Phylogeography of mitochondrial DNA in western Europe.

For most of the past century, prehistorians have had to rely on the fossil and archaeological records in order to reconstruct the past. In the last few decades, this evidence has been substantially supplemented from classical human genetics. More recently, phylogenetic analyses of DNA sequences that incorporate geographical information have provided a high-resolution tool for the investigation of prehistoric demographic events, such as founder effects and population expansions. These events can be dated using a molecular clock when the mutation rate and founder haplotypes are known. We have previously applied such methods to sequence data from the mitochondrial DNA control region, to suggest that most extant mitochondrial sequences in western Europe have a local ancestry in the Early Upper Palaeolithic, with a smaller proportion arriving from the Near East in the Neolithic. Here, we describe a cladistic notation for mitochondrial variation and expand upon our earlier analysis to present a more detailed portrait of the European mitochondrial record.

Variable levels of a heteroplasmic point mutation in individual hair roots.

During direct sequencing of the first hypervariable segment of the human mitochondrial control region, we identified one individual with a heteroplasmic point mutation at nt 16,256. We used primer extension to analyze the proportions of each mitochondrial haplotype in peripheral blood, buccal cells, and single hair roots from this individual and from eight members of his maternal lineage. Significant levels of heteroplasmy were found in only three individuals, and, in these cases, the proportions of each haplotype were similar in both blood and buccal cells. From the changes in mitochondrial haplotypes within mother-offspring pairs, we calculated that the most likely size of a mitochondrial bottleneck during development was 1-27 segregating units. However, highly variable levels of heteroplasmy were found in single hair roots, even among roots from the same individual. We analyzed a large number of hair roots from one individual and found that the proportion of one haplotype was within a range of 9% to > 99% in different roots. Roots originating from within a small patch of skin had haplotype proportions as variable as those from different areas of skin.

Heteroplasmic point mutations in the human mtDNA control region.

As part of an investigation of the fixation mechanisms of mtDNA mutations in humans, we sequenced the first hypervariable segment of the control region in 180 twin pairs and found evidence of site heteroplasmy in 4 pairs. Significant levels of two mitochondrial haplotypes differing by a single point mutation were found in two MZ pairs, and within each pair, both members had similar levels of heteroplasmy. Two DZ pairs were found in which the predominant mitochondrial haplotype differed within the pair. We measured proportions of mitochondrial haplotypes within two twin pairs and their maternal relatives, using primer extension. In both maternal lineages, most family members were heteroplasmic, and the proportions of each genotype varied widely in different individuals. We used the changes in haplotype proportions within mother-offspring pairs to calculate the size range of potential bottlenecks in mitochondrial numbers occurring during development of the offspring. In most individuals, the most likely effective bottleneck sizes ranged from 3 to 20 segregating units, though in two individuals a small bottleneck was very unlikely and there was no upper limit on its possible size. We also used the data from this study, together with unpublished data from other populations, to estimate the frequency of site heteroplasmy in normal human populations. From this, we calculated that the rate of mutation and fixation in the first hypervariable segment of the human mtDNA control region is between 1.2 x 10(-6) and 2.7 x 10(-5) per site per generation. This range is in good agreement with published estimates calculated by other methods.

Ancient DNA suggests a recent expansion of European cattle from a diverse wild progenitor species.

A total of 11 Bos primigenius and Bos taurus bones from archaeological sites between 500 and 12000 years old were examined for the presence of DNA. It was possible to amplify and sequence mitochondrial control region DNA extracted from seven of the 11 samples, including two Pleistocene B. primigenius samples. We compared the results with published data by constructing phylogenetic networks. The two B. primigenius samples clustered with the extant B. taurus samples in the networks. The similarity between B. primigenius and modern taurine cattle confirms that these should be considered members of a single species. The sequences obtained from the B. taurus specimens were either identical to the reference sequence for modern European cattle or closely related to it. They included two sequences not previously documented. The network analysis of the ancient data highlights the intermediary nature of the B. primigenius sequences between modern European and African B. taurus and the proximity of the ancient DNA B. taurus sequences to modern European B. taurus. Further analysis of the extant data in the light of the ancient DNA results suggests that a degree of Pleistocene diversity survives in the extant European Bos population that is mainly derived from a more recent population expansion.

Genetic diversity in the Iberian Peninsula determined from mitochondrial sequence analysis.

We have analysed 302 bp of the first hypervariable region of the mitochondrial D-loop in 271 individuals from different regions of the Iberian Peninsula and 85 individuals from Algeria. The Basque population is significantly different from neighbouring populations in terms of overall levels of diversity. This is because the majority of sequences in the Basques are restricted to the lineage group defined by the CRS (Cambridge Reference Sequence) and its derivatives although, like other Iberian populations, they showed a unimodal distribution of pairwise sequence differences. The timing of divergence of populations within Iberia points to a shared ancestry of all populations in the Upper Palaeolithic. Further genetic subdivision is apparent in Catalonia and Andalusia, with increased genetic diversity in the latter. Lineage diversity comparisons of Iberian populations with European (Tuscan) and North African (Algerian) populations shows the Iberian Peninsula to be more similar to other European populations, although a small number of Iberian lineages can be traced to North Africa.