热应激对奶牛GNAS启动子区DNA甲基化水平的影响

doi:10.3864/j.issn.0578-1752.2023.12.013

Abstract

Abstract:

【Objective】Heat stress has seriously impaired the production and health of dairy cows, causing the subsequent limitation in sustainable development of dairy industry. DNA methylation is an important epigenetic regulatory mechanism involved in an animal’s heat stress response, but the potential functions and molecular mechanisms of which are not clear. The current study was conducted to detect the DNA methylation related to heat stress in dairy cows and to identify target genes related to DNA methylation, so as to provide a better insight into the epigenetics mechanism of heat stress in dairy cows.【Method】In the study, 24 Chinese Holstein lactation cows (same lactation stage and same parity) in Sanyuan dairy farm were used for the blood samples collection in heat stress period (July in the summer of 2017) and non-heat stress period (April in spring 2017), respectively, followed by DNA extraction. To explore the DNA methylation differences in dairy cows from different heat stress period, 15 of 24 animals were randomly assigned to 3 groups (N=5 animals/group), 5 DNA samples in one group were mixed together to get a single pooled DNA sample, thus 6 pooled DNA samples including 3 from spring and 3 from summer were used for the DNA methylation detection by the whole-genome bisulfite sequencing (WGBS), then the differential methylation region (DMR; 1000 bp windows, 500 bp overlap, P<0.05) and key gene were identified. PROMO and Methprimer software were used to predict transcription factor binding sites and CpG islands, respectively. Then, the bovine mammary gland epithelial cells (Mac-T) were treated at 39 ℃ for 24 h, 48 h, and 72 h, and the cell viability were detected by MTT method. Finally, using the bisulfite sequencing PCR (BSP), the methylation levels of target gene promoter in 24 dairy cows in spring and summer and Mac-T cells treated in 39 ℃ were examined, respectively. 【Result】Based on the DNA methylation analysis of WGBS data, 49 861 differential methylation regions (DMRs) associated with heat stress were identified. One of DMRs was attributed to the promoter area of GNAS complex locus (GNAS), whose methylation level significantly increased in heat-stressed animals (P<0.001). Also, there was a 352 bp CpG island in the promoter of GNAS containing potential binding sites for Sp1, C/EBP and other important transcription factors. Further the methylation status of the GNAS gene promoter region in heat stressed dairy cows were verified by BSP, and the average methylation level in all cytosine of 31 CpG sites was higher in heat stress cows than that in control groups (P<0.05), which corresponding to the above WGBS results. Moreover, the 21 (-113 bp, Chr13:57532733) and 27 (-63 bp, Chr13:57532683) CpG sites showed significant differences between the spring and summer groups (P<0.05). In Mac-T cells, after 48 h and 72 h heat treatment, the cell viability decreased significantly (P<0.01), but the overall CG methylation level of 31 CpG sites in the GNAS gene promoter region increased significantly (P<0.05), and also the similar significant methylation changes appeared in the site 21 and 27 CpG in cell. 【Conclusion】 Heat stress increased the methylation levels of the promoter region of the GNAS in dairy cows as well as in cells, which indicated that GNAS was a potential target gene regulated DNA methylation in heat stress response of dairy cows.

Key words: heat stress, dairy cows, WGBS, DNA methylation, GNAS

CHEN YuMei, ZHANG CongCong, HU LiRong, FANG Hao, DOU JinHuan, GUO Gang, WANG Yan, LIU QiaoXiang, WANG YaChun, XU Qing. Effect of Heat Stress on DNA Methylation of GNAS Promoter Region in Dairy Cows[J].Scientia Agricultura Sinica, 2023, 56(12): 2395-2406.

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引物名称 Primer name	引物序列 Primer sequence	产物长度 The length of product (bp)
外侧引物 Outer primer	F：5′-GTTTGAGATTATTTTTTTTTAATTATAAT-3′	676
外侧引物 Outer primer	R：5′-AAAAACACCTACCTTCCTAACCACTCAACT-3′	676
内侧引物 Inner primer	F：5′-AGTTTTTGGAAAATGTTTTGGATTGGAT-3′	598
内侧引物 Inner primer	R：5′-CCTCTACTTACCACTCTAAACAT-3′	598

Effect of Heat Stress on DNA Methylation of GNAS Promoter Region in Dairy Cows

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