ABSTRACT
The central Andean rainforests and the Atlantic Forest are two similar biomes that are fully isolated by xerophytic and open-vegetation regions (the Chaco and Cerrado, respectively). Even though there is evidence suggesting that these rainforests have been connected in the past, their dynamics of connection, the geographic areas that bridged these regions, and the biological processes that have promoted diversification between them remain to be studied. In this research, we used three passerine species (Poecilotriccus plumbeiceps, Phylloscartes ventralis and Cacicus chrysopterus) as models to address whether the Andean and the Atlantic forests have acted as a refugia system (macrorefugia), and to evaluate biogeographic hypotheses of diversification and connection between them. In order to achieve these goals, we performed traditional phylogeographic analyses and compared alternative biogeographic scenarios by using Approximate Bayesian Computation. Additionally, we performed morphological analyses to evaluate phenotypic divergence between these regions. Our findings support that both rainforest regions acted as refugia, but that the impact of their isolation was stronger on the genetic than on the morphologic characters. Our results provided evidence that both geographic isolation as well as ecological factors have modeled the external traits of forest organisms in the region. Regarding the connection routes between the Andes and the Atlantic Forest, the genetic data rejected the hypothesis of a Chaco connection in the tested species, providing evidence for a connection through the Cerrado or through the transition between the Cerrado and Chaco, in a process that could have started as early as the Late Miocene.
Subject(s)
Biological Evolution , Forests , Genetic Variation , Passeriformes/anatomy & histology , Passeriformes/genetics , Animals , Bayes Theorem , Ecosystem , Genetics, Population , Phylogeny , Phylogeography , Species SpecificityABSTRACT
The biogeographic histories of parasites and pathogens are infrequently compared with those of free-living species, including their hosts. Documenting the frequency with which parasites and pathogens disperse across geographic regions contributes to understanding not only their evolution, but also the likelihood that they may become emerging infectious diseases. Haemosporidian parasites of birds (parasite genera Plasmodium, Haemoproteus and Leucocytozoon) are globally distributed, dipteran-vectored parasites. To date, over 2000 avian haemosporidian lineages have been designated by molecular barcoding methods. To achieve their current distributions, some lineages must have dispersed long distances, often over water. Here we quantify such events using the global avian haemosporidian database MalAvi and additional records primarily from the Americas. We scored lineages as belonging to one or more global biogeographic regions based on infection records. Most lineages were restricted to a single region but some were globally distributed. We also used part of the cytochrome b gene to create genus-level parasite phylogenies and scored well-supported nodes as having descendant lineages in regional sympatry or allopatry. Descendant sister lineages of Plasmodium, Haemoproteus and Leucocytozoon were distributed in allopatry in 11, 16 and 15% of investigated nodes, respectively. Although a small but significant fraction of the molecular variance in cytochrome b of all three genera could be explained by biogeographic region, global parasite dispersal likely contributed to the majority of the unexplained variance. Our results suggest that avian haemosporidian parasites have faced few geographic barriers to dispersal over their evolutionary history.
Subject(s)
Bird Diseases/epidemiology , Communicable Diseases, Emerging/epidemiology , Global Health , Haemosporida/physiology , Protozoan Infections, Animal/epidemiology , Analysis of Variance , Animal Migration , Animals , Bird Diseases/parasitology , Bird Diseases/transmission , Birds , Communicable Diseases, Emerging/parasitology , Communicable Diseases, Emerging/transmission , Communicable Diseases, Emerging/veterinary , DNA Barcoding, Taxonomic/veterinary , Diptera/classification , Diptera/parasitology , Genetic Variation , Haemosporida/classification , Insect Vectors/classification , Insect Vectors/parasitology , Likelihood Functions , Phylogeny , Phylogeography , Protozoan Infections, Animal/parasitology , Protozoan Infections, Animal/transmissionABSTRACT
Parasite prevalence is thought to be positively related to host population density owing to enhanced contagion. However, the relationship between prevalence and local abundance of multiple host species is underexplored. We surveyed birds and their haemosporidian parasites (genera Plasmodium and Haemoproteus) at multiple sites across eastern North America to test whether the prevalence of these parasites in a host species at a particular site is related to that host's local abundance. Prevalence was positively related to host abundance within most sites, although the effect was stronger and more consistent for Plasmodium than for Haemoproteus. In contrast, prevalence was not related to variation in the abundance of most individual host species among sites across the region. These results suggest that parasite prevalence partly reflects the relative abundances of host species in local assemblages. However, three nonnative host species had low prevalence despite being relatively abundant at one site, as predicted by the enemy release hypothesis.
