RESUMEN
Fish feeding habit determines the digestive tract structure and intestinal microflora. However, the relationship between feeding habit, digestive intestinal morphology, and microbial diversity of omnivorous, herbivorous, plankton feeder, and carnivorous fish from the same environment has not been compared. This study compared the digestive enzyme activities, intestinal morphology, and intestinal microflora of omnivorous (Carassius auratus), herbivorous (Ctenopharyngodon idellus), carnivorous (Siniperca chuatsi), and plankton feeder (Schizothorax grahami) fishes and predicted the potential functions of specific microflora on different nutrients. Twelve intestine samples were collected from each of the four fishes from Dianchi Lake. The composition and diversity of microbial communities were determined by using high-throughput sequencing of 16S rDNA. The results showed that the carnivorous fish (S. chuatsi) had higher trypsin and pancrelipase activities in the hepatopancreas and enteropeptidase in the intestine, but lower amylase activities in the intestine. The carnivorous fish intestine had more microvilli branches and complex structures than other fish species in the order carnivorous > herbivorous > plankton feeder > omnivorous. The intestinal microflora diversity was higher in the omnivorous fish and followed the order omnivorous > herbivorous > plankton feeder > carnivorous. Acinetobacter species and Bacteroides species were the most dominant flora in the carnivorous and herbivorous fishes, respectively. Acinetobacter species and Pseudomonas species might help the host to digest protein, while Bacteroidetes species may help the host to digest cellulose. Taken together, feeding habit determines the digestive enzyme activities, intestinal tissue morphology, and differential colonization of fish intestinal flora. The knowledge obtained is useful in feed formulation and feeding practices for the studied fish species.
RESUMEN
In November 2009, scientists from the US, UK, and other countries announced the complete genome sequence draft of the domestic pig. With the release of improved versions of the pig genome assembly and the increase of correctly assembled sequenced fragments over the past two years, it is particularly urgent to have the pig genes annotated at whole-genome level. This article is aimed at introducing an excellent manual annotation tool, Otterlace software, developed by Sanger institute. We used CFL1 (Cofilin 1) gene as an example to expound the usage of the three main components of Otterlace, Zmap, Blixem, and Dotter tools, and developed a practical procedure for manual annotations. We have analyzed 243 immune-related genes, among which 180 genes have been completely or partially annotated, offering novel information to the porcine functional genomics.