Carolina Núñez

Continent-Wide Decoupling of Y-Chromosomal Genetic Variation from Language and Geography in Native South Americans

Numerous studies of human populations in Europe and Asia have revealed a concordance between their extant genetic structure and the prevailing regional pattern of geography and language. For native South Americans, however, such evidence has been lacking so far. Therefore, we examined the relationship between Y-chromosomal genotype on the one hand, and male geographic origin and linguistic affiliation on the other, in the largest study of South American natives to date in terms of sampled individuals and populations. A total of 1,011 individuals, representing 50 tribal populations from 81 settlements, were genotyped for up to 17 short tandem repeat (STR) markers and 16 single nucleotide polymorphisms (Y-SNPs), the latter resolving phylogenetic lineages Q and C. Virtually no structure became apparent for the extant Y-chromosomal genetic variation of South American males that could sensibly be related to their inter-tribal geographic and linguistic relationships. This continent-wide decoupling is consistent with a rapid peopling of the continent followed by long periods of isolation in small groups. Furthermore, for the first time, we identified a distinct geographical cluster of Y-SNP lineages C-M217 (C3*) in South America. Such haplotypes are virtually absent from North and Central America, but occur at high frequency in Asia. Together with the locally confined Y-STR autocorrelation observed in our study as a whole, the available data therefore suggest a late introduction of C3* into South America no more than 6,000 years ago, perhaps via coastal or trans-Pacific routes. Extensive simulations revealed that the observed lack of haplogroup C3* among extant North and Central American natives is only compatible with low levels of migration between the ancestor populations of C3* carriers and non-carriers. In summary, our data highlight the fact that a pronounced correlation between genetic and geographic/cultural structure can only be expected under very specific conditions, most of which are likely not to have been met by the ancestors of native South Americans.

Reconstructing the population history of Nicaragua by means of mtDNA, Y‐chromosome STRs, and autosomal STR markers

Before the arrival of the Spaniards in Nicaragua, diverse Native American groups inhabited the territory. In colonial times, Native Nicaraguan populations interacted with Europeans and slaves from Africa. To ascertain the extent of this genetic admixture and provide genetic evidence about the origin of the Nicaraguan ancestors, we analyzed the mitochondrial control region (HVSI and HVSII), 17 Y chromosome STRs, and 15 autosomal STRs in 165 Mestizo individuals from Nicaragua. To carry out interpopulation comparisons, HVSI sequences from 29 American populations were compiled from the literature. The results reveal a close relationship between Oto-manguean, Uto-Aztecan, Mayan groups from Mexico, and a Chibchan group to Nicaraguan lineages. The Native American contribution to present-day Nicaraguan Mestizos accounts for most of the maternal lineages, whereas the majority of Nicaraguan Y chromosome haplogroups can be traced back to a West Eurasian origin. Pairwise Fst distances based on Y-STRs between Nicaragua and European, African and Native American populations show that Nicaragua is much closer to Europeans than the other populations. Additionally, admixture proportions based on autosomal STRs indicate a predominantly Spanish contribution. Our study reveals that the Nicaraguan Mestizo population harbors a high proportion of European male and Native American female substrate. Finally, the amount of African ancestry is also interesting, probably because of the contribution of Spanish conquerors with North African genetic traces or that of West African slaves.

Association between ancient bone preservation and dna yield: A multidisciplinary approach

Ancient molecular typing depends on DNA survival in archaeological bones. Finding valuable tools to predict DNA presence in ancient samples, which can be measured prior to undertaking a genetic study, has become an important issue as a consequence of the peculiarities of archaeological samples. Since the survival of DNA is explained by complex interrelations of multiple variables, the aim of the present study was to analyze morphological, structural, chemical, and biological aspects of a set of medieval human bones, to provide an accurate reflection of the state of preservation of the bony components and to relate it with DNA presence. Archaeological bones that yielded amplifiable DNA presented high collagen content (generally more than 12%), low racemization values of aspartic acid (lesser than 0.08), leucine and glutamic acid, low infrared splitting factor, small size of crystallite, and more compact appearance of bone in the scanning electron micrographs. Whether these patterns are characteristic of ancient bones or specific of each burial site or specimen requires further investigation.

