ABSTRACT
Traumatic brain injuries (TBI) manifest into post-traumatic stress disorders such as anxiety comorbid with gut ailments. Theperturbations in gut microbial communities are often linked to intestinal and neuropsychological disorders. We havepreviously reported anxiety and abnormalities in gut function in mild TBI (MTBI)-exposed rats. The current studydemonstrates the changes in gut microbiome of MTBI-exposed animals and discusses its implications in intestinal healthand behaviours. The rats were subjected to repeated MTBI (rMTBI) and microbial composition in jejunum was examinedafter 6 h, 48 h and 30 days of rMTBI. Significant reduction in bacterial diversity was observed in the rMTBI-exposedanimals at all the time points. Principal coordinate analysis based on weighted UniFrac distances indicated substantialdifferences in gut microbial diversity and abundances in rMTBI-exposed animals as compared to that in healthy controls.The abundance of Proteobacteria increased dramatically with reciprocal decrease in Firmicutes after rMTBI. At the genuslevel, Helicobacter, Lactobacillus, Campylobacter, and Streptococcus were found to be differentially abundant in thejejunum of rMTBI-exposed rats as compared to sham controls indicating profound dysbiosis from the healthy state.Furthermore, substantial depletion in butyrate-producing bacterial communities was observed in rMTBI-exposed animals.These results suggest that the traumatic stress alters the gut microbiome with possible implications in gut health andneuropsychopathology.
ABSTRACT
Microbial community structure of crude petroleum oil (CP)- and refined petroleum oil (RP)-contaminated soil wasinvestigated. The taxonomical and functional diversity of such soils can be a great source of information about microbialcommunity and genes involved in petroleum hydrocarbon (PHC) degradation. In this study, microbial diversity of soilscontaminated by RP from urban biome of Pune, India, and CP from agricultural biome of Gujarat, India, were assessed by16S rRNA amplicon sequencing on Illumina MiSeq platform. Association between the soil microbial community and thephysicochemical parameters were investigated for their potential role. In RP- and CP-contaminated soils, the microbiomeanalysis showed Proteobacteria as most dominant phylum followed by Actinobacteria. Interestingly, Firmicutes were mostprevailing in a CP-contaminated sample while they were least prevailing in RP-contaminated soils. Soil moisture content,total organic carbon and organic nitrogen content influenced the taxa diversity in these soils. Species richness was more inRP as compared to CP soils. Further prediction of metagenome using PICRUSt revealed that the RP and CP soils containmicrobial communities with excellent metabolic potential for PHC degradation. Microbial community contributing to genesessential for soil health improvement and plant growth promotion was also gauged. Our analysis showed promising resultsfor future bioaugmentation assisted phytoremediation (BAP) strategies for treating such soils.
ABSTRACT
Ayurveda is one of the ancient systems of medicine which is widely practised as a personalized scientific approach towardsthe general wellness. Ayurvedic prakriti is broadly defined as the phenotypes which are determined on the basis of physical,psychological and physiological traits irrespective of their social, ethnic, dietary and geographical stature. Prakriti is theconstitution of a person, which comprises vata, pitta, and kapha and is a key determinant of how one individual is differentfrom the other. Human microbiome is considered the ‘latest discovered’ human organ and microbiome research reiteratesthe fundamental principles of Ayurveda for creating a healthy gut environment by maintaining the individual-specificmicrobiome. Hence, it is important to understand the association of human microbiome with the Ayurvedic prakriti of anindividual. Here, we provide a comprehensive analysis of human microbiome from the gut, oral and skin samples of healthyindividuals (n=18) by 16S rRNA gene-based metagenomics using standard QIIME pipeline. In the three different prakritisamples differential abundance of Bacteroides, Desulfovibrio, Parabacteroides, Slackia, and Succinivibrio was observed inthe gut microbiome. Analysis also revealed prakriti-specific presence of Mogibacterium, Propionibacterium, Pyramidobacter, Rhodococcus in the kapha prakriti individuals Planomicrobium, Hyphomicrobium, Novosphingobium in the pittaprakriti individuals and Carnobacterium, Robiginitalea, Cetobacterium, Psychrobacter in the vata prakriti individuals.Similarly, the oral and skin microbiome also revealed presence of prakriti-specific differential abundance of diversebacterial genera. Prakriti-specific presence of bacterial taxa was recorded and only 42% microbiome in the oral samples and52% microbiome in the skin samples were shared. Bacteria known for preventing gut inflammation by digesting theresistant starch were abundant in the pitta prakriti individuals, who are more prone to develop gut-inflammation-relateddisorders. In summary, human gut, oral and skin microbiome showed presence
ABSTRACT
Germ band retraction (GBR) stage is one of the important stages during insect development. It is associated with an extensive epithelial morphogenesis and may also be pivotal in generation of morphological diversity in insects. Despite its importance, only a handful of studies report the transcriptome repertoire of this stage in insects. Here, we report generation, annotation and analysis of ESTs from the embryonic stage (16–22 h post fertilization) of laboratoryreared Anopheles stephensi mosquitoes. A total of 1002 contigs were obtained upon clustering of 1140 high-quality ESTs, which demonstrates an astonishingly low transcript redundancy (12.1%). Putative functions were assigned only to 213 contigs (21%), comprising mainly of transcripts encoding protein synthesis machinery. Approximately 78% of the transcripts remain uncharacterized, illustrating a lack of sequence information about the genes expressed in the embryonic stages of mosquitoes. This study highlights several novel transcripts, which apart from insect development, may significantly contribute to the essential biological complexity underlying insect viability in adverse environments. Nonetheless, the generated sequence information from this work provides a comprehensive resource for genome annotation, microarray development, phylogenetic analysis and other molecular biology applications in entomology.
ABSTRACT
Obesity is a consequence of a complex interplay between the host genome and the prevalent obesogenic factors among the modern communities. The role of gut microbiota in the pathogenesis of the disorder was recently discovered; however, 16S-rRNA-based surveys revealed compelling but community-specific data. Considering this, despite unique diets, dietary habits and an uprising trend in obesity, the Indian counterparts are poorly studied. Here, we report a comparative analysis and quantification of dominant gut microbiota of lean, normal, obese and surgically treated obese individuals of Indian origin. Representative gut microbial diversity was assessed by sequencing fecal 16S rRNA libraries for each group (n=5) with a total of over 3000 sequences. We detected no evident trend in the distribution of the predominant bacterial phyla, Bacteroidetes and Firmicutes. At the genus level, the bacteria of genus Bacteroides were prominent among the obese individuals, which was further confirmed by qPCR (P<0.05). In addition, a remarkably high archaeal density with elevated fecal SCFA levels was also noted in the obese group. On the contrary, the treated-obese individuals exhibited comparatively reduced Bacteroides and archaeal counts along with reduced fecal SCFAs. In conclusion, the study successfully identified a representative microbial diversity in the Indian subjects and demonstrated the prominence of certain bacterial groups in obese individuals; nevertheless, further studies are essential to understand their role in obesity.