Comparative genomic analysis of the false killer whale ( Pseudorca crassidens ) LMBR1 locus

The sequencing and comparative genomic analysis of LMBR1 loci in mammals or other species, including human, would be very important in understanding evolutionary genetic changes underlying the evolution of limb development. In this regard, comparative genomic annotation of the false killer whale LMB...

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Bibliographic Details
Published in:Genome
Main Authors: Kim, Dae-Won, Choi, Sang-Haeng, Kim, Ryong Nam, Kim, Sun-Hong, Paik, Sang-Gi, Nam, Seong-Hyeuk, Kim, Dong-Wook, Kim, Aeri, Kang, Aram, Park, Hong-Seog
Other Authors: Danzmann, Roy
Format: Article in Journal/Newspaper
Language:English
Published: Canadian Science Publishing 2010
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Online Access:http://dx.doi.org/10.1139/g10-043
http://www.nrcresearchpress.com/doi/full-xml/10.1139/G10-043
http://www.nrcresearchpress.com/doi/pdf/10.1139/G10-043
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Summary:The sequencing and comparative genomic analysis of LMBR1 loci in mammals or other species, including human, would be very important in understanding evolutionary genetic changes underlying the evolution of limb development. In this regard, comparative genomic annotation of the false killer whale LMBR1 locus could shed new light on the evolution of limb development. We sequenced two false killer whale BAC clones, corresponding to 156 kb and 144 kb, respectively, harboring the tightly linked RNF32, LMBR1, and NOM1 genes. Our annotation of the false killer whale LMBR1 gene showed that it consists of 17 exons (1473 bp), in contrast to 18 exons (1596 bp) in human, and it displays 93.1% and 95.6% nucleotide and amino acid sequence similarity, respectively, compared with the human gene. In particular, we discovered that exon 10, deleted in the false killer whale LMBR1 gene, is present only in primates, and this fact strongly implies that exon 10 might be crucial in determining primate-specific limb development. ZRS and TFBS sequences have been well conserved across 11 species, suggesting that these regions could be involved in an important function of limb development and limb patterning. The neighboring gene RNF32 showed several lineage-conserved exons, such as exons 2 through 9 conserved in eutherian mammals, exons 3 through 9 conserved in mammals, and exons 5 through 9 conserved in vertebrates. The other neighboring gene, NOM1, had undergone a substitution (ATGā†’GTA) at the start codon, giving rise to a 36 bp shorter N-terminal sequence compared with the human sequence. Our comparative analysis of the false killer whale LMBR1 genomic locus provides important clues regarding the genetic regions that may play crucial roles in limb development and patterning.