Y chromosome haplogroup diversity in a Mestizo population of Nicaragua

Y chromosome single nucleotide polymorphisms (Y-SNPs) are indispensable markers for haplogroup determination. Since Y chromosome haplogroups show a high specific geographical distribution, they play a major role in population genetics but can also benefit forensic investigations. Although haplogroup prediction methods based on Y chromosome short tandem repeats (Y-STRs) exist and are frequently used, precaution is required in this regard. In this study we determine the Y chromosome haplogroups of a Nicaraguan population using several Y-SNP multiplex reactions. Y chromosome haplogroups have been predicted before, but our results show that a confirmation with Y-SNP typings is necessary. These results have revealed a 4.8% of error in haplogroup prediction based on Y-STR haplotypes using Atheys Haplogroup Predictor. The Nicaraguan Mestizo population displays a majority of Eurasian lineages, mainly represented by haplogroup R-M207 (46.7%). Other Eurasian lineages have been observed, especially J-P209 (13.3%), followed by I-M170 (3.6%) and G-M201 (1.8%). Haplogroup E-P170 was also observed in 15.2% of the sample, particularly subhaplogroup E1b1b1-M35. Finally, the Native American haplogroup Q-M242 was found in 15.2% of the sample, with Q1a3a-M3 being the most frequent.

Highly discriminatory capacity of the PowerPlex(®) Y23 System for the study of isolated populations.

In order to evaluate the forensic utility of the new PowerPlex(®) Y23 System, two Northern Spanish populations, the autochthonous Basque Country (N=105) and Cantabria (N=98), were typed. Two of the new markers incorporated in the panel, the rapid mutating loci DYS576 and DYS570, were among the most discriminative markers in both population datasets. In terms of the analysis of 23 Y-STRs, the two populations showed high haplotype diversities, with values slightly superior in the population of Cantabria (1±0.0015) than in the Basque Country (0.9987±0.0016). The comparison of the discrimination capacity obtained with the analysis of 23 Y-STRs and other available markers sets of 12 Y-STRs (PowerPlex(®) Y System) or 17 Y-STRs (YFiler™), clearly demonstrated an improvement in the population of the Basque Country. Nevertheless, in Cantabria this augment was only seen when the number of markers was increased from 12 to 23, since the study of 17 Y-STRs was enough to differentiate all haplotypes. Therefore, this study shows that the improvement in forensic parameters by increasing the number of Y-STR markers analyzed is much more pronounced in the case of isolated populations such as the autochthonous population of the Basque Country, as it facilitates the differentiation among similar haplotypes. Moreover, by the use of the PowerPlex(®) Y23 identification of population specific haplotypes increased in both populations. Ultimately, the analysis of 23 Y-STRs differentiated among the two geographically close populations of Basque Country and Cantabria. Indeed it showed significant differences between the Basque Country population and all European populations included, meanwhile Cantabria did exhibit significant proximity with the Iberian and the majority of European populations considered.

Mitochondrial diversity in Amerindian Kichwa and Mestizo populations from Ecuador

This study presents mitochondrial DNA (mtDNA) data from 107 unrelated individuals from two of the major ethnic groups in Ecuador: Amerindian Kichwas (n = 65) and Mestizos (n = 42). We characterized the diversity of the matrilineal lineages of these Ecuadorian groups by analyzing the entire mtDNA control region. Different patterns of diversity were observed in the two groups as result of the unique historical and demographic events which have occurred in each population. Higher genetic diversity values were obtained for the Mestizo group than for the Amerindian group. Interestingly, only Native American lineages were detected in the two population samples, but with differences in the haplogroup distribution: Kichwa (A, 49%; B, 3%; C, 8%; and D, 40%) and Mestizo (A, 33%; B, 33%; C, 10%; and D, 24%). Analysis of the complete mtDNA control region proved to be useful to increase the discrimination power between individuals who showed common haplotypes in HVSI and HVSII segments; and added valuable information to the phylogenetic interpretation of mtDNA haplotypes.

Nuclear DNA typing from ancient teeth.

