Y-chromosome DNA haplotypes in Basques

One Y-specific DNA polymorphism (p49/TaqI) was studied in a sample of 97 French Basques and compared with those found in 7 other French, Iberian, and Italian populations. A particularly high frequency (72.2%) of Y-haplotype XV was observed in Basques, compared to values (mean of 41%) obtained in other Western Europeans. Basques were also characterized by virtual absence, or presence at a low level, of the South or Near Eastern haplotypes XII, VII, and VIII. Considered together, these results confirm that Basques are a very ancient European population which has had little previous contact with the Neolithics.     

North African Berber and Arab influences in the western Mediterranean revealed by Y-chromosome DNA haplotypes

We have analyzed Y-chromosome diversity in the western Mediterranean area, examining p49a,f TaqI haplotype V and subhaplotypes Vb (Berber) and Va (Arab). A total of 2,196 unrelated DNA samples, belonging to 22 populations from North Africa and the southern Mediterranean coast of occidental Europe, have been typed. Subhaplotype Vb, predominant in a Berber population of Morocco (63.5%), was also found at high frequencies in southern Portugal (35.9%) and Andalusia (25.4%). The Arab subhaplotype Va, predominant in Algeria (53.9%) and Tunisia (50.6%), was also found at a relatively high frequency in Sicily (23.1%) and Naples (16.4%); its highest frequency in Iberia was in northern Portugal (22.8%) and Andalusia (15.5%). In Iberia there is a gradient of decreasing frequencies in latitude for both subhaplotypes Va and Vb, related to eight centuries of Muslim domination (8th to 15th centuries) in southern Iberia.     

Y-chromosome haplotypes in Corsica

We studied the distribution of Y-chromosome specific haplotypes (detected by the TaqI polymorphism of probes p49a,f) on a total of 328 Corsican males native of the regions of Ajaccio, Bastia and Corte. Three haplotypes are differential among regions: haplotype XV (A3 C1 D2 F1 I1), preponderant in the North of the island, haplotype V (A2 C0 D0 F1 I1) in the South, and haplotype XII (A3 C0 D1 F1 I0) in the highlands of the centre. Distribution of haplotypes can be explained by Corsican history and geography.     

Y-chromosome DNA haplotypes in Jews: comparisons with Lebanese and Palestinians

One Y-specific DNA polymorphism (p49/Taq I) was studied in 54 Lebanese and 69 Palestinian males, and compared with the results found in 693 Jews from three communities (Oriental, Sephardic, and Ashkenazic). Lebanese, Palestinian, and Sephardic Jews seem to be similar in their Y-haplotype patterns, both with regard to the haplotype distributions and the ancestral haplotype VIII frequencies. The haplotype distribution in Oriental Jews is characterized by a significantly higher frequency of haplotype VIII. These results confirm similarities in the Y-haplotype frequencies in Lebanese, Palestinian, and Sephardic Jewish men, three Near-Eastern populations sharing a common geographic origin.     

Y-chromosome haplotypes in azoospermic Israeli men

Among azoospermic and severely oligozoospermic men, 7-15% present microdeletions of a region on the long arm of the Y chromosome that has been called AZF (azoospermia factor). Because these deletions present varying relative frequencies in different populations, we decided to ascertain whether their presence was correlated with specific Y-chromosome haplotypes. For that, we evaluated 51 infertile Israeli men, 9 of whom had microdeletions in AZF. Haplotypes were identified using a hierarchical system with eight biallelic DNA markers. We also checked for the presence of the deletion marker 50f2/C, which was absent in all seven patients with isolated AZFc deletion and also in the one patient with isolated AZFb deletion, suggesting that these microdeletions overlap. As expected, haplogroup J was the most common (47%), followed by equal frequencies of haplogroups Y* (xDE, J, K), P* (xR1a, R1b8), K* (xP), and E. In six patients with AZFc deficiencies of comparable size, three belonged to haplogroup J, two belonged to haplogroup P* (xR1a, R1b8), and one belonged to haplogroup R1a. Also, there were no significant differences in the haplotype frequencies between the groups with and without microdeletions. Thus we did not identify any association of a specific haplogroup with predisposition to de novo deletion of the AZF region in the Israeli population.     

Characterization of ancestral and derived Y-chromosome haplotypes of New World native populations.

