Molecular Phylogenetics and Evolution, Jan 1, 2007
The extant crocodylians comprise 23 species divided among three families, Alligatoridae, Crocodyl... more The extant crocodylians comprise 23 species divided among three families, Alligatoridae, Crocodylidae, and Gavialidae. Currently, based on morphological data sets, Tomistoma schlegelii (false gharial) is placed within the family Crocodylidae. Molecular data sets consistently support a sister-taxon relationship of T. schlegelii with Gavialis gangeticus (Indian Gharial), which is the sole species in Gavialidae. To elucidate the placement of T. schlegelii within the extant crocodylians, we have sequenced 352 bp of the dentin matrix protein 1 (DMP1) nuclear gene in 30 individuals and 424 bp of the nuclear gene C-mos in 74 individuals. Molecular analysis of the DMP1 data set indicates that it is highly conserved within the Crocodylia. Of special note is a seven base-pair indel (GTGCTTT) shared by T. schlegelii and G. gangeticus, that is absent in the genus Crocodylus, Osteolaemus, and Mecistops. To date, C-mos is the largest molecular data set analyzed for any crocodylian study including multiple samples from all representatives of the eight extant genera. Analysis of these molecular data sets, both as individual gene sequences and concatenated sequences, support the hypothesis that T. schlegelii should be placed within the family Gavialidae.
Molecular Phylogenetics and Evolution, Jan 1, 2009
Transthyretin (TTR) is an attractive candidate for use in phylogenetic analysis because it is a s... more Transthyretin (TTR) is an attractive candidate for use in phylogenetic analysis because it is a short, single-copy nuclear gene with regions that are highly conserved across evolutionarily-divergent organisms from Xenopus laevis to Homo sapiens. To explore its utility as a phylogenetic marker, the complete intron one region (789–805 bp) was sequenced in 22 crocodylian species. Detailed analyses of intron 1 resolved the three expected lineages, Alligatorids, Crocodylids, and Gavialids, and offered additional evidence for the utility of synapomorphic indels in elucidating higher-level phylogenetic relationships. When used in conjunction with other genetic and morphological data sets, intron 1 should be a valuable tool in the investigation of other closely related taxa.
Molecular Phylogenetics and Evolution, Jan 1, 2006
Recently, the phylogenetic placement of the African slender snouted crocodile, Crocodylus cataphr... more Recently, the phylogenetic placement of the African slender snouted crocodile, Crocodylus cataphractus, has come under scrutiny and herein we address this issue using molecular and morphological techniques. Although it is often recognized as being a “basal” form, morphological studies have traditionally placed C. cataphractus within the genus Crocodylus, while molecular studies have suggested that C. cataphractus is very distinct from other Crocodylus. To address the relationship of this species to its congeners we have sequenced portions of two nuclear genes (C-mos 302 bp and ODC 294 bp), and two mitochondrial genes (ND6-tRNAglu-cytB 347 bp and control region 457 bp). Analyses of these molecular datasets, both as individual gene sequences and as concatenated sequences, support the hypothesis that C. cataphractus is not a member of Crocodylus or Osteolaemus. Examination of 165 morphological characters supports and strengthens our resurrection of an historic genus, Mecistops (Gray 1844) for cataphractus.
Molecular Phylogenetics and Evolution, Jan 1, 2007
The extant crocodylians comprise 23 species divided among three families, Alligatoridae, Crocodyl... more The extant crocodylians comprise 23 species divided among three families, Alligatoridae, Crocodylidae, and Gavialidae. Currently, based on morphological data sets, Tomistoma schlegelii (false gharial) is placed within the family Crocodylidae. Molecular data sets consistently support a sister-taxon relationship of T. schlegelii with Gavialis gangeticus (Indian Gharial), which is the sole species in Gavialidae. To elucidate the placement of T. schlegelii within the extant crocodylians, we have sequenced 352 bp of the dentin matrix protein 1 (DMP1) nuclear gene in 30 individuals and 424 bp of the nuclear gene C-mos in 74 individuals. Molecular analysis of the DMP1 data set indicates that it is highly conserved within the Crocodylia. Of special note is a seven base-pair indel (GTGCTTT) shared by T. schlegelii and G. gangeticus, that is absent in the genus Crocodylus, Osteolaemus, and Mecistops. To date, C-mos is the largest molecular data set analyzed for any crocodylian study including multiple samples from all representatives of the eight extant genera. Analysis of these molecular data sets, both as individual gene sequences and concatenated sequences, support the hypothesis that T. schlegelii should be placed within the family Gavialidae.
Molecular Phylogenetics and Evolution, Jan 1, 2009
Transthyretin (TTR) is an attractive candidate for use in phylogenetic analysis because it is a s... more Transthyretin (TTR) is an attractive candidate for use in phylogenetic analysis because it is a short, single-copy nuclear gene with regions that are highly conserved across evolutionarily-divergent organisms from Xenopus laevis to Homo sapiens. To explore its utility as a phylogenetic marker, the complete intron one region (789–805 bp) was sequenced in 22 crocodylian species. Detailed analyses of intron 1 resolved the three expected lineages, Alligatorids, Crocodylids, and Gavialids, and offered additional evidence for the utility of synapomorphic indels in elucidating higher-level phylogenetic relationships. When used in conjunction with other genetic and morphological data sets, intron 1 should be a valuable tool in the investigation of other closely related taxa.
Molecular Phylogenetics and Evolution, Jan 1, 2006
Recently, the phylogenetic placement of the African slender snouted crocodile, Crocodylus cataphr... more Recently, the phylogenetic placement of the African slender snouted crocodile, Crocodylus cataphractus, has come under scrutiny and herein we address this issue using molecular and morphological techniques. Although it is often recognized as being a “basal” form, morphological studies have traditionally placed C. cataphractus within the genus Crocodylus, while molecular studies have suggested that C. cataphractus is very distinct from other Crocodylus. To address the relationship of this species to its congeners we have sequenced portions of two nuclear genes (C-mos 302 bp and ODC 294 bp), and two mitochondrial genes (ND6-tRNAglu-cytB 347 bp and control region 457 bp). Analyses of these molecular datasets, both as individual gene sequences and as concatenated sequences, support the hypothesis that C. cataphractus is not a member of Crocodylus or Osteolaemus. Examination of 165 morphological characters supports and strengthens our resurrection of an historic genus, Mecistops (Gray 1844) for cataphractus.
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