Selenium deficiency modulates necroptosis-mediated intestinal inflammation in broiler through the lncRNAWSF27/miRNA1696/GPX3 axis.

IF 2.7 2区农林科学 Q1 AGRICULTURE, DAIRY & ANIMAL SCIENCE

Journal of animal science Pub Date : 2024-09-27 DOI:10.1093/jas/skae288

Yiming Zhang,Chunyu Wei,Jiayi Ding,Jiahong Chu,Bo Huang,Guangliang Shi,Shu Li

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引用次数: 0

Abstract

Deficiency of selenium (Se), an important trace element, causes diarrhea and even death in broilers, thereby affecting the economic development of poultry production. Adding Se is one way to relieve this situation; however, it has not fundamentally resolved intestinal inflammation. Therefore, we sought a new strategy to alleviate intestinal inflammation by studying the specific mechanisms of Se deficiency. By replicating the Se-deficient broiler model and establishing a chicken small intestinal epithelial cell (CSIEC) model, we determined that Se deficiency caused intestinal oxidative stress and necroptotic intestinal inflammation in broilers by decreasing glutathione peroxidase (GPX) 3 expression. Simultaneously, the expression of long non-coding RNA (lncRNA)WSF27 decreased and that of miR-1696 increased in Se-deficient intestines. Recently discovered competing endogenous RNAs (ceRNAs) form novel regulatory networks, which were found that selenoproteins involved in ceRNA regulation. However, the mechanism of action of the non-coding RNA/GPX3 axis in Se-deficient broiler intestinal inflammation remains unclear. This study aimed to explore the mechanism through which Se deficiency regulates intestinal inflammation in broilers through the lncRNAWSF27/miR-1696/GPX3 axis. Our previous studies showed that lncRNAWSF27, miR-1696, and GPX3 have ceRNA-regulatory relationships. To further determine the role of the lncRNAWSF27/miR-1696/GPX3 axis in Se-deficient broiler intestinal inflammation, CSIEC models with GPX3 knockdown/overexpression, lncRNAWSF27 knockdown, or miR-1696 knockdown/overexpression were established to simulate intestinal injury. GPX3 knockdown, as well as lncRNAWSF27 and miR-1696 overexpression, aggravated cell damage. On the contrary, it can alleviate this situation. Our results reveal that mechanism of lncRNAWSF27/miR-1696/GPX3 regulated Se-deficient broiler intestinal inflammation. This conclusion enriches our understanding of the mechanism of intestinal injury caused by Se deficiency, and contributes to the diagnosis of Se-deficient intestinal inflammation and relevant drug development.

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缺硒通过lncRNAWSF27/miRNA1696/GPX3轴调节肉鸡坏死介导的肠道炎症。

硒（Se）是一种重要的微量元素，它的缺乏会导致肉鸡腹泻甚至死亡，从而影响家禽生产的经济发展。添加 Se 是缓解这种情况的一种方法，但并不能从根本上解决肠道炎症。因此，我们通过研究Se缺乏的特殊机制，寻求缓解肠道炎症的新策略。通过复制缺Se肉鸡模型和建立鸡小肠上皮细胞（CSIEC）模型，我们确定缺Se会通过降低谷胱甘肽过氧化物酶（GPX）3的表达，引起肉鸡肠道氧化应激和坏死性肠炎。同时，缺Se肠道中长非编码RNA（lncRNA）WSF27的表达量减少，miR-1696的表达量增加。最近发现的竞争性内源性 RNA（ceRNA）形成了新的调控网络，发现硒蛋白参与了 ceRNA 的调控。然而，非编码 RNA/GPX3 轴在缺硒肉鸡肠道炎症中的作用机制仍不清楚。本研究旨在探讨Se缺乏通过lncRNAWSF27/miR-1696/GPX3轴调控肉鸡肠道炎症的机制。我们之前的研究表明，lncRNAWSF27、miR-1696和GPX3具有ceRNA调控关系。为了进一步确定lncRNAWSF27/miR-1696/GPX3轴在Se缺陷肉鸡肠道炎症中的作用，我们建立了GPX3基因敲除/缺失表达、lncRNAWSF27基因敲除或miR-1696基因敲除/缺失表达的CSIEC模型来模拟肠道损伤。GPX3敲除以及lncRNAWSF27和miR-1696过表达会加重细胞损伤。相反，它却能缓解这种情况。我们的研究结果揭示了lncRNAWSF27/miR-1696/GPX3调控缺Se肉鸡肠道炎症的机制。这一结论丰富了我们对Se缺乏引起肠道损伤机制的认识，有助于Se缺乏性肠炎的诊断和相关药物的开发。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of animal science 农林科学-奶制品与动物科学

CiteScore

4.80

自引率

12.10%

发文量

1589

审稿时长

3 months

期刊介绍： The Journal of Animal Science (JAS) is the premier journal for animal science and serves as the leading source of new knowledge and perspective in this area. JAS publishes more than 500 fully reviewed research articles, invited reviews, technical notes, and letters to the editor each year. Articles published in JAS encompass a broad range of research topics in animal production and fundamental aspects of genetics, nutrition, physiology, and preparation and utilization of animal products. Articles typically report research with beef cattle, companion animals, goats, horses, pigs, and sheep; however, studies involving other farm animals, aquatic and wildlife species, and laboratory animal species that address fundamental questions related to livestock and companion animal biology will be considered for publication.