Your search keyword '"Finches classification"' showing total 2 results

1. Differentially expressed genes match bill morphology and plumage despite largely undifferentiated genomes in a Holarctic songbird.

Author

Mason NA and Taylor SA

Subjects

Animals, Arctic Regions, Beak anatomy & histology, Ecosystem, Feathers anatomy & histology, Female, Finches anatomy & histology, Gene Flow, Genetics, Population, High-Throughput Nucleotide Sequencing, Linear Models, Male, Models, Genetic, North America, Phylogeny, Polymorphism, Single Nucleotide, Sequence Analysis, DNA, Transcriptome, Finches classification, Phenotype

Abstract

Understanding the patterns and processes that contribute to phenotypic diversity and speciation is a central goal of evolutionary biology. Recently, high-throughput sequencing has provided unprecedented phylogenetic resolution in many lineages that have experienced rapid diversification. The Holarctic redpoll finches (Genus: Acanthis) provide an intriguing example of a recent, phenotypically diverse lineage; traditional sequencing and genotyping methods have failed to detect any genetic differences between currently recognized species, despite marked variation in plumage and morphology within the genus. We examined variation among 20 712 anonymous single nucleotide polymorphisms (SNPs) distributed throughout the redpoll genome in combination with 215 825 SNPs within the redpoll transcriptome, gene expression data and ecological niche modelling to evaluate genetic and ecological differentiation among currently recognized species. Expanding upon previous findings, we present evidence of (i) largely undifferentiated genomes among currently recognized species; (ii) substantial niche overlap across the North American Acanthis range; and (iii) a strong relationship between polygenic patterns of gene expression and continuous phenotypic variation within a sample of redpolls from North America. The patterns we report may be caused by high levels of ongoing gene flow between polymorphic populations, incomplete lineage sorting accompanying very recent or ongoing divergence, variation in cis-regulatory elements, or phenotypic plasticity, but do not support a scenario of prolonged isolation and subsequent secondary contact. Together, these findings highlight ongoing theoretical and computational challenges presented by recent, rapid bouts of phenotypic diversification and provide new insight into the evolutionary dynamics of an intriguing, understudied non-model system., (© 2015 John Wiley & Sons Ltd.)

Published

2015

2. Patchy distributions belie morphological and genetic homogeneity in rosy-finches.

Author

Drovetski SV, Zink RM, and Mode NA

Subjects

Animals, Asia, DNA, Mitochondrial genetics, Evolution, Molecular, Feathers anatomy & histology, Female, Finches anatomy & histology, Finches classification, Geography, Haplotypes, Male, Mitochondria genetics, North America, Phenotype, Pigmentation, Sequence Analysis, DNA, Species Specificity, Finches genetics, Genetic Speciation, Genetic Variation, Phylogeny

Abstract

DNA sequence data often appear to contradict low-level avian taxonomy, which is usually based on patterns of external phenotypic similarity. We examined such an apparent contradiction in the Nearctic rosy-finches. On the basis of several phenotypic characters the finches were divided into three species congeneric with three Asian species. When Nearctic taxa were analyzed in a principal components analysis, 66.9% of phenotypic variation was explained by differences between the Bering Sea and continental populations, sexual dimorphism and a latitudinal cline. Our phylogenetic analysis of mitochondrial ND2 sequences revealed four clades among six species of rosy-finches. Three clades corresponded to three Asian species. The fourth clade included all three Nearctic species. Their haplotypes were not reciprocally monophyletic and the combined genetic variability of all Nearctic taxa was lower than in two of their Asian congeners. A Z-specific intron (ACO1I9) and an autosomal coding locus (MC1R) provided little additional phylogenetic information, most likely because of the longer coalescence times relative to ND2. Phylogeographic analyses of ND2 data revealed significant gene flow among neighboring localities regardless of their taxonomic assignment. Our analyses showed that DNA and phenotypic data are not in conflict, but rather complement each other, and together help clarify species limits. Our data are consistent with a single species in North America, not three.

Published

2009