Un método molecular rápido, no invasivo y simple para determinar el sexo en pingüinos pigoscélidos / A rapid, non invasive and simple molecular method for sex determination in pygoscelis penguins

En los pingüinos Adélie (Pygoscelis adeliae) y pingüinos gentoo (Pygoscelis papua), no existe un dimorfismo sexual conspicuo y a menudo resulta difícil determinar el sexo en base a la morfología externa. La información sobre el sexo es importante en muchos estudios de ecología y conservación. En este artículo se evaluó el uso de un par de cebadores (2550F/2718R) para identificar el sexo en aves sexualmente monomórficas. Para ambas especies de pingüinos la amplificación produjo dos bandas discretas, CHD1Z y CHD1W, que permitieron la identificación sexual. Se trata de un sistema sencillo, rápido y económico para el sexaje molecular de los pingüinos gentoo y Adélie.

In Adélie penguins (Pygoscelis adeliae) and gentoo penguins (Pygoscelis papua), the conspicuous sexual dimorphism often makes it difficult to determine sex on the basis of external morphology. The information about sex is important in many ecology and conservation studies. In this paper we evaluated the use of an established primer pair (2550F/2718R) to identify sex in sexually monomorphic birds. In both penguin species, it resulted in two distinct CHD1Z and CHD1W PCR bands, allowing sex identification. This is a simple, rapid and cheap system for molecular sexing of gentoo and Adélie penguins.

Genealogical surveys show a high rate of non-paternal surname transmission with regional differences in Argentina.

Surnames are a vertically transmitted cultural trait that in Argentina follows the paternal line of descent when the paternity is known. There was a lack of empirical information regarding non-paternal surname transmissions among the general population, so we performed 2,550 genealogical interviews, which included 6,954 surname passes, in different regions of this country. We compared the proportion of non-paternal transmissions between the propositus and parental generation and found no significant difference between them (p<0.01). Inter-population comparisons allowed us to describe 4 regional groups. We also drew models and simulations to estimate how many generations it would take to find that only half of the population maintained the paternal transmission. The lowest proportion of non-paternal transmission was 7.3%, estimating 9 generations (between 225 and 315 years) to find that, at most, half its population keeps following the paternal transmission; the highest proportion was 23%, taking 3 generations (75-105 years). Our results show a high proportion of unrecognized paternities among the general population, a very quick loss of association between male lineages and surnames, and regional proportions with significant differences between each other.

Technical note: A method for assignment of the weight of characters.

The weight of characters is a crucial step in different population analyses. We propose a new formula to facilitate this while establishing a scale that follows the criteria of the probability of change in each character. This method is described for drawing of median-joining networks, yet it could also be used for other methods in which the weight of the characters is required.

Allele and genotype frequencies of metabolic genes in Native Americans from Argentina and Paraguay.

Interethnic differences in the allele frequencies of CYP2D6, NAT2, GSTM1 and GSTT1 deletions have been documented for Caucasians, Asians, and Africans population. On the other hand, data on Amerindians are scanty and limited to a few populations from southern areas of South America. In this report we analyze the frequencies of 11 allele variants of CYP2D6 and 4 allele variants of NAT2 genes, and the frequency of GSTM1 and GSTT1 homozygous deleted genotypes in a sample of 90 donors representing 8 Native American populations from Argentina and Paraguay, identified as Amerindians on the basis of their geographic location, genealogical data, mitochondrial- and Y-chromosome DNA markers. For CYP2D6, 88.6% of the total allele frequency corresponded to *1, *2, *4 and *10 variants. Average frequencies for NAT2 *4, *5, *6 and *7 alleles were 51.2%, 25%, 6.1%, and 20.1%, respectively. GSTM1 deletion ranged from 20% to 66%, while GSTT1 deletion was present in four populations in less than 50%. We assume that CYP2D6 *2, *4, *10, *14; NAT2 *5, *7 alleles and GSTM1 and GSTT1 *0/*0 genotypes are founder variants brought to America by the first Asian settlers.

