Project description:This study aimed to explore the changes in miRNAome in the rumen epithelium during diet transition from forage to high-grain and the modulation through supplementation with phytogenic feed additives (PHY).

Project description:Feed regimens have a pivotal role in modulating the transcriptional programs that, in turns, have an impact on many biological processes, including metabolism, health and development. Green feed diet in ruminant exerts a beneficial effect on rumen metabolism and enhances the content of health-promoting biomolecules in the milk. However, a comprehensive analysis focused to the identification of genes, and therefore, biological processes modulated by the green feed diet in buffalo rumen has never been reported so far. In this regard, to highlight the impact of the green feed diet on ruminal transcriptomic profiles, we performed RNA-sequencing in buffaloes fed a total mixed ratio (TMR) + the inclusion of 30% of ryegrass green feed (treated group) in comparison with buffaloes fed a dry TMR diet (control group).

Project description:Given that different diets could alter cow milk yield and composition, the effects of different feed formula on milk extracellular vesicle (EV) miRNAs were detected. Cow milk EVs contained various small RNAs, including miRNAs, snRNAs, tiRNAs, Cis-regulatory elements, and piRNAs. Two hundred and seventy-six known bos taurus miRNAs were identified by sequencing in bovine milk EVs. There were 13 immune-related miRNAs in the top 20 miRNAs in milk EVs. Nine differently expressed known miRNAs were detected in responding to different feed formulations. Cow milk EVs are abundant of small RNAs, especially miRNAs, which might be closely related to the development of maternal mammary gland and neonatal immune maturity.

Project description:In this study, we studied the fibrolytic potential of the rumen microbiota in the rumen of 6 lambs separated from their dams from 12h of age and artificially fed with milk replacer (MR) and starter feed from d8, in absence (3 lambs) or presence (3 lambs) of a combination of the live yeast Saccharomyces cerevisiae CNCM I-1077 and selected yeast metabolites. The fibrolytic potential of the rumen microbiota of the lambs at 56 days of age was analyzed with a DNA microarray (FibroChip) targeting genes coding for 8 glycoside hydrolase (GH) families.

Project description:Aristolochic acid (AA) is an active component of herbal drugs derived from the Aristolochia species that have been used for medicinal purposes since antiquity. However, AA is genotoxic and induces tumors in animals and humans. AA induces mutations and tumors in the kidney but solely mutations in the liver. To evaluate whether miRNAs could indicate AA’s tissue-specific carcinogenicity and mutagenicity, we first conducted microarray analysis of miRNA expression in kidneys and livers of rats treated with a carcinogenic dose of AA. Then, miR-21, a biomarker for carcinogenicity, and miR-34a, a biomarker for mutagenicity, the two miRNAs whose expressions were most altered, were evaluated for their expression in the kidney (the AA’s mutagenic and carcinogenic target tissue), liver (the AA’s mutagenic target tissue), and testis, the non-target tissue where neither tumors nor mutation induction was found in previous studies and in this study. Genomic analysis of miRNA expression for kidney and liver samples showed that miRNA expression was globally changed by the treatment. Nineteen miRNAs were significantly dysregulated by the treatment in the kidney. Most of these miRNAs are related to carcinogenesis. Only one miRNA, miR-34a, was differentially expressed in the liver. Expression of miR-21 was induced in the kidney by AA treatment in a dose-dependent manner while no changes occurred in the liver or testis, indicating that the kidney is the carcinogenic target. miR-34a was dose-dependently up-regulated in the kidneys and livers of rats treated with AA, but not in the testis, suggesting that the kidney and liver are mutagenic target tissues, but the testis is not. Our results demonstrate that miRNA profiles can reflect the AA’s carcinogenicity in a tissue-specific manner while specific miRNAs can signify the target tissues for carcinogenicity or mutagenicity of AA.

Project description:Very little is known about miRNAs found in breastmilk cells, which also reflect the cells of the lactating mammary epithelium. Our hypothesis is that breastmilk cells are richer in miRNA compared to other milk fractions, such as skim milk. Further, the effects of milk removal by the infant on milk cell miRNA content and/or composition have not been investigated. Breastmilk cells conserved higher miRNA content than previously published lipid and skim fractions of breastmilk as well as other known sources of miRNA in humans. Specifically, 1,467 known mature miRNAs were identified and a further 1996 novel miRNAs, of which 89 were highly expressed. As previously shown, post-feed milk contained more cells than pre-feed milk, and the same was observed for miRNA content. However, no statistically significant difference was found in the expression of the total known and novel miRNAs between pre- and post-feed milk (p=0.76), although 27 known miRNAs and 1 novel miRNA were higher expressed in post-feed milk. As expected, samples richer in viable cells contained more known miRNAs (p = 0.01). Functional analysis of the top 10 most highly expressed known miRNAs showed that they may be potentially involved in crucial roles for the infant, including body fluid balance, thirst, appetite, immune responses, and development. In conclusion, breastmilk is highly rich in miRNA which may play important functions in the breastfed infant and the lactating breast. Milk removal by the infant can influence the total miRNA content of breastmilk, similar to its cell and fat content, but the miRNA composition remains constant

Project description:This study aimed to explore the changes in miRNAome in the rumen fluid during diet transition from forage to high-grain.

Project description:We assessed the transcriptomic adaptation of the calf rumen epithelium to changes in ruminal pH caused by feeding calf starter with and without forage during weaning transition. The calves were divided into a gorage provision group (HAY group, n = 3) and forage non-provision group (CON group, n = 4) 3 weeks after weaning.

Project description:MicroRNAs are important regulators of cell-autonomous gene expression that influences many biological processes. They are also released from cells and are present in virtually all body fluids, including blood, urine, saliva, sweat, and milk. The functional role of extracellular miRNAs is controversial, and irrefutable demonstration of miRNA uptake by cells and canonical miRNA function is still lacking. Here we show that miRNAs are present at high levels in milk of lactating mice. To investigate intestinal uptake of miRNAs in newborn mice, we employed genetic models in which newborn miR-375 and miR-200c KO mice received milk from wildtype foster mothers. Analysis of intestinal epithelium, blood, liver and spleen revealed no evidence for miRNA uptake. miR-375 levels in hepatocytes were at the limit of detection and remained orders of magnitude below the threshold for target gene regulation (between 1000 and 10,000 copies/cell). Furthermore, our study revealed rapid degradation of milk miRNAs in the intestinal fluid. Together, our results indicate a nutritional rather than gene regulatory role of miRNAs in milk of newborn mice.

Project description:We assessed the transcriptomic adaptation of the calf rumen epithelium to changes in ruminal pH caused by feeding calf starter with and without forage during weaning transition.