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Interspecific Divergence (interspecific + divergence)

Distribution by Scientific Domains
Life Sciences100%

Selected Abstracts

Evolutionary acceleration in the most endangered mammal of Canada: speciation and divergence in the Vancouver Island marmot (Rodentia, Sciuridae)

JOURNAL OF EVOLUTIONARY BIOLOGY, Issue 5 2007
A. CARDINI
Abstract The Vancouver Island marmot is the most endangered mammal of Canada. Factors which have brought this population to the verge of extinction have not yet been fully elucidated, but the effects of deforestation and habitat fragmentation on survival rates, as well as those of variation in rainfall, temperature, snowpack depth and snowmelt strongly suggest that marmots on the island are struggling to keep pace with environmental changes. Genetic analyses, however, seem to indicate that the Vancouver Island marmot may merely represent a melanistic population of its parental species on the mainland. Were it not for its black pelage colour, it is unlikely that it would have attracted much attention as a conservation priority. Our study uses three-dimensional coordinates of cranial landmarks to further assess phenotypic differentiation of the Vancouver Island marmot. A pattern of strong interspecific divergence and low intraspecific variation was found which is consistent with aspects of drift-driven models of speciation. However, the magnitude of shape differences relative to the putatively neutral substitutions in synonymous sites of cytochrome b is too large for being compatible with a simple neutral model. A combination of bottlenecks and selective pressures due to natural and human-induced changes in the environment may offer a parsimonious explanation for the large phenotypic differentiation observed in the species. Our study exemplifies the usefulness of a multidisciplinary approach to the study of biological diversity for a better understanding of evolutionary models and to discover aspects of diversity that may be undetected by using only a few genetic markers to characterize population divergence and uniqueness. [source]

Testing candidate plant barcode regions in the Myristicaceae

MOLECULAR ECOLOGY RESOURCES, Issue 3 2008
S. G. NEWMASTER
Abstract The concept and practice of DNA barcoding have been designed as a system to facilitate species identification and recognition. The primary challenge for barcoding plants has been to identify a suitable region on which to focus the effort. The slow relative nucleotide substitution rates of plant mitochondria and the technical issues with the use of nuclear regions have focused attention on several proposed regions in the plastid genome. One of the challenges for barcoding is to discriminate closely related or recently evolved species. The Myristicaceae, or nutmeg family, is an older group within the angiosperms that contains some recently evolved species providing a challenging test for barcoding plants. The goal of this study is to determine the relative utility of six coding (Universal Plastid Amplicon , UPA, rpoB, rpoc1, accD, rbcL, matK) and one noncoding (trnH-psbA) chloroplast loci for barcoding in the genus Compsoneura using both single region and multiregion approaches. Five of the regions we tested were predominantly invariant across species (UPA, rpoB, rpoC1, accD, rbcL). Two of the regions (matK and trnH-psbA) had significant variation and show promise for barcoding in nutmegs. We demonstrate that a two-gene approach utilizing a moderately variable region (matK) and a more variable region (trnH-psbA) provides resolution among all the Compsonuera species we sampled including the recently evolved C. sprucei and C. mexicana. Our classification analyses based on nonmetric multidimensional scaling ordination, suggest that the use of two regions results in a decreased range of intraspecific variation relative to the distribution of interspecific divergence with 95% of the samples correctly identified in a sequence identification analysis. [source]

DNA BARCODING: Barcoding corals: limited by interspecific divergence, not intraspecific variation

MOLECULAR ECOLOGY RESOURCES, Issue 2 2008
T. L. SHEARER
Abstract The expanding use of DNA barcoding as a tool to identify species and assess biodiversity has recently attracted much attention. An attractive aspect of a barcoding method to identify scleractinian species is that it can be utilized on any life stage (larva, juvenile or adult) and is not influenced by phenotypic plasticity unlike morphological methods of species identification. It has been unclear whether the standard DNA barcoding system, based on cytochrome c oxidase subunit 1 (COI), is suitable for species identification of scleractinian corals. Levels of intra- and interspecific genetic variation of the scleractinian COI gene were investigated to determine whether threshold values could be implemented to discriminate conspecifics from other taxa. Overlap between intraspecific variation and interspecific divergence due to low genetic divergence among species (0% in many cases), rather than high levels of intraspecific variation, resulted in the inability to establish appropriate threshold values specific for scleractinians; thus, it was impossible to discern most scleractinian species using this gene. [source]

