丁酸盐灌注对奶牛干期瘤胃上皮转录组学的影响。

Gene regulation and systems biology Pub Date : 2018-05-09 eCollection Date: 2018-01-01 DOI:10.1177/1177625018774798
Ransom L Baldwin, Robert W Li, Yankai Jia, Cong-Jun Li
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引用次数: 14

摘要

本研究旨在探讨丁酸盐灌注对瘤胃上皮转录组的影响。利用新一代测序技术(NGS)和生物信息学技术,在全转录组水平上加速理解丁酸盐灌注诱导干期牛瘤胃上皮转录组的调控。丁酸盐是一种能改变组蛋白乙酰化和甲基化的组蛋白去乙酰化酶(HDAC)抑制剂,是营养物质的必需元素,在调节影响瘤胃营养利用和功能的基因组活性方面发挥着重要作用。在0小时取样后(基线对照)持续瘤胃输注丁酸盐,以5.0 L/天的速率持续输注2.5 M溶液168小时。灌注168小时后,停止灌注,奶牛继续饲喂基础泌乳日粮168小时进行采样。在输注后0、24、72、168小时(D1、D3、D7)和168小时(D14),通过瘤胃瘘管连续活检收集瘤胃上皮样本。与注射前0小时相比,在严格的错误发现率(FDR)截止条件下,在不同的采样时间点至少注射一次丁酸盐,共鉴定出3513个基因在瘤胃上皮中受到影响。
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Transcriptomic Impacts of Rumen Epithelium Induced by Butyrate Infusion in Dairy Cattle in Dry Period.

The purpose of this study was to evaluate the effects of butyrate infusion on rumen epithelial transcriptome. Next-generation sequencing (NGS) and bioinformatics are used to accelerate our understanding of regulation in rumen epithelial transcriptome of cattle in the dry period induced by butyrate infusion at the level of the whole transcriptome. Butyrate, as an essential element of nutrients, is a histone deacetylase (HDAC) inhibitor that can alter histone acetylation and methylation, and plays a prominent role in regulating genomic activities influencing rumen nutrition utilization and function. Ruminal infusion of butyrate was following 0-hour sampling (baseline controls) and continued for 168 hours at a rate of 5.0 L/day of a 2.5 M solution as a continuous infusion. Following the 168-hour infusion, the infusion was stopped, and cows were maintained on the basal lactation ration for an additional 168 hours for sampling. Rumen epithelial samples were serially collected via biopsy through rumen fistulae at 0-, 24-, 72-, and 168-hour (D1, D3, D7) and 168-hour post-infusion (D14). In comparison with pre-infusion at 0 hours, a total of 3513 genes were identified to be impacted in the rumen epithelium by butyrate infusion at least once at different sampling time points at a stringent cutoff of false discovery rate (FDR) < 0.01. The maximal effect of butyrate was observed at day 7. Among these impacted genes, 117 genes were responsive consistently from day 1 to day 14, and another 42 genes were lasting through day 7. Temporal effects induced by butyrate infusion indicate that the transcriptomic alterations are very dynamic. Gene ontology (GO) enrichment analysis revealed that in the early stage of rumen butyrate infusion (on day 1 and day 3 of butyrate infusion), the transcriptomic effects in the rumen epithelium were involved with mitotic cell cycle process, cell cycle process, and regulation of cell cycle. Bioinformatic analysis of cellular functions, canonical pathways, and upstream regulator of impacted genes underlie the potential mechanisms of butyrate-induced gene expression regulation in rumen epithelium. The introduction of transcriptomic and bioinformatic technologies to study nutrigenomics in the farm animal presented a new prospect to study multiple levels of biological information to better apprehend the whole animal response to nutrition, physiological state, and their interactions. The nutrigenomics approach may eventually lead to more precise management of utilization of feed resources in a more effective approach.

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