The Experts below are selected from a list of 72 Experts worldwide ranked by ideXlab platform
Tilman C Schneider - One of the best experts on this subject based on the ideXlab platform.
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genetic population structure and relatedness in the narrow striped mongoose mungotictis decemlineata a social malagasy carnivore with sexual segregation
Ecology and Evolution, 2016Co-Authors: Tilman C Schneider, Peter M Kappeler, Luca PozziAbstract:Information on the genetic structure of animal populations can allow inferences about mechanisms shaping their social organization, dispersal, and mating system. The mongooses (Herpestidae) include some of the best-studied mammalian systems in this respect, but much less is known about their closest relatives, the Malagasy carnivores (Eupleridae), even though some of them exhibit unusual association patterns. We investigated the genetic structure of the Malagasy narrow-striped mongoose (Mungotictis decemlineata), a small forest-dwelling gregarious carnivore exhibiting sexual segregation. Based on mtDNA and microsatellite analyses, we determined population-wide haplotype structure and sex-specific and within-group relatedness. Furthermore, we analyzed parentage and sibship relationships and the level of reproductive skew. We found a matrilinear population structure, with several neighboring female units sharing identical haplotypes. Within-group female relatedness was significantly higher than expected by chance in the majority of units. Haplotype diversity of males was significantly higher than in females, indicating male-biased dispersal. Relatedness within the majority of male associations did not differ from random, not proving any kin-directed benefits of male sociality in this case. We found indications for a mildly promiscuous mating system without monopolization of females by males, and low levels of reproductive skew in both sexes based on parentages of emergent young. Low relatedness within breeding pairs confirmed immigration by males and suggested similarities with patterns in social mongooses, providing a starting point for further investigations of mate choice and female control of reproduction and the connected behavioral mechanisms. Our study contributes to the understanding of the determinants of male sociality in carnivores as well as the mechanisms of female competition in species with small social units.
Steven M Goodman - One of the best experts on this subject based on the ideXlab platform.
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new insights into the systematics of malagasy mongoose like carnivorans carnivora Eupleridae galidiinae based on mitochondrial and nuclear dna sequences
Journal of Zoological Systematics and Evolutionary Research, 2017Co-Authors: Geraldine Veron, Delia Dupre, Andrew P Jennings, Charlie J Gardner, Alexandre Hassanin, Steven M GoodmanAbstract:The Malagasy carnivorans (Eupleridae) comprise seven genera and up to ten species, depending on the authority, and, within the past decades, two new taxa have been described. The family is divided into two subfamilies, the Galidiinae, mongoose-like animals, and the Euplerinae, with diverse body forms. To verify the taxonomic status of Galidiinae species, including recently described taxa, as well as some recognized subspecies, we studied intrageneric genetic variation and structure, using both mitochondrial and nuclear markers. Our results suggest the recognition of four species in the Galidiinae, rendering each genus monospecific. We propose to recognize three subspecies in Galidia elegans (G. e. dambrensis, G. e. elegans, and G. e. occidentalis), two subspecies in Mungotictis decemlineata (M. d. decemlineata and M. d. lineata), and two subspecies in Galidictis fasciata (G. f. fasciata and G. f. grandidieri, the latter was recently described as a distinct species). Our results indicate also that Salanoia durrelli should be treated as a junior synonym of Salanoia concolor. Low levels of intraspecific divergence revealed some geographical structure for the Galidiinae taxa, suggesting that environmental barriers have isolated certain populations in recent geological time. All taxa, whether at the species or subspecies level, need urgent conservation attention, particularly those with limited geographical distributions, as all are threatened by forest habitat degradation.