We analyze the allelic polymorphisms in seven Y-specific microsatellite loci and a Y-specific alphoid system with 27 variants (alphah I-XXVII), in a total of 89 Y chromosomes carrying the DYS199T allele and belonging to populations representing Amerindian and Na-Dene linguistic groups. Since there are no indications of recurrence for the DYS199C-->T transition, it is assumed that all DYS199T haplotypes derive from a single individual in whom the C-->T mutation occurred for the first time. We identified both the ancestral founder haplotype, 0A, of the DYS199T lineage and seven derived haplogroups diverging from the ancestral one by one to seven mutational steps. The 0A haplotype (5.7% of Native American chromosomes) had the following constitution: DYS199T, alphah II, DYS19/13, DYS389a/10, DYS389b/27, DYS390/24, DYS391/10, DYS392/14, and DYS393/13 (microsatellite alleles are indicated as number of repeats). We analyzed the Y-specific microsatellite mutation rate in 1,743 father-son transmissions, and we pooled our data with data in the literature, to obtain an average mutation rate of.0012. We estimated that the 0A haplotype has an average age of 22,770 years (minimum 13,500 years, maximum 58,700 years). Since the DYS199T allele is found with high frequency in Native American chromosomes, we propose that 0A is one of the most prevalent founder paternal lineages of New World aborigines.     

Brief communication: Y-chromosome haplotypes in Egypt

We analyzed Y-chromosome haplotypes in the Nile River Valley in Egypt in 274 unrelated males, using the p49a,f TaqI polymorphism. These individuals were born in three regions along the river: in Alexandria (the Delta and Lower Egypt), in Upper Egypt, and in Lower Nubia. Fifteen different p49a,f TaqI haplotypes are present in Egypt, the three most common being haplotype V (39.4%), haplotype XI (18.9%), and haplotype IV (13.9%). Haplotype V is a characteristic Arab haplotype, with a northern geographic distribution in Egypt in the Nile River Valley. Haplotype IV, characteristic of sub-Saharan populations, shows a southern geographic distribution in Egypt.     

Y-chromosome specific alleles and haplotypes in European and Asian populations: Linkage disequilibrium and geographic diversity

Variation on the Y chromosome may permit our understanding the evolution of the human paternal lineage and male gene flow. This study reports upon the distribution and non random association of alleles at four Y-chromosome specific loci in four populations, three Caucasoid (Italian, Greek and Slav) and one Asian. The markers include insertion/deletion (p12f), point mutation (92R7 and pYαI), and repeat sequence (p21A1) polymorphisms. Our data confirm that the p12f/TaqI 8 kb allele is a Caucasoid marker and that Asians are monomorphic at three of the loci (p12f, 92R7, and pYαI). The alleles at 92R7 and pYαI were found to be in complete disequilibrium in Europeans. Y-haplotype diversity was highly significant between Asians and all three European groups (P < 0.001), but the Greeks and Italians were also significantly different with respect to some alleles and haplotypes (P < 0.02). We find strong evidence that the p12f/TaqI 8 kb allele may have arisen only once, as a deletion event, and, additionally, that the present-day frequency distribution of Y chromosomes carrying the p12f/8 kb allele suggests that it may have been spread by colonising sea-faring peoples from the Near East, possibly the Phoenicians, rather than by expansion of Neolithic farmers into continental Europe. The p12f deletion is the key marker of a unique Y chromosome, found only in Caucasians to date, labelled ‘Mediterranean’ and this further increases the level of Y-chromosome diversity seen among Caucasoids when compared to the other major population groups. Am J Phys Anthropol 104:167–176, 1997. © 1997 Wiley-Liss, Inc.     

North African genes in Iberia studied by Y-chromosome DNA haplotype 5.

The frequency of haplotype 5 at the Y-chromosome-specific DNA polymorphism (p49/TaqI) was reported in a study of 487 males originating from five different geographic locations in Iberia and North Africa. The highest frequency of haplotype 5 (68.9%) was previously observed in Berbers from Morocco, and it has been established that this haplotype is a characteristic Berber haplotype in North Africa. The relative frequencies of haplotype 5 distribution show a geographical gradient of decreasing frequency according to latitude in Iberia: 40.8% in Andalusia, 36.2% in Portugal, 12.1% in Catalonia, and 11.3% in the Basque Country; such a cline of decreasing frequency of haplotype 5 from the south to the north in Iberia clearly establishes a gene flow from North Africa towards Iberia.     

