotecs, and Highland Mixe) from southern Mexico by PCR amplification and high-resolution restriction endonuclease analysis. Four groups of mtDNA haplotypes (haplogroups A, B, C, and D) characterize Amerind populations, but only three (haplogroups A, B, and C) were observed in these Mexican populations. The comparison of their mtDNA variation with that observed in other populations from Mexico and Central America permits a clear distinction among the different Middle American tribes and raises questions about some of their linguistic affiliations. The males of these population samples were also analyzed for Y-chromosome RFLPs with the probes 49a, 49f, and 12f2. This analysis suggests that certain Y-chromosome haplotypes were brought from Asia during the colonization of the Americas, and a differential gene flow was introduced into Native American populations from European males and females