In silico analysis of functional nsSNPs in human TRPC6 gene associated with steroid resistant nephrotic syndrome.

The aim of the present study is to identify functional non-synonymous SNPs of TRPC6 gene using various in silico approaches. These SNPs are believed to have a direct impact on protein stability through conformation changes. Transient receptor potential cation channel-6 (TRPC6) is one of the proteins that plays a key role causing focal segmental glomerulosclerosis (FSGS) associated with the steroid-resistant nephritic syndrome (SRNS). Data of TRPC6 was collected from dbSNP and further used to investigate a damaging effect using SIFT, PolyPhen, PROVEAN, and PANTHER. The comparative analysis predicted that two functional SNPs "rs35857503 at position N157T and rs36111323 at position A404V" showed a damaging effect (score of 0.096-1.00).We modeled the 3D structure of TRPC6 using a SWISS-MODEL workspace and validated it via PROCHECK to get a Ramachandran plot (83.0% residues in the most favored region, 12.7% in additionally allowed regions, 2.3% in a generously allowed region and 2.0% were in a disallowed region). QMEAN (0.311) and MUSTER (10.06) scores were under acceptable limits. Putative functional SNPs that may possibly undergo post-translation modifications were also identified in TRPC6 protein. It was found that mutation at N157T can lead to alteration in glycation whereas mutation at A404V was present at a ligand binding site. Additionally, I-Mutant showed a decrease in stability for these nsSNPs upon mutation, thus suggesting that the N157T and A404V variants of TRPC6 could directly or indirectly destabilize the amino acid interactions causing functional deviations of protein to some extent.

Bacterial diversity dynamics associated with different diets and different primer pairs in the rumen of Kankrej cattle.

The ruminal microbiome in herbivores plays a dominant role in the digestion of lignocellulose and has potential to improve animal productivity. Kankrej cattle, a popular native breed of the Indian subcontinent, were used to investigate the effect of different dietary treatments on the bacterial diversity in ruminal fractions using different primer pairs. Two groups of four cows were assigned to two primary diets of either dry or green forages. Each group was fed one of three dietary treatments for six weeks each. Dietary treatments were; K1 (50% dry/green roughage: 50% concentrate), K2 (75% dry/green roughage: 25% concentrate) and K3 (100% dry/green roughage). Rumen samples were collected using stomach tube at the end of each dietary period and separated into solid and liquid fractions. The DNA was extracted and amplified for V1-V3, V4-V5 and V6-V8 hypervariable regions using P1, P2 and P3 primer pairs, sequenced on a 454 Roche platform and analyzed using QIIME. Community compositions and the abundance of most bacterial lineages were driven by interactions between primer pair, dietary treatment and fraction. The most abundant bacterial phyla identified were Bacteroidetes and Firmicutes however, the abundance of these phyla varied between different primer pairs; in each primer pair the abundance was dependent on the dietary treatment and fraction. The abundance of Bacteroidetes in cattle receiving K1 treatment indicate their diverse functional capabilities in the digestion of both carbohydrate and protein while the predominance of Firmicutes in the K2 and K3 treatments signifies their metabolic role in fibre digestion. It is apparent that both liquid and solid fractions had distinct bacterial community patterns (P<0.001) congruent to changes in the dietary treatments. It can be concluded that the P1 primer pair flanking the V1-V3 hyper-variable region provided greater species richness and diversity of bacterial populations in the rumen of Kankrej cattle.