A mitochondrial phylogeography of Brachidontes variabilis (Bivalvia: Mytilidae) reveals three cryptic species

JOURNAL OF ZOOLOGICAL SYSTEMATICS AND EVOLUTIONARY RESEARCH, Issue 4 2007
M. Sirna Terranova
Abstract This study examined genetic variation across the range of Brachidontes variabilis to produce a molecular phylogeography. Neighbour joining (NJ), minimum evolution (ME) and maximum parsimony (MP) trees based on partial mitochondrial DNA sequences of 16S-rDNA and cytochrome oxidase (COI) genes revealed three monophyletic clades: (1) Brachidontes pharaonis s.l. from the Mediterranean Sea and the Red Sea; (2) B. variabilis from the Indian Ocean; (3) B. variabilis from the western Pacific Ocean. Although the three clades have never been differentiated by malacologists employing conventional morphological keys, they should be ascribed to the taxonomic rank of species. The nucleotide divergences between Brachidontes lineages (between 10.3% and 23.2%) were substantially higher than the divergence between congeneric Mytilus species (2.3,6.7%) and corresponded to interspecific divergences found in other bivalvia, indicating that they should be considered three different species. Analysis of the 16S-rDNA sequences revealed heteroplasmy, indicating dual uniparental inheritance (DUI) of mtDNA in the species of Brachidontes collected in the Indian Ocean, but not in the species in the Pacific nor in the species in the Red Sea and the Mediterranean Sea. When we employed the conventional estimate of the rate of mitochondrial sequence divergence (2% per million years), the divergence times for the three monophyletic lineages were 6,11 Myr for the Indian Ocean and Pacific Ocean Brachidontes sp. and 6.5,9 Myr for the Red Sea and Indian Ocean Brachidontes sp. Thus, these species diverged from one another during the Miocene (23.8,5.3 Myr). We infer that a common ancestor of the three Brachidontes species probably had an Indo-Pacific distribution and that vicariance events, linked to Pleistocene glaciations first and then to the opening of the Red Sea, produced three monophyletic lineages. Riassunto Lo studio filogeografico è stato condotto su tutto l'areale di Brachidontes variabilis (Krauss, 1848) attraverso l'analisi di sequenze mitocondriali (16S-rDNA e COI) che hanno separato i campioni in tre cladi monofiletici. Diversi algoritmi (NJ, ME e MP) hanno elaborato alberi con la stessa topologia, in cui è possibile riconoscere: (1) Brachidontes pharaonis s.l. dell'area Mar Mediterraneo , Mar Rosso; (2) Brachidontes variabilis dell' Oceano Indiano; (3) Brachidontesvariabilis dell'Oceano Pacifico. Il loro grado di divergenza è sufficientemente alto da potere ascrivere al rango di specie i singoli cladi, nonostante non siano stati ancora individuati i caratteri tassonomici distintivi, a causa della grande variazione morfologica. La divergenza nucleotidica tra le tre linee di Brachidontes era compresa tra 10.3% e 23.2%, in un range di valori superiori a quelli trovati nel confronto tra specie congeneriche di Mytilus sp (2.3,6.7%). Utilizzando il tasso evolutivo, che convenzionalmente viene applicato ai valori di divergenza genetica di geni mitocondriali (2% per milioni di anni), si sono ricavati tempi di divergenza corrispondenti a 6,11 milioni di anni tra Oceano Indiano e Pacifico, e a 6.5,9 milioni di anni tra Mar Rosso e Oceano Indiano. Le tre linee evolutive sembrano essersi separate durante il Miocene. Probabilmente un comune antenato con distribuzione Indo-Pacifica può essere andato incontro a processi di vicarianza e/o di dispersione legati alle glaciazioni pleistoceniche prima e all'apertura del Mar Rosso dopo. [source]