RESUMO
A great diversity of animal species adapted to life in the semi-arid Caatinga of northeastern Brazil, including seasonal killifishes, has been reported in the last three decades. More recently, field and molecular data have shown a high occurrence of cryptic species. The killifish group herein analysed, the Hypsolebiasmagnificus species complex, is endemic to the middle and southern portion of the Caatinga, occupying about 120 km along the floodplains of the middle São Francisco River and some adjacent tributaries. Species of this complex are rare and presently considered threatened with extinction, being uniquely found in pools protected by trees and bushes. Single-locus delimitation methods were used to test species limits of populations displaying different colour patterns along the whole distribution of the complex. All analyses consistently supported the three nominal species and two new, herein described: H.gardneri Costa, sp. n., from the floodplains of the middle São Francisco River and H.hamadryades Costa, sp. n., from the Gorotuba River floodplains. The phylogenetic analysis highly supports H.hamadryades as sister to a clade comprising H.gardneri and H.harmonicus. Our field observations suggest that H.hamadryades is a miniature species. This study indicates that the H.magnificus complex comprises cryptic species apparently endemic to small areas and extremely vulnerable to environmental changes, deserving high concern.
RESUMO
The Caatinga is the largest nucleus of seasonally dry tropical forests in South America, but little is known about the evolutionary history and biogeography of endemic organisms. Evolutionary diversification and distribution of terrestrial vertebrates endemic to the Caatinga have been explained by palaeogeographical Neogene episodes, mostly related to changes in the course of the São Francisco River, the largest river in the region. Our objective is to estimate the timing of divergence of two endemic groups of short-lived seasonal killifishes inhabiting all ecoregions of the Caatinga, testing the occurrence of synchronic events of spatial diversification in light of available data on regional palaeogeography. We performed independent time-calibrated phylogenetic molecular analyses for two clades of sympatric and geographically widespread seasonal killifishes endemic to the Caatinga, the Hypsolebias antenori group and the Cynolebias alpha-clade. Our results consistently indicate that species diversification took place synchronically in both groups, as well as it is contemporary to diversification of other organisms adapted to life in the semi-arid Caatinga, including lizards and small mammals. Both groups originated during the Miocene, but species diversification started between the Late Miocene and Early Pliocene, when global cooling probably favoured the expansion of semi-arid areas. Synchronic diversification patterns found are chronologically related to Tertiary palaeogeographical reorganizations associated to continental drift and to Quaternary climatic changes, corroborating the recent proposal that South American biodiversity has been continuously shaped between the Late Paleogene and Pleistocene.
Assuntos
Peixes Listrados , Animais , Biodiversidade , Brasil , Florestas , Especiação Genética , Variação Genética , História Antiga , Peixes Listrados/classificação , Peixes Listrados/genética , Filogenia , Filogeografia , Estações do Ano , Clima TropicalRESUMO
The rich biological diversity of South America has motivated a series of studies associating evolution of endemic taxa with the dramatic geologic and climatic changes that occurred during the Cainozoic. The organism here studied is the killifish tribe Cynolebiini, a group of seasonal fishes uniquely inhabiting temporary pools formed during the rainy seasons. The Cynolebiini are found in open vegetation areas inserted in the main tropical and subtropical South American phytogeographical regions east of the Andes. Here, we present the first molecular phylogeny sampling all the eight genera of the Cynolebiini, using fragments of two mitochondrial and four nuclear genes for 35 species of Cynolebiini plus 19 species as outgroups. The dataset, 4448bp, was analysed under Bayesian and maximum likelihood approaches, providing a relatively well solved tree, which retrieves high support values for the Cynolebiini and most included clades. The resulting tree was used to estimate the time of divergence in included lineages using two cyprinodontiform fossils to calibrate the tree. We further investigated historical biogeography through the likelihood-based DEC model. Our estimates indicate that divergence between the clades comprising New World and Old World aplocheiloids occurred during the Eocene, about 50Mya, much more recent than the Gondwanan fragmentation scenario assumed in previous studies. This estimation is nearly synchronous to estimated splits involving other South American and African vertebrate clades, which have been explained by transoceanic dispersal through an ancient Atlantic island chain during the Palaeogene. We estimate that Cynolebiini split from its sister group Cynopoecilini in the Oligocene, about 25Mya and that Cynolebiini started to diversify giving origin to the present genera during the Miocene, about 20-14Mya. The Cynolebiini had an ancestral origin in the Atlantic Forest and probably were not present in the open vegetation formations of central and northeastern South America until the Middle Miocene, when expansion of dry open vegetation was favoured by cool temperatures and strike seasonality. Initial splitting between the genera Cynolebias and Simpsonichthys during the Miocene (about 14Mya) is attributed to the uplift of the Central Brazilian Plateau.
Assuntos
Peixes Listrados/classificação , Animais , Teorema de Bayes , Brasil , DNA/química , DNA/isolamento & purificação , DNA/metabolismo , Complexo IV da Cadeia de Transporte de Elétrons/classificação , Complexo IV da Cadeia de Transporte de Elétrons/genética , Fósseis , Peixes Listrados/genética , Funções Verossimilhança , Proteínas dos Microfilamentos/classificação , Proteínas dos Microfilamentos/genética , Neuropeptídeos/classificação , Neuropeptídeos/genética , Proteínas Nucleares/classificação , Proteínas Nucleares/genética , Filogenia , RNA Ribossômico 16S/classificação , RNA Ribossômico 16S/genética , Rodopsina/classificação , Rodopsina/genética , Estações do Ano , Análise de Sequência de DNA , América do SulRESUMO
Internal fertilization is a widespread mode of reproduction in chondrichthyans and tetrapods, but uncommon in actinopterygian fishes. In killifishes of the suborder Aplocheiloidei, internal fertilization is restricted to two genera, Campellolebias and Cynopoecilus, both containing species adapted to life in seasonal pools of subtropical South America and exhibiting elaborated inseminating structures. Phylogenetic studies involving these genera are scarce and limited to morphological characters and fragments of mitochondrial DNA sequences available for a few taxa, providing incongruent results and thus impeding hypotheses on the evolution of insemination and related morphological traits. We analyzed three nuclear loci (GLYT1, ENC1, Rho) for 13 aplocheiloid taxa obtaining the first well-supported phylogeny for cynopoecilines, thus providing a significant background to interpret evolutionary changes within the group. Like in killifishes of the suborder Cyprinodontoidei, the evolution of internal fertilization in aplocheiloids is associated with deep changes in the structure of male anal fin. The phylogenetic analyses indicate that internal fertilization corresponds to a single evolutionary event during the evolution of aplocheiloid killifishes. The analyses also indicate that male specialized muscle characters, comprising a muscular ejaculatory pump in the urogenital region and hypertrophied inclinatores and depressores anales, arose in the ancestor of the clade comprising Campellolebias and Cynopoecilus. On the other hand, anal fin specialized structures including the male inseminating tube of Campellolebias and the male inseminating fan of Cynopoecilus evolved independently in each genus.