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genetic population structure in the boky boky carnivora Eupleridae a conservation flagship species in the dry deciduous forests of central western madagascar
Animal Conservation, 2012Co-Authors: Jansen B Van Vuuren, L Woolaver, Steven M GoodmanAbstract:The boky-boky, Mungotictis decemlineata, is an endemic and presumed forest-dependent carnivoran species restricted to lowland central western Madagascar. It inhabits dry deciduous forests, which have been severely reduced in surface area with ∼60% destroyed or degraded by humans during the past 60 years. M. decemlineata is limited to the remnant forests of the central and southern Menabe, and using samples collected from sites across this zone, a phylogeographic study was conducted based on two mitochondrial (1140 base pairs [bp] of cytochrome b and 563 bp of the control region) and one nuclear fragment (591 bp of the seventh intron of the fibrinogen gene). Forty-seven individuals were included from the central Menabe from four principal localities and two animals from the southern Menabe from a single locality. Low sequence divergence (1.65% for the combined fragment, 4.26% for the control region and 0.78% for cytochrome b) characterized specimens across a zone of 130 km delimited by the Tsiribihina River to the north and the Mangoky River to the south; this area includes most of the geographical range of M. decemlineata. Phylogenetic trees, haplotype networks and exact test of population differentiation did not reveal any meaningful geographic partitioning of genetic variation. However, shallow yet significant genetic structure was revealed by ΦST calculations for the combined as well as separate DNA fragments, which we ascribe to isolation-by-distance. We proposed two different scenarios to explain the lack of meaningful phylogeographical structure in Mungotictis: (1) for this forest-dependent species, dispersal during periods of more continuous forest cover gave rise to a genetic meta-population or (2) that it is able to cross non-forested zones and broadly disperses, leading to high levels of genetic homogeneity. Current inferences favour the first hypothesis. The short- and medium-term future of this taxon is in jeopardy associated with habitat destruction across its geographical range.
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seasonal variation in the diet of galidictis grandidieri wozencraft 1986 carnivora Eupleridae in a sub arid zone of extreme south western madagascar
Journal of Zoology, 2009Co-Authors: R Andriatsimietry, Steven M Goodman, E Razafimahatratra, Jana W E Jeglinski, M Marquard, Jorg U GanzhornAbstract:We describe the diet of Grandidier's Vontsira Galidictis grandidieri (family Eupleridae), one of the rarest carnivorans in the world and restricted to an area of 400 km2 in the spiny forest of south-western Madagascar. From May 2006 to May 2007, 342 G. grandidieri scats were collected in the Parc National de Tsimanampetsotsa – 256 faecal samples in the dry season and 86 in the wet season. In total, 886 prey items were identified from these scats. Invertebrates (principally large cockroaches of the genus Gromphadorhina) were the most frequently eaten prey. Even though vertebrates comprised only 8 and 17% of prey individuals in the diet of G. grandidieri during the dry and wet seasons, they contributed 58 and 80% of the prey biomass in each season, respectively. About 90% of all prey consumed had body masses below 10 g. This is well below the weight of the prey consumed by Cryptoprocta ferox, the only native carnivoran occurring in sympatry with G. grandidieri, making competition for food between the two species unlikely.
Luca Pozzi - One of the best experts on this subject based on the ideXlab platform.
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genetic population structure and relatedness in the narrow striped mongoose mungotictis decemlineata a social malagasy carnivore with sexual segregation
Ecology and Evolution, 2016Co-Authors: Tilman C Schneider, Peter M Kappeler, Luca PozziAbstract:Information on the genetic structure of animal populations can allow inferences about mechanisms shaping their social organization, dispersal, and mating system. The mongooses (Herpestidae) include some of the best-studied mammalian systems in this respect, but much less is known about their closest relatives, the Malagasy carnivores (Eupleridae), even though some of them exhibit unusual association patterns. We investigated the genetic structure of the Malagasy narrow-striped mongoose (Mungotictis decemlineata), a small forest-dwelling gregarious carnivore exhibiting sexual segregation. Based on mtDNA and microsatellite analyses, we determined population-wide haplotype structure and sex-specific and within-group relatedness. Furthermore, we analyzed parentage and sibship relationships and the level of reproductive skew. We found a matrilinear population structure, with several neighboring female units sharing identical haplotypes. Within-group female relatedness was significantly higher than expected by chance in the majority of units. Haplotype diversity of males was significantly higher than in females, indicating male-biased dispersal. Relatedness within the majority of male associations did not differ from random, not proving any kin-directed benefits of male sociality in this case. We found indications for a mildly promiscuous mating system without monopolization of females by males, and low levels of reproductive skew in both sexes based on parentages of emergent young. Low relatedness within breeding pairs confirmed immigration by males and suggested similarities with patterns in social mongooses, providing a starting point for further investigations of mate choice and female control of reproduction and the connected behavioral mechanisms. Our study contributes to the understanding of the determinants of male sociality in carnivores as well as the mechanisms of female competition in species with small social units.
Peter M Kappeler - One of the best experts on this subject based on the ideXlab platform.
