Isolation of chromosomal regions controlling intersex development in a marsupial.

A marsupial (Sminthopsis douglasi) with bilateral intersexuality had a hemiscrotum on the right side and a hemi-pouch with nipples on the left. A normal female karyotype (2n = 14, XX) was present in cells from the right (male) side, while cells from the left (female) side initially had a female karyotype plus two dot-like chromosomes (2n = 14, XX + 2B). It is proposed that the dots represented a region deleted from the X chromosome that contains the "pouch-mammary/scrotum" (PMS) switch gene whose dosage determines development of a pouch and teats (two doses) or a scrotum (one dose). Mis-segregation early in embryonic development produced a lineage with one normal X and one deleted X (male side), and a lineage with a normal and deleted X, plus two copies of the deleted region (female side). The origin of the supernumerary elements was therefore investigated in the expectation that they may contain the long-sought pouch-mammary/scrotum switch gene. Several elements were microdissected, and amplified DNA was used for in situ hybridization, producing signals in five different chromosome regions including the X. This could represent a region of the X that contains, as well as PMS, repetitive DNA that is present also at other chromosomal sites.

Genetic differentiation in South Amerindians is related to environmental and cultural diversity: evidence from the Y chromosome.

The geographic structure of Y-chromosome variability has been analyzed in native populations of South America, through use of the high-frequency Native American haplogroup defined by the DYS199-T allele and six Y-chromosome-linked microsatellites (DYS19, DYS389A, DYS389B, DYS390, DYS391, and DYS393), analyzed in 236 individuals. The following pattern of within- and among-population variability emerges from the analysis of microsatellite data: (1) the Andean populations exhibit significantly higher levels of within-population variability than do the eastern populations of South America; (2) the spatial-autocorrelation analysis suggests a significant geographic structure of Y-chromosome genetic variability in South America, although a typical evolutionary pattern could not be categorically identified; and (3) genetic-distance analyses and the analysis of molecular variance suggest greater homogeneity between Andean populations than between non-Andean ones. On the basis of these results, we propose a model for the evolution of the male lineages of South Amerindians that involves differential patterns of genetic drift and gene flow. In the western part of the continent, which is associated with the Andean area, populations have relatively large effective sizes and gene-flow levels among them, which has created a trend toward homogenization of the gene pool. On the other hand, eastern populations-settled in the Amazonian region, the central Brazilian plateau, and the Chaco region-have exhibited higher rates of genetic drift and lower levels of gene flow, with a resulting trend toward genetic differentiation. This model is consistent with the linguistic and cultural diversity of South Amerindians, the environmental heterogeneity of the continent, and the available paleoecological data.

The phylogeography of Brazilian Y-chromosome lineages.

We examined DNA polymorphisms in the nonrecombining portion of the Y-chromosome to investigate the contribution of distinct patrilineages to the present-day white Brazilian population. Twelve unique-event polymorphisms were typed in 200 unrelated males from four geographical regions of Brazil and in 93 Portuguese males. In our Brazilian sample, the vast majority of Y-chromosomes proved to be of European origin. Indeed, there were no significant differences when the haplogroup frequencies in Brazil and Portugal were compared by means of an exact test of population differentiation. Y-chromosome typing was quite sensitive in the detection of regional immigration events. Distinct footprints of Italian immigration to southern Brazil, migration of Moroccan Jews to the Amazon region, and possible relics of the 17th-century Dutch invasion of northeast Brazil could be seen in the data. In sharp contrast with our mtDNA data in white Brazilians, which showed that > or =60% of the matrilineages were Amerindian or African, only 2.5% of the Y-chromosome lineages were from sub-Saharan Africa, and none were Amerindian. Together, these results configure a picture of strong directional mating between European males and Amerindian and African females, which agrees with the known history of the peopling of Brazil since 1500.

Molecular characterization and population study of an X chromosome homolog of the Y-linked microsatellite DYS391.

A novel microsatellite homologous to DYS391, a (GATA)(n) short tandem repeat on the human Y chromosome, was identified and characterized in the present work. Employing somatic cell hybrid and deletion panels in a PCR-based approach, we found out that the new microsatellite is located in Xp21.2-22.3, while its Y counterpart mapped to Yq11.21. This X-linked locus (provisionally called DXYS391) and its Y homolog constitute one more example of similarity outside the pseudoautosomal regions between the two human sex chromosomes. Sequencing data showed high levels of homology in the flanking regions of DXYS391 and DYS391 that differ primarily by the presence of a (GACA)(3) motif in the Y locus. Both loci were detected in chimpanzee DNA, suggesting that a putative transposition from the X to the Y occurred before the human/chimpanzee split. The allele frequencies of DYS391 and DXYS391 were investigated, respectively, in 271 Y and 337 X chromosomes from distinct human populations worldwide. DYS391 consistently displayed greater among-population component of the variance of the allele frequencies than DXYS391, as expected due to the three-times lower effective population size of Y chromosomes relative to the X. The intra-population diversity of DYS391, measured by Nei's locus diversity as well as by allele size variance, was lowest in Amerindians, while very low diversity of DXYS391 was seen in Africans. Since our African data are based on a small sample, further studies will be necessary to evaluate better this observation.

Divergent human Y-chromosome microsatellite evolution rates.

In this work, we analyze several characteristics influencing the low variability of the microsatellite DYS19 in the major founder Amerindian Y chromosome lineage containing the point mutation DYS199-T. Variation of DYS19 was compared with that of five other Y-linked tetranucleotide repeat loci (DYS389A, DYS389B, DYS390, DYS391, and DYS393) in the DYS199-T lineage. All the other microsatellites showed significantly higher levels of variability than DYS19 as measured by gene diversity and repeat number variance. Moreover, we had previously shown that DYS19 had high diversity in Brazilians and in several other populations worldwide. Thus, the slow DYS19 evolution in the DYS199-T lineage seems to be both locus and allele specific. To understand the slow DYS19 evolutionary rate, the microsatellite loci were compared according to their mapping on the Y chromosome and also on the basis of structural aspects such as the base composition of the repeat motif and flanking regions and the degree of perfection and size (repeat number) of the variable blocks. The only observed difference that might be related to the low DYS19 variability is its small average number of repeats, a value expected to be closer to the founder DYS19 allele in the DYS199-T lineage. These data were also compared to other derived Y lineages. The Tat-C lineage displayed a lower DYS19 variability correlated to a small average repeat number, while in the DYS234-G lineage, a high DYS19 variability was found associated to a larger average repeat number. This approach reveals that evolution of Y microsatellites in lineages defined by slowly evolving markers, such as point mutations, can be greatly influenced by the size (number of repeats of the variable block) of the founder allele in each microsatellite locus. Thus lineage-dating methods using microsatellite variation should be practiced with great care.