Correlation between molecular and conventional genealogies in Aicuña: a rural population from Northwestern Argentina.

Aicuña is a village in the northwest of Argentina, located about 300 km south of La Rioja city, in the province of La Rioja. The population of Aicuña derives from a founder couple established in the uninhabited Aicuña valley in the early years of the 17th century. Due to land ownership litigation, the descendants maintained a well-documented genealogy that extends for 12 generations, comprising more than 8,000 individuals. From the historical pedigree of Aicuña, we selected 14 males with direct patrilineal descent from the 2 most ancient male founders, and 23 donors (9 females and 14 males) with direct matrilineal descent from the most ancient female founder. All 3 founders lived in the 17th century. We collected DNA from buccal swabs and characterized the mitochondrial DNA (mtDNA) and Y haplotypes using 14 Y-specific markers, 11 mtDNA polymorphic markers and sequencing of the mt hypervariable regions 1 and 2. We found four different Y haplotypes: Y1 and Y2 haplotypes of European origin corresponding to the founder ancestors Francisco Páez de Espinoza and Apolinario Ormeño, which were shared by 6 and 3 donors, respectively. Three males selected as Ormeño patrilineal descendants showed a different Y haplotype (Y3), probably originated by erroneous paternity registration due to illegitimacy. The remaining case (haplotype Y4), also assumed to belong to the Ormeño lineage, was probably also due to an erroneously registered paternity. Twenty-two donors showed an association of mtDNA markers corresponding to the Amerindian haplotype A2. The founder of this matrilineage could be traced back for more than 14 generations. The haplotype B of one remaining female did not correspond with the historical pedigree and could be due to an error in the genealogy registration. Our results showed an 85% agreement between conventional and molecular genealogies, with mtDNA markers being Amerindian, and Y markers being European. The methodology used in this report is a tool which could potentially be employed as a precedent for land ownership by Aicuña villagers and Amerindian populations.

Nuclear and mitochondrial genome instability in human breast cancer.

We analyzed 40 pairs of breast normal/cancer tissues for the presence of mitochondrial (mt) genome instability and nuclear MSI in tumor cells. As mt, markers we used a (CA)n mt microsatellite (MS) starting at the 514-bp position of the D loop region and 4 informative MnlI sites located between the 16,108- and 16,420-bp positions of the D loop region. Nuclear microsatallite instability (MSI) was tested with 8 (CA)n MS, syntenic for the 13q chromosome arm. Moreover, we tested the spontaneous frequency of mtMSI and mt-MnlI mutations in 459 mother/descendant events. Mutations of mt-MnlI sites were found in 19 of 40 (47.5%) breast tumors, representing a 216-fold increase over the spontaneous rate in the female germline. Instability of the mtMS occurred in 17 of 40 (42.5%) breast cancers, which implies a 16-fold increase over the rate of spontaneous mutations. Nuclear MSI was found in 20 of 40 (50%) cases. In 15 of these cases the MSI was restricted to one locus, whereas in 5 instances the change of alleles was detected in 2 or 3 loci. Analysis of the correlation between mt and nuclear mutations showed no significant associations, suggesting that different systems are responsible for mt and nuclear genome instability in tumor cells. We propose that the two main mechanisms producing mtRFLP and mtMSI are damage by free radicals and error repair by the polymerase gamma, the first mechanism being a major cause of MnlI mutations and a secondary cause of mtMSI.

Origin of YAP+ lineages of the human Y-chromosome.

