Whole mitochondrial DNA sequencing in Alpine populations and the genetic history of the Neolithic Tyrolean Iceman.

The Tyrolean Iceman is an extraordinarily well-preserved natural mummy that lived south of the Alpine ridge ~5,200 years before present (ybp), during the Copper Age. Despite studies that have investigated his genetic profile, the relation of the Iceman´s maternal lineage with present-day mitochondrial variation remains elusive. Studies of the Iceman have shown that his mitochondrial DNA (mtDNA) belongs to a novel lineage of haplogroup K1 (K1f) not found in extant populations. We analyzed the complete mtDNA sequences of 42 haplogroup K bearing individuals from populations of the Eastern Italian Alps - putatively in genetic continuity with the Tyrolean Iceman-and compared his mitogenome with a large dataset of worldwide K1 sequences. Our results allow a re-definition of the K1 phylogeny, and indicate that the K1f haplogroup is absent or rare in present-day populations. We suggest that mtDNA Iceman´s lineage could have disappeared during demographic events starting in Europe from ~5,000 ybp. Based on the comparison of our results with published data, we propose a scenario that could explain the apparent contrast between the phylogeographic features of maternal and paternal lineages of the Tyrolean Iceman within the context of the demographic dynamics happening in Europe from 8,000 ybp.

Detecting Sex-Biased Gene Flow in African-Americans through the Analysis of Intra- and Inter-Population Variation at Mitochondrial DNA and Y- Chromosome Microsatellites.

This study reports on variations at the mitochondrial DNA (mtDNA) hypervariable region 1 (HVR-1) and at seven Y-chromosome microsatellites in an African-American population sample from Chicago, IL, USA. Our results support the hypothesis that the population studied had undergone a European male-biased gene flow. We show that comparisons of intra-and inter-population diversity parameters between African-Americans, Europeans and Africans may help detect sex-biased gene flow, providing a complement to quantitative methods to estimate genetic admixture.

A multi-perspective view of genetic variation in Cameroon.

In this study, we report the genetic variation of autosomal and Y-chromosomal microsatellites in a large Cameroon population dataset (a total of 11 populations) and jointly analyze novel and previous genetic data (mitochondrial DNA and protein coding loci) taking geographic and cultural factors into consideration. The complex pattern of genetic variation of Cameroon can in part be described by contrasting two geographic areas (corresponding to the northern and southern part of the country), which differ substantially in environmental, biological, and cultural aspects. Northern Cameroon populations show a greater within- and among-group diversity, a finding that reflects the complex migratory patterns and the linguistic heterogeneity of this area. A striking reduction of Y-chromosomal genetic diversity was observed in some populations of the northern part of the country (Podokwo and Uldeme), a result that seems to be related to their demographic history rather than to sampling issues. By exploring patterns of genetic, geographic, and linguistic variation, we detect a preferential correlation between genetics and geography for mtDNA. This finding could reflect a female matrimonial mobility that is less constrained by linguistic factors than in males. Finally, we apply the island model to mitochondrial and Y-chromosomal data and obtain a female-to-male migration Nnu ratio that was more than double in the northern part of the country. The combined effect of the propensity to inter-populational admixture of females, favored by cultural contacts, and of genetic drift acting on Y-chromosomal diversity could account for the peculiar genetic pattern observed in northern Cameroon.

HLA class I variation in the West African Pygmies and their genetic relationship with other African populations.

