Lower mitochondrial DNA content relates to high-altitude adaptation in Tibetans.

Mitochondrial DNA (mtDNA) is crucial to mitochondria in energy production and other physiological functions. When lowlanders arrive at high altitude, the mitochondrial content tends to decrease. However, the mtDNA content of native highlanders share the same feature as lowlanders remains unknown. It is also interesting to dissect the other changes in blood plasma that might accompany the change of mtDNA content. To address these issues, we recruited 241 Tibetan subjects in Tibet and 220 Han subjects in Shaanxi province. Relative mtDNA copy number and blood biochemical indexes were measured. Results show that relative mtDNA copy number in Tibetans is significantly lower as compared to Han subjects; sex, age, blood glucose, triglyceride and total cholesterol show no influence on mtDNA content, but carbon dioxide combining power is negatively correlated with mtDNA content. These results indicate that an increase in CO2 combining power along with lower mtDNA content may provide adaptive potential.

Mitochondrial DNA content contributes to climate adaptation using Chinese populations as a model.

Maintaining a balance between ATP synthesis and heat generation is crucial for adapting to changes in climate. Variation in the mitochondrial DNA (mtDNA), which encodes 13 subunits of the respiratory chain complexes, may contribute to climate adaptation by regulating thermogenesis and the use of bioenergy. However, studies looking for a relationship between mtDNA haplogroups and climate have obtained mixed results, leaving unresolved the role of mtDNA in climate adaptation. Since mtDNA content can regulate human bioenergy processes and is known to influence many physiological traits and diseases, it is possible that mtDNA content contributes to climate adaptation in human populations. Here, we analyze the distribution of mtDNA content among 27 Chinese ethnic populations residing across China and find a significant association between mtDNA content and climate, with northern populations having significantly higher mtDNA content than southern populations. Functional studies have shown that high mtDNA content correlates with an increase in the expression of energy metabolism enzymes, which may accelerate thermogenesis. This suggests that the significantly higher mtDNA content observed in northern populations may confer a selective advantage in adapting to colder northern climates.

Absence of association between mitochondrial DNA C150T polymorphism and longevity in a Han Chinese population.

Human longevity has been associated with mitochondrial DNA (mtDNA) coding region polymorphisms, as well as the C150T polymorphism in the non-coding region in previous studies especially in Europeans. This study investigated the potential association between the mtDNA C150T polymorphism and longevity in a Han Chinese population. Leukocyte mtDNAs from two groups of a Han Chinese population living in Dujiangyan city of Sichuan province, including 556 longevous individuals (90-108 years-old) and 403 unrelated controls, were analyzed and mtDNA haplogroups were determined by sequencing control regions and restriction fragment length polymorphisms (RFLPs) in coding regions. Our results did not show a universal association between the mitochondrial C150T polymorphism and longevity in this population. Even when mtDNA haplogroups defined by C150T and gender were taken into account, there was no significant association with longevity. In conclusion, the mtDNA C150T polymorphism could not present an accumulation in an elderly Han Chinese population. Previous association studies might have been influenced by nuclear DNA and/or environment factors.

Inland post-glacial dispersal in East Asia revealed by mitochondrial haplogroup M9a'b.

BACKGROUND: Archaeological studies have revealed a series of cultural changes around the Last Glacial Maximum in East Asia; whether these changes left any signatures in the gene pool of East Asians remains poorly indicated. To achieve deeper insights into the demographic history of modern humans in East Asia around the Last Glacial Maximum, we extensively analyzed mitochondrial DNA haplogroup M9a'b, a specific haplogroup that was suggested to have some potential for tracing the migration around the Last Glacial Maximum in East Eurasia. RESULTS: A total of 837 M9a'b mitochondrial DNAs (583 from the literature, while the remaining 254 were newly collected in this study) pinpointed from over 28,000 subjects residing across East Eurasia were studied here. Fifty-nine representative samples were further selected for total mitochondrial DNA sequencing so we could better understand the phylogeny within M9a'b. Based on the updated phylogeny, an extensive phylogeographic analysis was carried out to reveal the differentiation of haplogroup M9a'b and to reconstruct the dispersal histories. CONCLUSIONS: Our results indicated that southern China and/or Southeast Asia likely served as the source of some post-Last Glacial Maximum dispersal(s). The detailed dissection of haplogroup M9a'b revealed the existence of an inland dispersal in mainland East Asia during the post-glacial period. It was this dispersal that expanded not only to western China but also to northeast India and the south Himalaya region. A similar phylogeographic distribution pattern was also observed for haplogroup F1c, thus substantiating our proposition. This inland post-glacial dispersal was in agreement with the spread of the Mesolithic culture originating in South China and northern Vietnam.

Large-scale mtDNA screening reveals a surprising matrilineal complexity in east Asia and its implications to the peopling of the region.

In order to achieve a thorough coverage of the basal lineages in the Chinese matrilineal pool, we have sequenced the mitochondrial DNA (mtDNA) control region and partial coding region segments of 6,093 mtDNAs sampled from 84 populations across China. By comparing with the available complete mtDNA sequences, 194 of those mtDNAs could not be firmly assigned into the available haplogroups. Completely sequencing 51 representatives selected from these unclassified mtDNAs identified a number of novel lineages, including five novel basal haplogroups that directly emanate from the Eurasian founder nodes (M and N). No matrilineal contribution from the archaic hominid was observed. Subsequent analyses suggested that these newly identified basal lineages likely represent the genetic relics of modern humans initially peopling East Asia instead of being the results of gene flow from the neighboring regions. The observation that most of the newly recognized mtDNA lineages have already differentiated and show the highest genetic diversity in southern China provided additional evidence in support of the Southern Route peopling hypothesis of East Asians. Specifically, the enrichment of most of the basal lineages in southern China and their rather ancient ages in Late Pleistocene further suggested that this region was likely the genetic reservoir of modern humans after they entered East Asia.

Tracing the origins of Hakka and Chaoshanese by mitochondrial DNA analysis.

Hakka and Chaoshanese are two unique Han populations residing in southern China but with northern Han (NH) cultural traditions and linguistic influences. Although most of historical records indicate that both populations migrated from northern China in the last two thousand years, no consensus on their origins has been reached so far. To shed more light on the origins of Hakka and Chaoshanese, mitochondrial DNAs (mtDNAs) of 170 Hakka from Meizhou and 102 Chaoshanese from Chaoshan area, Guangdong Province, were analyzed. Our results show that some southern Chinese predominant haplogroups, e.g. B, F, and M7, have relatively high frequencies in both populations. Although median network analyses show that Hakka/Chaoshanese share some haplotypes with NH, interpopulation comparison reveals that both populations show closer affinity with southern Han (SH) populations than with NH. In consideration of previous results from nuclear gene (including Y chromosome) research, it is likely that matrilineal landscapes of both Hakka and Chaoshanese have largely been shaped by the local people during their migration southward and/or later colonization in southern China, and factors such as cultural assimilation, patrilocality, and even sex-bias in the immigrants might have played important roles during the process.