We screened a total of 841 Y-chromosomes representing 36 human populations of wide geographical distribution for the presence of a Y-specific Alu insert (YAP+ chromosomes). The Alu element was found in 77 cases. We tested 5 biallelic and 8 polyallelic markers in 70 out of the 77 YAP+ chromosomes. We could identify the existence of a hierarchical and chronological structuring of ancestral and derived YAP+ lineages, giving rise to 4 haplogroups, 14 subhaplogroups and 60 haplotypes. Moreover, we propose a monophyletic origin for each one of the YAP+ lineages. Out-of-Africa and out-of-Asia models have been suggested to explain the origin and evolution of ancestral and derived YAP+ elements. We analyze the evidence supporting these two hypotheses, and we conclude that the information available does not allow one to decide between the out-of-Asia or out-of-Africa models.

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.

Paternal directional mating in two Amerindian subpopulations located at different altitudes in northwestern Argentina.

We used mitochondrial DNA (mtDNA) and Y-chromosome DNA polymorphisms to analyze the ethnic origin of maternal and paternal lineages in two Amerindian subpopulations from northwestern Argentina. One of the subpopulations was from San Salvador de Jujuy, located 1200 m above sea level. The second subpopulation inhabits the Quebrada de Humahuaca area at altitudes ranging from 2500 to 3500 m. Both subpopulations have the same ethnic background. All mtDNA haplotypes were identified as Amerindian with a frequency of 64.6% of the B form (9-bp deletion in mtDNA region V). Because all Central Andean Amerindian populations studied so far exhibit high frequencies of the B haplotype, we propose that they probably are derived from a common ancestral population that inhabited the Central Andes 6000-8000 years B.P. The presence of paternal directional mating (asymmetric contribution of one parental lineage to interethnic gene mixtures) was demonstrated by the finding of an average introgression of 40.5% Spanish Y chromosomes into our Amerindian sample. This introgression was more evident at low altitude than at high altitude, with frequencies of 64.3% in San Salvador de Jujuy (low altitude) and 27.6% in Quebrada de Humahuaca (high altitude) (p < 0.05). The San Salvador de Jujuy subpopulation also showed a significantly higher Y-chromosome gene variability than the Quebrada de Humahuaca subpopulation. These findings are in good agreement with historical reports indicating that the colonization of South America was undertaken by men who usually practiced polygamous unions with Amerindian women and that San Salvador de Jujuy was the main northwestern Argentinian region of European to Amerindian gene admixture. We found 16.7% of cases with Spanish Y chromosomes and Amerindian family names, and the same percentage with Amerindian Y chromosomes and Hispanic names. The former group probably is the result of unions between Hispanic men, who transmitted the Y chromosome, and Amerindian women, who transmitted the family name to the progeny. The latter group likely illustrates the practice of changing names from Amerindian to Hispanic during the baptism of native Americans in colonial times.

Characterization of mitochondrial DNA and Y-chromosome haplotypes in a Uruguayan population of African ancestry.

We used a set of informative mtDNA and Y-chromosome-specific markers to determine the origin of maternal and paternal lineages in a sample of 41 Uruguayan black individuals. We found that 20 maternal lineages were African, 13 were Amerindian, and 5 were Caucasian. In three individuals we were unable to determine the ethnic origin of the mtDNA lineages. Of the 22 males analyzed we found 4 Y chromosomes of African origin, 5 of Caucasian origin, and 13 of undetermined ancestry. Our results suggest that mtDNA and Y-chromosome-specific DNA variants may be a useful tool in determining the level of mtDNA and Y chromosome ethnic introgression in a population of a given ethnic origin.

Origin of Amerindian Y-chromosomes as inferred by the analysis of six polymorphic markers.