Paternal European ancestry in French Polynesia detected by Y-chromosome haplotypes

Y-chromosome-specific polymorphisms p49f-a/TaqI were studied in a sample of 68 French Polynesians, and five haplotypes were observed. Three of them were haplotypes characteristic of European ancestry. The mean haplotype (45.6%) in French Polynesia is haplotype XV, a typical western European haplotype. Such an elevated frequency of European haplotypes is due to male gene flow from Europeans in French Polynesia.     

Y chromosome probe p49a detects complex PvuII haplotypes and many new TaqI haplotypes in southern African populations.

Y-specific 49a/TaqI haplotypes were determined for 831 individuals drawn from 21 different southern African populations. A total of 31 new haplotypes were observed, some of which contained new alleles or allelic variants. Duplication, in addition to CpG mutation, is implicated in the generation of certain allelic variants. Cluster analysis of genetic distances between the populations, calculated using the 49a/TaqI haplotype frequencies, revealed a basic split between African and non-African populations. Hybrid groups cluster with the caucasoid groups, indicating that male gene flow has occurred from the latter into the former. Clustering of the negroid and Khoisan groups is not what might have been expected from the known linguistic affinities. It is suggested that the 49a/TaqI haplotype analysis of these populations is not sufficiently sensitive to distinguish between many of the populations. The Y-specific 49a/PvuII polymorphism was studied in 127 individuals from southern African populations, and 17 polymorphic fragments ranging in size from 3.6 kb to greater than 48 kb were identified. A total of 53 PvuII haplotypes were observed, corresponding to only 30 TaqI haplotypes. There appears to be poor correlation between the two polymorphisms.     

Genetic substructure in South African Bantu-speakers: evidence from autosomal DNA and Y-chromosome studies

The extent of genetic differentiation between seven South African Bantu-speaking groups (Zulu, Xhosa, Tsonga/Shangaan, Southern Sotho, Pedi, Tswana, and Venda) was assessed from coancestry coefficients (F(ST)) estimated from autosomal serogenetic, DNA, and Y-chromosome DNA haplotypes. The overall F(ST) obtained from the autosomal data was 0.002, and that from the Y chromosome data was 0.014. The genetic relationships between groups examined were inferred from their cluster affinities in phylogenetic trees constructed from the genetic distances between them. Both autosomal and Y-chromosome DNA studies reveal that 6 of the 7 South African Bantu-speaking groups cluster according to their linguistic groupings, the exception being the Tsonga, who do not cluster with other Nguni language speakers, but rather with the Venda who live close to them. This suggests that the invading Shangaan-speakers, whose Nguni language was adopted by the Tsonga, did not have a major effect on the Tsonga gene pool, and that gene flow from the Venda into the Tsonga may have been considerable. Genetic distances were found to correlate with geographic distances between the regions where each group's apparent population density is the highest. Linguistic distances were also found to correlate with genetic distances, but linguistic and geographic distances showed no correlation. Together, these results suggest that linguistic and some genetic differentiation took place before the groups (or their forerunners) reached their present-day locations, and that further genetic change occurred after their arrival.     

The origin of Yakuts: analysis of Y-chromosome haplotypes

Gene pool structure of Sakha Republic (Yakutia) native population has been studied: we defined composition and frequencies of Y-chromosome haplogroups for Yakuts. Six haplogroups: C3 x M77, C3c, N*, N2, N3a and R1a1 have been revealed in Yakut gene pool. A greater part of Y-chromosome in Yakut population belongs to N3a haplogroup (89%). All investigated Yakut population samples have low values of gene diversity, calculated based on haplogroup frequencies. Gene differentiation of the investigated samples estimated using the analysis of molecular variance (AMOVA) by two marker systems (haplogroup frequencies and microsatellite haplotypes of Y-chromosome) revealed a portion of interpopulation differences amounting to 0.24 and 2.85%, respectively. Frequencies and molecular phylogeny of YSTR-haplotypes were revealed for N3a haplogroup of Y-chromosome. Altogether forty haplotypes were found in Yakuts. Evenks and Yakuts are characterized by overlapping and very specific spectrum of N3a haplotypes, which is not typical for other Siberian ethnic groups. Cluster analysis of populations by N3a YSTR-haplotypes shows Yakut isolation from Turkic-speaking populations in the South Siberia. Genetic diversity generation time for a specific spectrum of Yakut haplotypes was estimated as 4.45 +/- 1.96 thousand years. As opposed to the data on mtDNA, the obtained results give an evidence for significant contribution of a local palaeolithic component into Y-chromosomal Yakut gene pool. Ethnogenetic reconstruction of the present picture of genetic diversity in N3a haplogroup in the territory of Siberia is under consideration.     

