肝脏转录组网络揭示了与肉牛饲料效率相关的主要生物学过程。

Liver transcriptomic networks reveal main biological processes associated with feed efficiency in beef cattle.

作者信息

Alexandre Pamela A, Kogelman Lisette J A, Santana Miguel H A, Passarelli Danielle, Pulz Lidia H, Fantinato-Neto Paulo, Silva Paulo L, Leme Paulo R, Strefezzi Ricardo F, Coutinho Luiz L, Ferraz José B S, Eler Joanie P, Kadarmideen Haja N, Fukumasu Heidge

机构信息

Department of Veterinary Medicine, School of Animal Science and Food Engineering, University of Sao Paulo, Av. Duque de Caxias Norte, 225, Pirassununga, São Paulo, 13635-900, Brazil.

Department of Veterinary Clinical and Animal Sciences, Faculty of Health and Medical Sciences, University of Copenhagen, Copenhagen, Denmark.

出版信息

BMC Genomics. 2015 Dec 18;16:1073. doi: 10.1186/s12864-015-2292-8.

DOI:10.1186/s12864-015-2292-8

PMID:26678995

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4683712/

Abstract

BACKGROUND

The selection of beef cattle for feed efficiency (FE) traits is very important not only for productive and economic efficiency but also for reduced environmental impact of livestock. Considering that FE is multifactorial and expensive to measure, the aim of this study was to identify biological functions and regulatory genes associated with this phenotype.

RESULTS

Eight genes were differentially expressed between high and low feed efficient animals (HFE and LFE, respectively). Co-expression analyses identified 34 gene modules of which 4 were strongly associated with FE traits. They were mainly enriched for inflammatory response or inflammation-related terms. We also identified 463 differentially co-expressed genes which were functionally enriched for immune response and lipid metabolism. A total of 8 key regulators of gene expression profiles affecting FE were found. The LFE animals had higher feed intake and increased subcutaneous and visceral fat deposition. In addition, LFE animals showed higher levels of serum cholesterol and liver injury biomarker GGT. Histopathology of the liver showed higher percentage of periportal inflammation with mononuclear infiltrate.

CONCLUSION

Liver transcriptomic network analysis coupled with other results demonstrated that LFE animals present altered lipid metabolism and increased hepatic periportal lesions associated with an inflammatory response composed mainly by mononuclear cells. We are now focusing to identify the causes of increased liver lesions in LFE animals.

摘要

背景

选择具有饲料效率（FE）性状的肉牛不仅对生产效率和经济效益很重要，而且对减少牲畜对环境的影响也很重要。鉴于FE是多因素的且测量成本高昂，本研究的目的是确定与该表型相关的生物学功能和调控基因。

结果

在高饲料效率和低饲料效率动物（分别为HFE和LFE）之间有8个基因差异表达。共表达分析确定了34个基因模块，其中4个与FE性状密切相关。它们主要富集于炎症反应或炎症相关术语。我们还鉴定了463个差异共表达基因，其功能富集于免疫反应和脂质代谢。总共发现了8个影响FE的基因表达谱关键调节因子。LFE动物有更高的采食量以及皮下和内脏脂肪沉积增加。此外，LFE动物血清胆固醇和肝脏损伤生物标志物GGT水平更高。肝脏组织病理学显示门静脉周围炎症伴单核细胞浸润的比例更高。

结论

肝脏转录组网络分析以及其他结果表明，LFE动物存在脂质代谢改变和肝脏门静脉周围病变增加，与主要由单核细胞组成的炎症反应相关。我们目前正致力于确定LFE动物肝脏病变增加的原因。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/967a/4683712/18c411485b05/12864_2015_2292_Fig1_HTML.jpg

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肝脏转录组网络揭示了与肉牛饲料效率相关的主要生物学过程。

Liver transcriptomic networks reveal main biological processes associated with feed efficiency in beef cattle.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSION

背景

结果

结论

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