AbstractBecause of the adverse effects that diagenesis exert on ancient skeletal remains, DNA from these samples is often compromised to the point where genetic typing can be challenging. Nevertheless, robust and reliable methods are currently available to allow successful genotyping of ancient specimens. Here we report nuclear DNA–based methods and typing strategies used to analyze 2 human skeletons from a medieval burial. Reliable DNA nuclear profiles were obtained from teeth, whereas mitochondrial DNA analyses in bones were inconclusive. A complete nuclear mini short tandem repeat profile was obtained from a well-preserved premolar, but only a partial one from the femur. Increasing the sensitivity of the polymerase chain reaction system allowed a full profile from the latter, but the presence of artifacts reinforced the idea that the interpretation of this kind of analysis must be performed with caution. The results presented here also indicate that DNA from dental pieces can be better preserved than from bones, even in the case of well-preserved long bones with thick cortical tissue such as the femurs, and have a better chance of successful genetic typing, probably because of the high degree of protection conferred to the DNA by the enamel.

Development of a new highly efficient 17 X‐STR multiplex for forensic purposes

Currently, two of the most widely used X‐chromosome STR (X‐STR) multiplexes are composed by ten (GHEP‐ISFG decaplex) and 12 markers (Investigator Argus X‐12 Kit). The number of markers included is a drawback for complex relative testing cases, likewise the large size of some amplicons difficult their application to degraded samples. Here, we present a new multiplex of 17 X‐STRs with the aim of increasing both the resolution power and forensic applicability. This newly proposed set includes the X‐STRs of the GHEP‐ISFG decaplex, four X‐STRs from the Investigator Argus X‐12 Kit, three of them also included in the decaplex, and six additional more. In order to ensure the allele designation, an allelic ladder was developed. The validation of the present multiplex was carried out according to the revised guidelines by the SWGDAM (Scientific Working Group on DNA Analysis Methods). A total of 488 unrelated individuals from four different continents were analyzed. The forensic efficiency evaluation showed high values of combined power of discrimination in males (≥0.999999996) and females (≥0.999999999999995) as well as combined paternity exclusion probabilities in trios (≥0.99999998) and duos (≥0.999996). The results presented herein have demonstrated that the new 17 X‐STR set constitutes a high‐resolution alternative to the current X‐STR multiplexes.

Identification of new SNPs in native South American populations by resequencing the Y chromosome

The Y-chromosomal genetic landscape of South America is relatively homogenous. The majority of native Amerindian people are assigned to haplogroup Q and only a small percentage belongs to haplogroup C. With the aim of further differentiating the major Q lineages and thus obtaining new insights into the population history of South America, two individuals, both belonging to the sub-haplogroup Q-M3, were analyzed with next-generation sequencing. Several new candidate SNPs were evaluated and four were confirmed to be new, haplogroup Q-specific, and variable. One of the new SNPs, named MG2, identifies a new sub-haplogroup downstream of Q-M3; the other three (MG11, MG13, MG15) are upstream of Q-M3 but downstream of M242, and describe branches at the same phylogenetic positions as previously known SNPs in the samples tested. These four SNPs were typed in 100 individuals belonging to haplogroup Q.

Genetic analysis of 7 medieval skeletons from the Aragonese Pyrenees.

Aim To perform a genetic characterization of 7 skeletons from medieval age found in a burial site in the Aragonese Pyrenees. Methods Allele frequencies of autosomal short tandem repeats (STR) loci were determined by 3 different STR systems. Mitochondrial DNA (mtDNA) and Y-chromosome haplogroups were determined by sequencing of the hypervariable segment 1 of mtDNA and typing of phylogenetic Y chromosome single nucleotide polymorphisms (Y-SNP) markers, respectively. Possible familial relationships were also investigated. Results Complete or partial STR profiles were obtained in 3 of the 7 samples. Mitochondrial DNA haplogroup was determined in 6 samples, with 5 of them corresponding to the haplogroup H and 1 to the haplogroup U5a. Y-chromosome haplogroup was determined in 2 samples, corresponding to the haplogroup R. In one of them, the sub-branch R1b1b2 was determined. mtDNA sequences indicated that some of the individuals could be maternally related, while STR profiles indicated no direct family relationships. Conclusions Despite the antiquity of the samples and great difficulty that genetic analyses entail, the combined use of autosomal STR markers, Y-chromosome informative SNPs, and mtDNA sequences allowed us to genotype a group of skeletons from the medieval age.