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.     

Different haplotypes for cystic fibrosis-linked DNA polymorphisms in Polish and Dutch populations

Summary We analyzed DNA from 34 Polish and 63 Dutch cystic fibrosis (CF) patients and their families using the polymorphic markers XV2c and KM19, which are in linkage disequilibrium with the CF mutation. Strong linkage disequilibrium was found in the Dutch population sample, but the haplotypes of the Polish chromosomes showed a significantly less extreme disequilibrium. Our data and previous studies indicate that the highest degree of homogeneity of the CF defect and hence the best possible use of the XV2c/KM19/CF linkage disequilibrium for CF carrier detection/exclusion is in populations of northern European origin.     

Y chromosome DNA polymorphisms in two African populations.

Y chromosome-specific DNA polymorphisms were detected using probe p49f after restriction with TaqI enzyme on samples coming from two African populations: Bantus and Pygmies. All the main TaqI alleles at five Y loci already found in Caucasians are also found in these two populations; 12 of the 16 Caucasian haplotypes were found in these two African populations, and two new haplotypes are Pygmy specific. A proposed phylogeny of the various haplotypes that was derived by using the parsimony criterion established that haplotypes XIII and XVIII, respectively the most frequent one and only one present in Pygmies, are probably ancestral.     

The origin of Yakuts: Analysis of the Y-chromosome haplotypes

The gene pool structure was studied for the indigenous population of the Sakha Republic (Yakutia). The composition and frequencies of Y-chromosome haplotypes in Yakuts were characterized. Six haplogroups were observed: C3×M77, C3c, N*, N2, N3a, and R1a1, N3a being the most common (89%). The gene diversity computed from the haplogroup frequencies was low in all samples examined. Gene differentiation was analyzed by AMOVA with two marker systems (haplogroup frequencies and Y-chromosomal microsatellite haplotypes) and was estimated at 0.24 and 2.85%, respectively. The frequencies and molecular phylogeny of the YSTR haplotypes were studied for the N3a haplogroup. In total, 40 haplotypes were found in Yakuts. Evenks and Yakuts displayed highly specific overlapping N3a haplotype spectra, atypical for other Siberian ethnic groups. Cluster analysis with N3a YSTR haplotypes showed that Yakuts are isolated from other Turkic-speaking populations of Southern Siberia. The genetic diversity generation time was estimated at 4450 ± 1960 years for the Yakut haplotype spectrum. In contrast to mtDNA data, the results suggest a significant contribution of the local Paleolithic component to the Y-chromosome gene pool of Yakuts. Ethnogenetic reconstructions were inferred from the diversity and phylogeography of the N3a haplogroup in Siberia.     

Evolution of human Y-chromosome DNA

We have used human male-specific 3.4 kb Hae III restriction endonuclease fragments to explore the evolutionary history of man's Y-chromosome. We have identified four sets of reiterated, sequences on the basis of their relative sequence homology with autosomal DNA. The sequences account for approximately 40% of the human Y-chromosome, are interspersed within the same 3.4 kb Hae III fragments, are heterogeneous and contain all reiterated DNA previously demonstrated to be specific for the Y-chromosome (it-Y DNA). Y-specific 3.4 kb Hae III sequences do not reassociate with either human female or ape DNA at standard reassociation criteria. However, approximately half of it-Y DNA (cross reacting it-Y) reassociates with both human female and ape DNA at reduced reassociation criteria. The remaining half (Y-specific it-Y) retains its specificity for the human Y-chromosome. These two sets of it-Y DNA have distinct reiteration frequencies and thermal stabilities with their Y-chromosome homologs. Non-Y-specific 3.4 kb Hae III sequences reassociate with both human female and ape DNA at standard reassociation criteria. The abundance of these non-Y-specific sequences decreases as a function of their evolutionary distance from man. One subset of non-Y-specific 3.4 kb Hae III sequences forms stable duplexes with human Y-chromosome DNA and with human and ape autosomal DNA. No detectable base-mismatch occurs among these homologs suggesting complete conservation of these sequences during primate evolution. The second subset of Non-Y-specific Hae III sequences form stable duplexes with human Y-chromosome DNA but highly mismatched duplexes with human and ape autosomal DNA.The finding that homologs of 3.4 kb Hae III sequences are not found within the Y-chromosome of apes but are only present in autosomes suggests that 3.4 kb Hae III sequences are largely autosomal in origin. Since autosomal homologs of most 3.4 kb Hae III-sequences exhibit a greater degree of divergence than those localized to the Y-chromosome, their evolutionary history seems to be chromosome-dependent.Our findings are not easily correlated with the comparative morphology of primate Y-chromosomes and suggest that sequence rearrangement has been a major event in the evolution of the human Y-chromosome. The significance of the specific interspersion of four sets of reiterated sequences, with distinct evolutionary histories, within a repeating unit specific to the human Y-chromosome is not clear. The apparent conservation of at least some of these reiterated sequences suggests they may be of functional importance.     