We have studied the polymorphism of HLA class I in two West African Pygmy populations, namely, the Bakola from Cameroon and the Mbenzele from the Central African Republic. A unique number of HLA alleles and haplotypes showed specific patterns of these populations. In this study, we identify two alleles (B*37, B*41) and three haplotypes (A*30-B*37, A*66-B*41 and A*68-B*58) that appear to be 'private' or typical of Western Pygmies. These data reflect similarities with the AKA Pygmies from the Central African Republic. On the other hand, we failed to identify alleles that are found at high frequencies among other sub-Saharan populations (B*42, B*51). Allelic and haplotypic frequency distributions show differences between the two Pygmy groups, e.g. B*35 was very common in the Mbenzele but has been found to be absent in the Bakola. In contrast, B*53, which is found in the Bakola, has been found to be rare in the Mbenzele Pygmies. In order to analyse the genetic relationships of the Bakola and Mbenzele Pygmies with other sub-Saharan populations, HLA gene frequencies were subjected to the Neighbour-Joining tree analysis. The Mbenzele, Bakola and AKA were found to be relatively close to each other and isolated from other sub-African populations. However, both the genetic distances and the within-group variation suggests that the Bakola are more admixed with Bantu farmers than Mbenzele.

Haplotype diversity and linkage disequilibrium at human G6PD: recent origin of alleles that confer malarial resistance.

The frequencies of low-activity alleles of glucose-6-phosphate dehydrogenase in humans are highly correlated with the prevalence of malaria. These "deficiency" alleles are thought to provide reduced risk from infection by the Plasmodium parasite and are maintained at high frequency despite the hemopathologies that they cause. Haplotype analysis of "A-" and "Med" mutations at this locus indicates that they have evolved independently and have increased in frequency at a rate that is too rapid to be explained by random genetic drift. Statistical modeling indicates that the A- allele arose within the past 3840 to 11,760 years and the Med allele arose within the past 1600 to 6640 years. These results support the hypothesis that malaria has had a major impact on humans only since the introduction of agriculture within the past 10,000 years and provide a striking example of the signature of selection on the human genome.

A repository of 14 PCR-loci Italian gene frequencies in the World Wide Web.

A collection of 6830 typing results produced by the Immunohematology Laboratory at the UCSC, pertaining to 11 STRs (FES/FPS, vWA31, HUMTH01, F13A1, MBP, D21S11, D7S460, D18S51, CD4, TPOX, CSF1PO) and 3 AmpFLPs (D1S80, APO-B, COL2A1), is publicly available as an electronic archive at a website.

Inferring microevolutionary patterns from allele-size frequency distributions of minisatellite loci: a worldwide study of the APOB 3' hypervariable region polymorphism.

The availability of numerous population and molecular data makes the apolipoprotein B 3' hypervariable region (APOB 3' HVR) polymorphism ideal for a pilot study of the relationships between the allele-size frequency distributions (referred to as allele-size distributions) of minisatellite loci and the microevolutionary processes underlying their present-day polymorphism in human populations. In this paper, we present a worldwide APOB 3' HVR study, based on published and unpublished data, which refers to 36 populations. We systematically compare APOB 3' HVR within-group diversity (in terms of heterozygosity, number of alleles, and allele-size variance) in numerous human populations, including African, European, Asian, Amerindian, Australomelanesian, and Polynesian groups. Overall, our analyses indicate a greater APOB 3' HVR diversity in Africans than non-Africans. Then, we compare APOB 3' HVR allele-size distributions. The APOB 3' HVR allele-size distribution is found to be quasi-unimodal in Africans and bimodal or nonunimodal in non-African populations. The analysis of the distribution of pairwise comparisons suggests that Africans expanded earlier and/or that their ancestral population was larger than other continental groups. As a final step, we examine APOB 3' HVR interpopulational relationships by using three genetic distances. The F(ST) genetic distance, which assumes genetic drift as being the agent that differentiates populations, provides results that are more congruent with established anthropological knowledge than mutation-based distances (D(SW) and R(ST)). We hypothesize that the ancestral population was characterized by a high heterozygosity, an extended range of allele size, and a quasi-unimodal allele-size distribution centered on allele *37, features persisting in examined African populations. Sampling processes during "out-of-Africa" migrations would be responsible for the decrease in APOB 3' HVR gene diversity and the nonunimodal allele-size distribution observed in non-Africans. Some possible confounding factors are discussed and a prospect of how the hypothesis could be refined and tested is given.

