Evaluation of candidate reference genes for quantitative expression studies in Asian seabass (Lates calcarifer) during ontogenesis and in tissues of healthy and infected fishes.

Quantitative real-time PCR (qRT-PCR), used to determine the gene expression profile, is an important tool in functional genomic research, including fishes. To obtain more robust and meaningful result, the best possible normalization of the data is of utmost significance. In the present study, we have evaluated the potential of five commonly used housekeeping genes i.e., elongation factor 1-α (EF1A), ß-Actin (ACTB), 18S ribosomal RNA (18S), glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and ß-2-Microglobulin (B2M) in normal physiological conditions, developmental stages and in response to bacterial infection in Asian seabass, Lates calcarifer (Bloch), an important food fish cultured in the Asia-Pacific region. The expression levels of these five genes were estimated in 11 tissues of normal seabass juveniles, 14 embryonic and larval developmental stages and six tissues of Vibrio alginolyticus-challenged animals. Further, the expression stability of these genes was calculated based on three algorithms i.e. geNorm, NormFinder and BestKeeper. The results showed that although there are tissue-specific variations for each gene, ACTB and EF1A are the most stable genes across the tissues of normal animals. However, in bacteria-challenged animals, EF1A and 18S were found to be the best reference genes for data normalization. The expression of all the genes tested showed an increasing trend in developmental stages and the increase was significant at blastula stage. Among the five genes tested, EF1A and ACTB were found to be the genes with least variation and highest stability across the developmental stages. This forms the first report on validation of housekeeping genes in L. calcarifer, in the context of ontogenic development and in response to infection.

DNA barcoding of elasmobranchs from Indian coast and its reliability in delineating geographically widespread specimens.

Identification of elasmobranchs by conventional taxonomy is difficult due to similarities in morphological characters. Species-specific molecular markers are good choice for identifying species irrespective of it's life stage. Recently, mitochondrial cytochrome c oxidase subunit I (COI) gene got global recognition as a barcode gene to discriminate all animals up-to species level. In this study, mitochondrial COI partial gene was used to develop DNA barcodes for 18 species of elasmobranchs (10 species of sharks and 8 species of rays). The COI barcodes clearly distinguished all the species with high interspecific distance values than intraspecific values. The average interspecific and intraspecific distance values are 8.6% and 0.3% for sharks, respectively and 12.4% and 0.63% for rays, respectively using K2P method. The Neighbor-Joining tree showed distinct clusters shared by the species of same genera. The COI barcodes were also used to estimate allopatric divergences for selected species across broad geographical locations and found that Sphyrna lewini, Aetobatus narinari and Neotrygon kuhlii have cryptic diversity.

Molecular phylogeny of elasmobranchs inferred from mitochondrial and nuclear markers.

The elasmobranchs (sharks, rays and skates) being the extant survivors of one of the earliest offshoots of the vertebrate evolutionary tree are good model organisms to study the primitive vertebrate conditions. They play a significant role in maintaining the ecological balance and have high economic value. Due to over-exploitation and illegal fishing worldwide, the elasmobranch stocks are being decimated at an alarming rate. Appropriate management measures are necessary for restoring depleted elasmobranch stocks. One approach for restoring stocks is implementation of conservation measures and these measures can be formulated effectively by knowing the evolutionary relationship among the elasmobranchs. In this study, a total of 30 species were chosen for molecular phylogeny studies using mitochondrial cytochrome c oxidase subunit I, 12S ribosomal RNA gene and nuclear Internal Transcribed Spacer 2. Among different genes, the combined dataset of COI and 12S rRNA resulted in a well resolved tree topology with significant bootstrap/posterior probabilities values. The results supported the reciprocal monophyly of sharks and batoids. Within Galeomorphii, Heterodontiformes (bullhead sharks) formed as a sister group to Lamniformes (mackerel sharks): Orectolobiformes (carpet sharks) and to Carcharhiniformes (ground sharks). Within batoids, the Myliobatiformes formed a monophyly group while Pristiformes (sawfishes) and Rhinobatiformes (guitar fishes) formed a sister group to all other batoids.