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genetic population structure and relatedness in the narrow striped mongoose mungotictis decemlineata a social malagasy carnivore with sexual segregation
Ecology and Evolution, 2016Co-Authors: Tilman C Schneider, Peter M Kappeler, Luca PozziAbstract:Information on the genetic structure of animal populations can allow inferences about mechanisms shaping their social organization, dispersal, and mating system. The mongooses (Herpestidae) include some of the best-studied mammalian systems in this respect, but much less is known about their closest relatives, the Malagasy carnivores (Eupleridae), even though some of them exhibit unusual association patterns. We investigated the genetic structure of the Malagasy narrow-striped mongoose (Mungotictis decemlineata), a small forest-dwelling gregarious carnivore exhibiting sexual segregation. Based on mtDNA and microsatellite analyses, we determined population-wide haplotype structure and sex-specific and within-group relatedness. Furthermore, we analyzed parentage and sibship relationships and the level of reproductive skew. We found a matrilinear population structure, with several neighboring female units sharing identical haplotypes. Within-group female relatedness was significantly higher than expected by chance in the majority of units. Haplotype diversity of males was significantly higher than in females, indicating male-biased dispersal. Relatedness within the majority of male associations did not differ from random, not proving any kin-directed benefits of male sociality in this case. We found indications for a mildly promiscuous mating system without monopolization of females by males, and low levels of reproductive skew in both sexes based on parentages of emergent young. Low relatedness within breeding pairs confirmed immigration by males and suggested similarities with patterns in social mongooses, providing a starting point for further investigations of mate choice and female control of reproduction and the connected behavioral mechanisms. Our study contributes to the understanding of the determinants of male sociality in carnivores as well as the mechanisms of female competition in species with small social units.
Katrin Nyakatura - One of the best experts on this subject based on the ideXlab platform.
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Updating the evolutionary history of Carnivora (Mammalia): a new species-level supertree complete with divergence time estimates
BMC Biology, 2012Co-Authors: Katrin Nyakatura, Olaf Rp Bininda-emondsAbstract:Background Although it has proven to be an important foundation for investigations of carnivoran ecology, biology and evolution, the complete species-level supertree for Carnivora of Bininda-Emonds et al . is showing its age. Additional, largely molecular sequence data are now available for many species and the advancement of computer technology means that many of the limitations of the original analysis can now be avoided. We therefore sought to provide an updated estimate of the phylogenetic relationships within all extant Carnivora, again using supertree analysis to be able to analyze as much of the global phylogenetic database for the group as possible. Results In total, 188 source trees were combined, representing 114 trees from the literature together with 74 newly constructed gene trees derived from nearly 45,000 bp of sequence data from GenBank. The greater availability of sequence data means that the new supertree is almost completely resolved and also better reflects current phylogenetic opinion (for example, supporting a monophyletic Mephitidae, Eupleridae and Prionodontidae; placing Nandinia binotata as sister to the remaining Feliformia). Following an initial rapid radiation, diversification rate analyses indicate a downturn in the net speciation rate within the past three million years as well as a possible increase some 18.0 million years ago; numerous diversification rate shifts within the order were also identified. Conclusions Together, the two carnivore supertrees remain the only complete phylogenetic estimates for all extant species and the new supertree, like the old one, will form a key tool in helping us to further understand the biology of this charismatic group of carnivores.
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updating the evolutionary history of carnivora mammalia a new species level supertree complete with divergence time estimates
BMC Biology, 2012Co-Authors: Katrin Nyakatura, Olaf R P BinindaemondsAbstract:Although it has proven to be an important foundation for investigations of carnivoran ecology, biology and evolution, the complete species-level supertree for Carnivora of Bininda-Emonds et al. is showing its age. Additional, largely molecular sequence data are now available for many species and the advancement of computer technology means that many of the limitations of the original analysis can now be avoided. We therefore sought to provide an updated estimate of the phylogenetic relationships within all extant Carnivora, again using supertree analysis to be able to analyze as much of the global phylogenetic database for the group as possible. In total, 188 source trees were combined, representing 114 trees from the literature together with 74 newly constructed gene trees derived from nearly 45,000 bp of sequence data from GenBank. The greater availability of sequence data means that the new supertree is almost completely resolved and also better reflects current phylogenetic opinion (for example, supporting a monophyletic Mephitidae, Eupleridae and Prionodontidae; placing Nandinia binotata as sister to the remaining Feliformia). Following an initial rapid radiation, diversification rate analyses indicate a downturn in the net speciation rate within the past three million years as well as a possible increase some 18.0 million years ago; numerous diversification rate shifts within the order were also identified. Together, the two carnivore supertrees remain the only complete phylogenetic estimates for all extant species and the new supertree, like the old one, will form a key tool in helping us to further understand the biology of this charismatic group of carnivores.
