Genome Analysis of Enterococcus mundtii Pe103, a Human Gut-Originated Pectinolytic Bacterium.

Pectin exists in significant amounts in vegetables and fruits as a component of the plant cell wall. In human diet, pectin is not degraded by the human digestive enzymes due to its complex structure; only gut bacteria degrade pectin in the large intestine. To date, although pectin is one of the most important sources of dietary fiber in human diet, there have been only few reports on human gut-originated pectinolytic bacteria. In this study, the strain Enterococcus mundtii Pe103, a bacterium with pectin-degrading activity, was isolated from the feces of a healthy Korean adult female. Culture experiments revealed that it could grow on pectin as the sole carbon source by degrading pectin to approximately 35% within 13 h. We report the complete genome data of human gut E. mundtii Pe103. It consists of a circular chromosome (3,084,146 bps) and two plasmids (63,713 and 56,223 bps). Genomic analysis suggested that at least nine putative enzymes related to pectin degradation are present in E. mundtii Pe103. These enzymes may be involved in the degradation of pectin. The whole genome information of E. mundtii Pe103 could improve the understanding of the mechanism underlying the degradation of pectin by human gut microbiota.

Analysis of the canine brain transcriptome with an emphasis on the hypothalamus and cerebral cortex.

The diversity of dog breeds make the domestic dog a valuable model for identifying genes responsible for many phenotypic and behavioral traits. The brain, in particular, is a region of interest for the analysis of molecular changes that are involved in dog-specific behavioral phenotypes. However, such studies are handicapped due to incomplete annotation of the dog genome. We present a high-coverage transcriptome of the dog brain using RNA-Seq. Two areas of the brain, hypothalamus and cerebral cortex, were selected for their roles in cognition, emotion, and neuroendocrine functions. We detected many novel features of the dog transcriptome, including 13,799 novel exons, 51,357 exons with unique 5' or 3' modifications, and many novel alternative splicing events. We provide some examples of novel features in genes that are related to domestication, including ADCY8, SMOC2, and PRNP. We also found 247 novel protein-coding genes and 328 noncoding RNAs, including 57 long noncoding RNAs that represent the first empirical evidence for a large fraction of noncoding RNAs in the dog. In addition, we analyze both gene expression and alternative splicing differences between the hypothalamus and cerebral cortex and find that there is very little overlap between genes that are differentially alternatively spliced and genes that are differentially expressed. We thereby suggest that researchers who want to pinpoint the genetic causes for dog breed-specific traits and diseases should not confine their studies to gene expression alone, but should consider other factors such as alternative splicing and changes in untranslated regions.