Subject(s)
Bird Diseases/epidemiology , Bird Diseases/parasitology , Haemosporida/physiology , Host-Parasite Interactions/physiology , Protozoan Infections, Animal/epidemiology , Animals , Birds/parasitology , North America/epidemiology , Plasmodium/physiology , Population Density , PrevalenceABSTRACT
The drivers of regional parasite distributions are poorly understood, especially in comparison with those of free-living species. For vector-transmitted parasites, in particular, distributions might be influenced by host-switching and by parasite dispersal with primary hosts and vectors. We surveyed haemosporidian blood parasites (Plasmodium and Haemoproteus) of small land birds in eastern North America to characterize a regional parasite community. Distributions of parasite populations generally reflected distributions of their hosts across the region. However, when the interdependence between hosts and parasites was controlled statistically, local host assemblages were related to regional climatic gradients, but parasite assemblages were not. Moreover, because parasite assemblage similarity does not decrease with distance when controlling for host assemblages and climate, parasites evidently disperse readily within the distributions of their hosts. The degree of specialization on hosts varied in some parasite lineages over short periods and small geographic distances independently of the diversity of available hosts and potentially competing parasite lineages. Nonrandom spatial turnover was apparent in parasite lineages infecting one host species that was well-sampled within a single year across its range, plausibly reflecting localized adaptations of hosts and parasites. Overall, populations of avian hosts generally determine the geographic distributions of haemosporidian parasites. However, parasites are not dispersal-limited within their host distributions, and they may switch hosts readily.
Subject(s)
Birds/parasitology , Haemosporida/physiology , Host Specificity , Host-Parasite Interactions , Algorithms , Animals , Bird Diseases/blood , Bird Diseases/parasitology , Climate , Cytochromes b/genetics , Geography , Haemosporida/classification , Haemosporida/genetics , Models, Biological , Parasites/classification , Parasites/genetics , Parasites/physiology , Population Dynamics , Principal Component Analysis , Time Factors , United StatesABSTRACT
The Galápagos archipelago has never been connected to any continental land masses, so it is of interest to know the colonization and diversification history of its endemic species. We analyzed the phylogenetic placement of the endemic Galápagos flycatcher, M. magnirostris, within Myiarchus by using the genes ND2 and cytb (1970 bp) to compare 16 of the 22 species that comprise this genus. We also analyzed variability in cytb sequences from 154 M. magnirostris individuals captured on seven Galápagos islands. Our phylogenetic analyses recovered the two main Myiarchus clades that had been described by previous genetic, morphological, and vocal analyses. M. magnirostris is monophyletic and its closest living relative is M. tyrannulus from Mexico and Central America. The average age for the split node between these two groups was approximately 850,000 years (95% C.I. 630,735-1,087,557). M. tyrannulus, M. nugator, M. nuttingi, M. sagrae, and M. stolidus are not monophyletic species. Within M. magnirostris itself, we found low nucleotide and haplotype diversities (π=0.0009 and h=0.4913, respectively) and a high genetic structure among populations. We also detected a star-shaped haplotype network and significantly negative values for Tajima's D and Fu's Fs for this species. Our results suggest that M. magnirostris originated from a single colonization event and had a recent population expansion in the Galápagos archipelago.
