利用血液转录组分析确定大熊猫免疫和代谢随年龄的变化。

Using Blood Transcriptome Analysis to Determine the Changes in Immunity and Metabolism of Giant Pandas with Age.

作者信息

Liu Song, Li Caiwu, Yan Wenjun, Jin Senlong, Wang Kailu, Wang Chengdong, Gong Huiling, Wu Honglin, Fu Xue, Deng Linhua, Lei Changwei, He Ming, Wang Hongning, Cheng Yanxi, Wang Qian, Lin Shanshan, Huang Yan, Li Desheng, Yang Xin

机构信息

Key Laboratory of Bio-Resource and Eco-Environment of Ministry of Education, Animal Disease Prevention and Food Safety Key Laboratory of Sichuan Province, College of Life Sciences, Sichuan University, Chengdu 610017, China.

China Conservation and Research Center for the Giant Panda, Key Laboratory of State Forestry and Grassland Administration on Conservation Biology of Rare Animals in the Giant Panda National Park, Chengdu 610083, China.

出版信息

Vet Sci. 2022 Nov 30;9(12):667. doi: 10.3390/vetsci9120667.

DOI:10.3390/vetsci9120667

PMID:36548828

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9784451/

Abstract

A low reproductive rate coupled with human activities has endangered the giant panda, a species endemic to southwest China. Although giant pandas feed almost exclusively on bamboo, they retain carnivorous traits and suffer from carnivorous diseases. Additionally, their immune system is susceptible to aging, resulting in a reduced ability to respond to diseases. This study aimed to determine the genes and pathways expressed differentially with age in blood tissues. The differentially expressed genes in different age groups of giant pandas were identified by RNA-seq. The elderly giant pandas had many differentially expressed genes compared with the young group (3 years old), including 548 upregulated genes and 401 downregulated genes. Further, functional enrichment revealed that innate immune upregulation and adaptive immune downregulation were observed in the elderly giant pandas compared with the young giant pandas. Meanwhile, the immune genes in the elderly giant pandas changed considerably, including genes involved in innate immunity and adaptive immunity such as PLSCR1, CLEC7A, CCL5, CCR9, and EPAS1. Time series analysis found that giant pandas store glycogen by prioritizing fat metabolism at age 11, verifying changes in the immune system. The results reported in this study will provide a foundation for further research on disease prevention and the energy metabolism of giant pandas.

摘要

低繁殖率加上人类活动已使大熊猫这一中国西南部特有的物种濒临灭绝。尽管大熊猫几乎完全以竹子为食，但它们仍保留着肉食性特征，并患有肉食性疾病。此外，它们的免疫系统易受衰老影响，导致应对疾病的能力下降。本研究旨在确定血液组织中随年龄差异表达的基因和通路。通过RNA测序鉴定了不同年龄组大熊猫的差异表达基因。与幼年组（3岁）相比，老年大熊猫有许多差异表达基因，包括548个上调基因和401个下调基因。此外，功能富集分析显示，与幼年大熊猫相比，老年大熊猫出现固有免疫上调和适应性免疫下调。同时，老年大熊猫的免疫基因发生了显著变化，包括参与固有免疫和适应性免疫的基因，如PLSCR1、CLEC7A、CCL5、CCR9和EPAS1。时间序列分析发现，大熊猫在11岁时通过优先进行脂肪代谢来储存糖原，这证实了免疫系统的变化。本研究报告的结果将为进一步研究大熊猫的疾病预防和能量代谢提供基础。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3b6b/9784451/2d1b0239b4d5/vetsci-09-00667-g001.jpg

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利用血液转录组分析确定大熊猫免疫和代谢随年龄的变化。

Using Blood Transcriptome Analysis to Determine the Changes in Immunity and Metabolism of Giant Pandas with Age.

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