Short tandem-repeat polymorphism/alu haplotype variation at the PLAT locus: implications for modern human origins.

Two dinucleotide short tandem-repeat polymorphisms (STRPs) and a polymorphic Alu element spanning a 22-kb region of the PLAT locus on chromosome 8p12-q11.2 were typed in 1,287-1,420 individuals originating from 30 geographically diverse human populations, as well as in 29 great apes. These data were analyzed as haplotypes consisting of each of the dinucleotide repeats and the flanking Alu insertion/deletion polymorphism. The global pattern of STRP/Alu haplotype variation and linkage disequilibrium (LD) is informative for the reconstruction of human evolutionary history. Sub-Saharan African populations have high levels of haplotype diversity within and between populations, relative to non-Africans, and have highly divergent patterns of LD. Non-African populations have both a subset of the haplotype diversity present in Africa and a distinct pattern of LD. The pattern of haplotype variation and LD observed at the PLAT locus suggests a recent common ancestry of non-African populations, from a small population originating in eastern Africa. These data indicate that, throughout much of modern human history, sub-Saharan Africa has maintained both a large effective population size and a high level of population substructure. Additionally, Papua New Guinean and Micronesian populations have rare haplotypes observed otherwise only in African populations, suggesting ancient gene flow from Africa into Papua New Guinea, as well as gene flow between Melanesian and Micronesian populations.

Microsatellite variation in Central Africa: an analysis of intrapopulational and interpopulational genetic diversity.

As a part of a research project on molecular variation in Central Africa, we have analyzed 10 microsatellites (CD4, CSFO, D3S1358, D18S51, D21S11, F13A1, FES, TH01, TPOX, and VWA) in the Bamileke and Ewondo from Cameroon and the Sanga and Mbenzele Pygmies from the Central African Republic (a total of 390 chromosomes). A statistically significant trend towards heterozygote deficiency was detected in the Mbenzele Pygmies. This was established through the use of powerful exact tests for the Hardy-Weinberg equilibrium. A certain degree of isolation and a small effective size may explain this finding. However, the lack of any substantial reduction in allelic diversity in the Mbenzele does not support the possibility that this group has a smaller effective size in evolutionary terms. A possible explanation based on ethnographic studies suggests that the gene flow from non-Pygmies to Pygmies could have been interrupted only in relatively recent times. The analysis of association between genotypes at pairs of independent loci indicates that the level of subheterogeneity is markedly lower in the Bamileke than in other sampled populations. This may be explained by the combined effect of larger population size, more rigid respect of clanic exogamy, and higher matrimonial mobility of the Bamileke. Finally, we have analyzed interpopulational relationships among our sampled populations and other Central African populations. The results are consistent with a previous study of protein loci (Spedini et al. 1999), which suggests the recent history of the Bamileke and Ewondo has led them to aquire a substantial genetic similarity. Furthermore, the Mbenzele Pygmies diverge from Biaka Pygmies, despite their common origin and geographical proximity. This is probably due to the differentiating effect of genetic drift, which is enhanced by the small effective size of Pygmy populations.

A polymorphic L1 retroposon insertion in the centromere of the human Y chromosome.

We have identified a novel polymorphic L1 retroposon insertion, designated LY1, in the centromeric alphoid array of the human Y chromosome. The element belongs to the transpositionally active Ta subset and its presence is compatible with normal centromere function. It was found at highest frequency in China, where it accounts for 23% of the Han sample, and was present at low frequencies in the surrounding areas, but was not found at all outside Asia. Chromosomes carrying LY1 show considerable microsatellite diversity, suggesting an ancient origin for the lineage at approximately 10 000 years ago (with wide confidence limits), but only limited subsequent migration.

Variability at the uridine diphosphate glucuronosyltransferase 1A1 promoter in human populations and primates.