Subject(s)
Cytochromes b/genetics , DNA, Mitochondrial/genetics , NADH Dehydrogenase/genetics , Phylogeny , Songbirds/classification , Songbirds/genetics , Animals , Base Sequence , Ecuador , Evolution, Molecular , Genetic Speciation , Genetic Variation , Genome , Molecular Sequence Data , Sequence Alignment , Sequence Analysis, DNAABSTRACT
We studied the intraspecific evolutionary history of the South American Atlantic forest endemic Xiphorhynchusfuscus (Aves: Dendrocolaptidae) to address questions such as: Was the diversification of this bird's populations associated to areas of avian endemism? Which models of speciation (i.e., refuges, river as barriers or geotectonism) explain the diversification within X. fuscus? Does the genetic data support subspecies as independent evolutionary units (species)? We used mitochondrial (n=34) and nuclear (n=68) DNA sequences of X. fuscus to study temporal and spatial relationships within and between populations. We described four main monophyletic lineages that diverged during the Pleistocene. The subspecies taxonomy did not match all the evolutionary lineages; subspecies atlanticus was the only one that represented a monophyletic and isolated lineage. The distribution of these lineages coincided with some areas of endemism for passerines, suggesting that those areas could be regions of biotic differentiation. The ancestor of X. fuscus diverged approximately 3 million years ago from Amazonian taxa and the phylogeographic pattern suggested that X. fuscus radiated from northeastern Brazil. Neither the riverine nor the geotectonic vicariance models are supported as the primary cause for diversification of geographic lineages, but rainforest contractions and expansions (ecological vicariance) can explain most of the spatial divergence observed in this species. Finally, analyses of gene flow and divergence time estimates suggest that the endangered subspecies atlanticus (from northeastern Brazil) can be considered a full species under the general lineage species concept.
Subject(s)
Evolution, Molecular , Genes, Mitochondrial , Genetic Speciation , Passeriformes/genetics , Phylogeny , Animals , Bayes Theorem , Biodiversity , Brazil , Cell Nucleus/genetics , DNA, Mitochondrial/genetics , Gene Flow , Genetics, Population , Geography , Haplotypes , Likelihood Functions , Mitochondria/genetics , Models, Genetic , Passeriformes/classification , Sequence Alignment , Sequence Analysis, DNAABSTRACT
O gênero Melittobia Westwood compreende várias espécies de microparasitóides, das quais apenas duas foram registradas no Brasil até agora: M. australica Girault e M. hawaiiensis Perkins. Entretanto, essas espécies são de difícil identificação através de métodos taxonômicos tradicionais. No presente trabalho, marcadores moleculares amplificados ao acaso (PCR-RAPD) foram utilizados com o objetivo de se discriminar as duas espécies e, ao mesmo tempo, analisar a variabilidade genética em populações de M. australica. A maioria dos fragmentos gerados foi espécie-específicos estando presente em todos os indivíduos de uma espécie e ausente nos indivíduos da outra espécie, demonstrando a adequação dessa técnica na distinção das espécies de Melittobia estudadas. A técnica de PCR-RAPD também demonstrou que os indivíduos das diferentes populações estudadas são muito semelhantes entre si, o que pode ser atribuído ao efeito fundador e/ou a grande capacidade de dispersão dessas populações. As distâncias genéticas dentro (D = 1,19-3,54%) e entre as populações (D = 1,93-5,28%) de M. australica apresentaram valores muito baixos, refletindo a reduzida variação genética existente nas populações dessa espécie.
Subject(s)
Animals , Hymenoptera/classification , Hymenoptera/genetics , Random Amplified Polymorphic DNA TechniqueABSTRACT
The genus Melittobia Westwood comprises several species of microparasitoids and only two of them are know to occur in Brazil up to now: M. australica Girault and M. hawaiiensis Perkins. Nevertheless, the differentiation between these two species using traditional taxonomy is very difficult. In the present study, we used random amplified polymorphic DNA chain reaction (RAPD-PCR) to test for its ability to discriminate between these two species and to examine the genetic variation among the studied populations of M. australica. Most of the generated fragments were species-specific, occurring in all individuals of one species and absent in the individuals of the other species demonstrating the appropriateness of such technique to distinguish between both of the Melittobia species occurring in Brazil. RAPD-PCR also demonstrated low variability among different populations of M. australica, which may be due to a founder effect and/or high dispersion capacity of these populations. Genetic distances within (D = 1.19-3.54%) and among populations (D = 1.93-5.28%) presented very low values, reflecting the reduced genetic variation that exists among populations of M. australica.