Reduced Y-chromosome,but not mitochondrial DNA,diversity in human populations from West New Guinea

To investigate the paternal population history of New Guinea, 183 individuals from 11 regional populations of West New Guinea (WNG) and 131 individuals from Papua New Guinea (PNG) were analyzed at 26 binary markers and seven short-tandem-repeat loci from the nonrecombining part of the human Y chromosome and were compared with 14 populations of eastern and southeastern Asia, Polynesia, and Australia. Y-chromosomal diversity was low in WNG compared with PNG and with most other populations from Asia/Oceania; a single haplogroup (M-M4) accounts for 75% of WNG Y chromosomes, and many WNG populations have just one Y haplogroup. Four Y-chromosomal lineages (haplogroups M-M4, C-M208, C-M38, and K-M230) account for 94% of WNG Y chromosomes and 78% of all Melanesian Y chromosomes and were identified to have most likely arisen in Melanesia. Haplogroup C-M208, which in WNG is restricted to the Dani and Lani, two linguistically closely related populations from the central and western highlands of WNG, was identified as the major Polynesian Y-chromosome lineage. A network analysis of associated Y-chromosomal short-tandem-repeat haplotypes suggests two distinct population expansions involving C-M208--one in New Guinea and one in Polynesia. The observed low levels of Y-chromosome diversity in WNG contrast with high levels of mtDNA diversity reported for the same populations. This most likely reflects extreme patrilocality and/or biased male reproductive success (polygyny). Our data further provide evidence for primarily female-mediated gene flow within the highlands of New Guinea but primarily male-mediated gene flow between highland and lowland/coastal regions.     

Phylogeography of mitochondrial DNA and Y-chromosome haplogroups reveal asymmetric gene flow in populations of Eastern India

Polymorphisms in mitochondrial (mt) DNA and Y-chromosomes of seven socially and linguistically diverse castes and tribes of Eastern India were examined to determine their genetic relationships, their origin, and the influence of demographic factors on population structure. Samples from the Orissa Brahmin, Karan, Khandayat, Gope, Juang, Saora, and Paroja were analyzed for mtDNA hypervariable sequence (HVS) I and II, eight Y-chromosome short tandem repeats (Y-STRs), and lineage-defining mutations diagnostic for Indian- and Eurasian-specific haplogroups. Our results reveal that haplotype diversity and mean pairwise differences (MPD) was higher in caste groups of the region (>0.998, for both systems) compared to tribes (0.917-0.996 for Y-STRs, and 0.958-0.988 for mtDNA haplotypes). The majority of paternal lineages belong to the R1a1, O2a, and H haplogroups (62.7%), while 73.2% of maternal lineages comprise the Indian-specific M*, M5, M30, and R* mtDNA haplogroups, with a sporadic occurrence of West Eurasian lineages. Our study reveals that Orissa Brahmins (a higher caste population) have a genetic affinity with Indo-European speakers of Eastern Europe, although the Y-chromosome data show that the genetic distances of populations are not correlated to their position in the caste hierarchy. The high frequency of the O2a haplogroup and absence of East Asian-specific mtDNA lineages in the Juang and Saora suggest that a migration of Austro-Asiatic tribes to mainland India was exclusively male-mediated which occurred during the demographic expansion of Neolithic farmers in southern China. The phylogeographic analysis of mtDNA and Y-chromosomes revealed varied ancestral sources for the diverse genetic components of the populations of Eastern India.