Micropogonias furnieri is widely distributed in the southwestern Atlantic Ocean. In Uruguay, Laguna de Rocha and Río de La Plata estuary have been reported as reproductive and nursery areas. In Laguna de Rocha, individuals reach maturity at smaller total length than their oceanic counterparts. It has been difficult to establish whether Laguna de Rocha represents a biologically distinct population or simply ecophenotypic variation. More generally, the possible presence of several distinct populations of white croakers in Uruguayan waters has been hypothesized, but limited data exist to substantiate them. A recent mitochondrial DNA analysis suggested divergence between the Río de La Plata and the Oceanic front populations. Using seven microsatellites loci, we studied the population structure of M. furnieri in the nursery areas suggested by the literature, as well as in three additional localities to test these hypotheses. The individuals of Laguna de Rocha showed a moderate genetic differentiation with respect to some of the other populations surveyed. Specimens of Montevideo showed the higher genetic distinctiveness. Given the apparent absence of geographical barriers, other factors may be responsible for the observed differentiation. The complex pattern of forces interacting in this system makes it difficult to disentangle the causes of the population structure found. The adaptation to local environmental conditions could be playing an important role in population differentiation, as well as the possible selective pressures imposed by fisheries. The results obtained in this work offer clues about the processes responsible for differentiation of fishes in estuarine and marine environments.
Phylogeographic patterns of the SW Atlantic estuarine crab Neohelice granulata were examined using mitochondrial DNA cytochrome oxidase I sequences and analyzed together with morphometric data. Specimens were sampled during a 4-year period (2001)(2002)(2003)(2004) from 11 localities encompassing the full distributional range of this species along the SW Atlantic (22°57′ S to 42°25′ S). DNA sequences were obtained from 69 individuals belonging to seven localities, and morphometric variation in 12 continuous characters was analyzed for 646 crabs from ten localities. Strong genetic differentiation, consistent with a pattern of isolation-by-distance, was detected among all localities indicating that gene flow occurs mainly between neighboring populations. Analyses of molecular variance showed genetic subdivision between the southern (Argentina) and the northern (Brazil) sites, suggesting restricted gene flow at a regional scale. The genetic structure of this species could be divided into two distinct groups due to a limited gene flow between southern and northern regions as a consequence of larval dispersal patterns. Coastal currents in the vicinity of the Rio de la Plata likely act as a barrier to dispersal within the species range. Moreover, genetic data indicate that populations of N. granulata might have undergone a northward demographic expansion since the late Pleistocene. The morphometric analysis showed no geographical pattern of morphological differentiation, although there were differences among sampling sites.
A previous study showed that Dromiciops gliroides has deep phylogeographic structure, with 3 allopatric and highly differentiated groups. Here, we constructed on that study by assessing the morphologic variation of D. gliroides. Our results show that along its distribution Dromiciops is morphologically highly variable and that the geographic pattern of morphologic variation matches the phylogeographic pattern. Taken together, morphological and molecular data indicate the existence of 2 unrecognized and unnamed species of monito del monte, which are here named and described. Cranial and dental features can easily distinguish species of Dromiciops. One of the new species is endemic of Chile, and the other new species occurs in Argentina and Chile. D. gliroides s.s. is restricted to the southern part of the genus distribution including Chiloé Island. We comment on the conservation significance of our findings and on the need of continuing with field- and collection-based research in order to characterize the richness of the Chilean mammal assemblage. Un estudio previo mostró que Dromiciops gliroides tiene una marcada estructura filogeográfica con 3 grupos alopátridos bien diferenciados. Dado esos resultados, en el presente estudio analizamos la variación morfológica de D. gliroides. Nuestros resultados indican que D. gliroides es, a través de su distribución, altamente variable y que el patrón geográfico de la variación morfológica es congruente con el patrón filogeografico. Considerada en conjunto, la evidencia morfológica y molecular indica la existencia de dos especies de monito del monte que no han sido reconocidas, las que son aca descritas y nominadas. Las tres especies de Dromiciops se pueden distinguir fácilmente por características craneales y dentales. Una de las nuevas especies es endémica de Chile y la otra se distribuye en Argentina y Chile. D. gliroides s.s. se restringe a la porción sur del área distribucional del género, incluyendo la Isla de Chiloé. Cerramos el trabajo comentado sobre la necesidad de continuar realizando colectas y trabajo basado en colecciones con el fin de caracterizar la diversidad del ensamble de mamíferos de Chile.
A fundamental issue in the study of intraspecific variation is the analysis of how it is allocated within and between local populations. The genus Ctenomys represents an excellent model for studying such kinds of phenomena, and Ctenomys rionegrensis is particularly interesting for the study of the processes driving geographic differentiation. This species occupies a relatively small area in Uruguay, where it is restricted to sand dunes. Throughout its distribution, these ''tuco-tucos'' show conspicuous phenotypic variation in the form of three easily distinguishable pelage colours: melanic, agouti and dark-backed. These observations contrast with the usual correlation between pelage and substrate colour found among small mammals, including other tuco-tucos and subterranean rodents on other continents. Different hypotheses have been advanced to explain the population structure pattern found in this tuco-tuco, including the random fixation of alternative pelage colours by drift and the possible role of an unknown type of selection to compensate possible predation pressures against melanic individuals. We analyse the geographic variation in the cranial shape of C. rionegrensis along its distribution range, using geometric morphometric techniques. Thirteen landmarks, assumed to be homologous among all specimens analysed, were chosen in each of three views of the skull. The discriminant function analyses performed over the partial warps and uniform components scores matrix do not discriminate among different pelage types regardless of the view of the skull considered. In contrast, the discriminant function showed a better separation among local populations. No correlation was found between geographic and morphological distances, or between genetic and morphological distances, among pairs of popualtions studied. This geometric morphometric approach had proved to be sensitive enough to detect a similar pattern of population structure that the molecular markers employed before.
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