Variation at the UDP-glucuronosyltransferase (UGT) 1A1 gene promoter is present in humans. Variable numbers of TA repeats in the TATA box of this gene are found which are inversely related to levels of gene expression. We investigated this polymorphism in 658 individuals from a worldwide sample of 15 aboriginal and two admixed human populations. This study shows that there is a great deal of variability across ethnic groups with regard to UGT1A1 allele frequencies, with the most common allele varying in frequency from 33% to 91%. Populations of African origin harbor four different alleles while non-African populations appear to have only two alleles. In addition, alleles associated with lower gene expression levels reach the highest frequencies in populations of African origin and lowest among Asians and Amerindians. Thus, more variability in the metabolism of drugs eliminated by UGT1A1 glucuronidation should be expected in populations of Sub-Saharan African origin. The sequence analysis of nine primate species shows that the number of TA repeats has increased during primate evolution achieving the largest number in humans. We suggest that the UGT1A1 promoter variability does not reflect historical relationships between populations and that it may be maintained by natural selection. Our findings are consistent with the proposal that the TA repeat variation is a balanced polymorphism.

The peopling of sub-Saharan Africa: the case study of Cameroon.

This study analyzes the distribution of ten protein genetic polymorphisms in eighteen populations from the most densely inhabited areas of Cameroon. The languages spoken belong to three different linguistic families [Afro-Asiatic (AA), Nilo-Saharan (NS) and Niger-Kordofanian (NK)]. The analysis of variation of allele frequencies indicates that the level of genetic interpopulation differentiation is rather low (F(st) = 0.011 +/- 0.006) but statistically significant (p < 0.001). This result is not unexpected because of the relatively small geographic area covered by our survey. This value is also significantly lower than the one estimated for other groups of African populations. Among the factors responsible for this, we discuss the possible role of gene flow. There is a considerable genetic differentiation among the AA populations of north Cameroon as is to be expected because they all originated from the first agriculturists of the farming "savanna complex." The Podowko and Uldeme are considerably different from all the other AA groups, probably due to the combined effect of genetic drift and isolation. In the case of the Wandala and Massa, our analyses suggest that genetic admixture with allogeneous groups (especially with the Kanuri) played an important role in determining their genetic differentiation from other AA speaking groups. The Bantu speaking populations (Bakaka, Bamileke Bassa and Ewondo, NK family, Benué Congo subfamily) settled in western and southern Cameroon are more tightly clustered than AA speaking groups. This result shows that the linguistic affinity among these four populations coincides with a substantial genetic similarity despite their different origin. Finally, the Fulbe are genetically distinct from all the populations that belong to their same linguistic phylum (NK), and closer to the neighboring Fali and Tupuri, eastern Adamawa speaking groups of north Cameroon.

Combined use of biallelic and microsatellite Y-chromosome polymorphisms to infer affinities among African populations.

To define Y-chromosome haplotypes, we studied seven biallelic polymorphic sites. We combined data with those from four dinucleotide-repeat polymorphisms, to establish Y-chromosome compound superhaplotypes. Eight biallelic haplotypes that matched the dendrogram proposed by other investigators were identified in 762 Y chromosomes from 25 African populations. For each biallelic site, coalescence time of lineages carrying the derived allele was estimated and compared with previous estimates. The "ancestral" haplotype (haplotype 1A) was observed among Ethiopians, "Khoisan" (!Kung and Khwe), and populations from northern Cameroon. Microsatellite distributions within this haplotype showed that the Khoisan haplotypes 1A are widely divergent from those of the other two groups. Populations from northern Africa and northern Cameroon share a haplotype (i.e., 1C), which is not observed in other African populations but represents a major Eurasian cluster. Haplotypes 1C of northern Cameroon are clearly distinct from those of Europe, whereas haplotypes 1C of northern African are well intermingled with those of the other two groups. Apportionment of diversity for the Y-chromosomal biallelic haplotypes was calculated after populations were clustered into different configurations. Despite some correspondence between language affiliation and genetic similarity, geographic proximity seems to be a better predictor of genetic affinity.