We analysed the frequency of six Y-specific polymorphisms in 105 Amerindian males from seven different populations, 42 Caucasian males, and a small number of males of African, Chinese, and Melanesian origin. The combination of three of the six polymorphisms studied produced four different Y-haplogroups. The haplogroups A (non-variant) was the most frequent one. Eighty-five percent of Amerindians showing haplogroup A have the alphoid II (alpha hII) and the DYS19A Y-specific markers, an association that is found only in 10% of Caucasians and that has not been detected in Asiatics and Africans. Haplogroups C (YAP+) and D (YAP+ plus an A-->G transmission in the locus DYS271) are of African origin. Four percent of Amerindians and approximately 12% of Caucasians showed haplogroup C; approximately 1% of Amerindians and approximately 2% of Caucasians had haplogroup D. Haplogroup B is characterized by a C-->T transition in nucleotide position 373 of the SRY gene domain; this haplogroup is found in Caucasians (approximately 12%) and Amerindians (approximately 4%). None of the Amerindians exhibiting the haplogroups B, C, or D show the haplotype alpha hII/DYS19A. By haplotyping the the Alu insert and the DNA region surrounding the insert in YAP+ individuals, we could demonstrate that Amerindian Y chromosomes bearing African markers (haplogroups C and D) are due to recent genetic admixture. Most non-alpha hII/DYS19A Amerindian Y-chromosomes in haplogroup A and most cases in haplogroup B are also due to gene flow. We show that haplotype alpha hII/DYS19A is in linkage disequilibrium with a C-->T transition in the locus DYS19A. Our results suggest that most Amerindian Y-chromosomes derive from a single paternal lineage characterized by the alpha hII/DYS19A/DYS199T Amerindian-specific haplotype. The analysis of a larger sample of native American Y-chromosome will be required in order to confirm or correct this hypothesis.

Mitochondrial DNA mutations in normal and tumor tissues from breast cancer patients.

We have characterized the mtDNA in normal and breast cancer tissues from seven patients. Both types of tissue showed point mutation heteroplasmies and extensive deletions of the mtDNA. The analysis of these polymorphisms allowed us to infer the mtDNA composition of the breast cell that underwent malignant transformation.

Founder mitochondrial haplotypes in Amerindian populations.

It had been proposed that the colonization of the New World took place by three successive migrations from northeastern Asia. The first one gave rise to Amerindians (Paleo-Indians), the second and third ones to Nadene and Aleut-Eskimo, respectively. Variation in mtDNA has been used to infer the demographic structure of the Amerindian ancestors. The study of RFLP all along the mtDNA and the analysis of nucleotide substitutions in the D-loop region of the mitochondrial genome apparently indicate that most or all full-blooded Amerindians cluster in one of four different mitochondrial haplotypes that are considered to represent the founder maternal lineages of Paleo-Indians. We have studied the mtDNA diversity in 109 Amerindians belonging to 3 different tribes, and we have reanalyzed the published data on 482 individuals from 18 other tribes. Our study confirms the existence of four major Amerindian haplotypes. However, we also found evidence supporting the existence of several other potential founder haplotypes or haplotype subsets in addition to the four ancestral lineages reported. Confirmation of a relatively high number of founder haplotypes would indicate that early migration into America was not accompanied by a severe genetic bottleneck.

Characterization and sequencing of the sex determining region Y gene (Sry) in Akodon (Cricetidae) species with sex reversed females.

The sex determining region Y gene (Sry) is the strongest candidate to be the testis determining factor gene (Tdy). Several South-American Akodon species have two varieties of Y chromosome. One type transmitted via male specimens induces testis development. The second Y variety fails to induce male gonadal differentiation and gives rise to fully fertile XY females. These variant females test positive for Sry. Moreover, sequencing of a partial open reading frame of the conserved region of Sry from males and XY females shows no sequence difference. Sry is two- to sixfold amplified in six of eight akodont species tested. Since Sry amplification was found in species having and not having XY females, amplification apparently does not in itself play a primary role in the origin of sex reversal. The development of fully fertile ovaries in XY Akodon females is not due to a deletion of Sry or to mutations in the Sry segment analyzed in this report. Sex reversal may be due to abnormal expression of this gene at the stage of gonadal differentiation. Alternatively, other genes in the sex-determining pathway may be involved. Several of the Akodon species showing Sry amplification also have amplification of Zfy, which may map to the same region of the Akodon Y chromosome.