Testing a biochemical model of human genetic resistance to falciparum malaria by the analysis of variation at protein and microsatellite loci.

We recently proposed a biochemical model of genetic resistance to falciparum malaria based on the role of oxidant stress (of parasitic origin) in inducing the irreversible oxidation of hemoglobin and its binding to the erythrocyte membrane (Destro-Bisol et al. 1996). To test the model, we analyzed the relationships between the polymorphisms at the hemoglobin beta chain (HBB) and red cell glutathione peroxidase (GPX1) loci in 18 populations that had been subjected to endemic malaria (Cameroon and Central African Republic). The erythrocytes of GPX1*2 heterozygotes should be more efficient in sheltering the cell membrane from irreversible oxidation and binding of hemoglobin caused by the oxidant stress exerted by Plasmodium falciparum. According to our model, the GPX1*2 allele has an epistatic effect on the HBB*A/*S genotype by lowering its protection against falciparum malaria. In turn, this should decrease the fitness of the HBB*A/*S-GPX1*2/*1 genotype. Our predictions were confirmed. In fact, we observed a clear trend toward a dissociation between the HBB*A/*S and GPX1*2/*1 genotypes in the overall data. To test alternative hypotheses, we also analyzed the genetic variation at 9 protein and 10 autosomal microsatellite loci at both the single- and the 2-locus level. We also discuss the possible relevance of an alternative biochemical pathway. The results further support the conclusions of our study because the dissociation between the GPX1*2/*1 and HBB*A/*S genotypes does not appear to be related either to a general decrease in heterozygosity or to an increased risk of sudden death in HBB*A/*S individuals.

Brief communication: Resistance to Falciparum malaria in alpha-thalassemia, oxidative stress, and hemoglobin oxidation.

A recent survey conducted on Vanuatu Island suggests that resistance to Plasmodium falciparum in alpha-thalassemic individuals may have an immunological basis. This study is important since it seems to undermine the current idea that red-cell genetic defects give protection against falciparum malaria by reducing intraerythrocytic growth and development of the parasite. However, the mechanisms underlying these clinical and genetic observations are not yet fully understood. Based on a review of the relevant literature, we first show that the model based on the interaction between hemoglobin (Hb) and membrane components may provide a molecular basis for the involvement of the immune response in genetic adaptation to malaria. Second, we discuss the main evolutionary implications of the model. Finally, we suggest two approaches by which anthropological studies could provide a useful way of testing the model: 1) analysis of the interactions of malaria-resistance genes with genetic polymorphisms which affect the erythrocyte redox status and 2) study of the antimalarial effects of natural products (introduced as a part of a diet or for traditional antimalarial therapy) capable of interfering with the Hb/membrane interaction.

Estimating European admixture in African Americans by using microsatellites and a microsatellite haplotype (CD4/Alu).

We have analyzed 10 unlinked microsatellites and a linked Alu deletion polymorphism at the CD4 locus in an African American population sample from Chicago (USA). Heterozygosity estimates at the microsatellite loci range from 0.727+/-0.025 (D3S1358) to 0.873+/-0.017 (D18S51), with an average of 0.794+/-0.016. These values are comparable to or higher than those reported for Europeans, with only one exception (D3S1358). The CD4/Alu haplotypic diversity (0.887+/-0.012) is comparable to diversity levels observed in sub-Saharan African populations and is higher than the diversity levels reported in European populations. No consistent pattern of within, between, or multi-locus deviations from Hardy-Weinberg expectations is observed, suggesting a low sub-heterogeneity within the sampled population. We have applied a maximum likelihood method and estimated the proportion of European admixture to the African American gene pool to be 0.26+/-0.02. The narrow confidence interval indicates that allele frequency data from multiple microsatellite loci, whether analyzed independently or as haplotypes, are particularly useful for estimating genetic admixture.