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共表达、保守基因和基因家族的综合分析揭示了多年生荒漠旱生植物松叶猪毛菜热胁迫响应的核心调控网络。

Integrated analysis of co-expression, conserved genes and gene families reveal core regulatory network of heat stress response in Cleistogenes songorica, a xerophyte perennial desert plant.

作者信息

Yan Qi, Zong Xifang, Wu Fan, Li Jie, Ma Tiantian, Zhao Yufeng, Ma Qian, Wang Penglei, Wang Yanrong, Zhang Jiyu

机构信息

State Key Laboratory of Grassland Agro-ecosystems, Key Laboratory of Grassland Livestock Industry Innovation, Engineering Research Center of Grassland Industry, Ministry of Education, College of Pastoral Agriculture Science and Technology, Lanzhou University, Lanzhou, 730020, People's Republic of China.

出版信息

BMC Genomics. 2020 Oct 16;21(1):715. doi: 10.1186/s12864-020-07122-8.

DOI:10.1186/s12864-020-07122-8
PMID:33066732
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7566159/
Abstract

BACKGROUND

As global warming continues, heat stress (HS) is becoming an increasingly significant factor limiting plant growth and reproduction, especially for cool-season grass species. The objective of this study was to determine the transcriptional regulatory network of Cleistogenes songorica under HS via transcriptome profiling, identify of gene families and comparative analysis across major Poaceae species.

RESULTS

Physiological analysis revealed significantly decreased leaf relative water content (RWC) but increased proline (Pro) content in C. songorica under 24 h of HS. Transcriptome profiling indicated that 16,028 and 14,645 genes were differentially expressed in the shoots and roots of C. songorica under HS, respectively. Two subgenomes of C. songorica provide equal contribution under HS on the basis of the distribution and expression of differentially expressed genes (DEGs). Furthermore, 216 DEGs were identified as key evolutionarily conserved genes involved in the response to HS in C. songorica via comparative analysis with genes of four Poaceae species; these genes were involved in the 'response to heat' and 'heat acclimation'. Notably, most of the conserved DEGs belonged to the heat-shock protein (HSP) superfamily. Similar results were also obtained from co-expression analysis. Interestingly, hub-genes of co-expression analysis were found to overlap with conserved genes, especially heat-shock protein (HSP). In C. songorica, 84 HSP and 32 heat-shock transcription factor (HSF) genes were identified in the allotetraploid C. songorica genome, and might have undergone purifying selection during evolutionary history based on syntenic and phylogenetic analysis. By analysing the expression patterns of the CsHSPs and CsHSFs, we found that the transcript abundance of 72.7% of the CsHSP genes and of 62.5% of the CsHSF genes changed under heat stress in both the shoots and roots. Finally, a core regulatory network of HS was constructed on the basis of the CsHSP, CsHSF and other responsive genes in C. songorica.

CONCLUSIONS

Regulatory network and key genes were comprehensively analysed and identified in C. songorica under HS. This study improves our knowledge of thermotolerance mechanisms in native grasses, and also provides candidate genes for potential applications in the genetic improvement of grasses.

摘要

背景

随着全球变暖持续,热胁迫(HS)正成为限制植物生长和繁殖的一个日益重要的因素,尤其是对于冷季型草种而言。本研究的目的是通过转录组分析确定热胁迫下蒙古冰草的转录调控网络,鉴定基因家族并对主要禾本科物种进行比较分析。

结果

生理分析表明,在24小时热胁迫下,蒙古冰草叶片相对含水量(RWC)显著降低,但脯氨酸(Pro)含量增加。转录组分析表明,热胁迫下蒙古冰草地上部和根部分别有16,028个和14,645个基因差异表达。基于差异表达基因(DEGs)的分布和表达情况,蒙古冰草的两个亚基因组在热胁迫下贡献相当。此外,通过与四个禾本科物种的基因进行比较分析,在蒙古冰草中鉴定出216个差异表达基因作为参与热胁迫响应的关键进化保守基因;这些基因参与“热响应”和“热驯化”。值得注意的是,大多数保守的差异表达基因属于热休克蛋白(HSP)超家族。共表达分析也得到了类似结果。有趣的是,共表达分析的枢纽基因被发现与保守基因重叠,尤其是热休克蛋白(HSP)。在蒙古冰草的异源四倍体基因组中鉴定出84个HSP和32个热休克转录因子(HSF)基因,基于共线性和系统发育分析,这些基因在进化历史中可能经历了纯化选择。通过分析CsHSPs和CsHSFs的表达模式,我们发现72.7%的CsHSP基因和62.5%的CsHSF基因的转录丰度在地上部和根部的热胁迫下均发生了变化。最后,基于蒙古冰草中的CsHSP、CsHSF和其他响应基因构建了热胁迫的核心调控网络。

结论

对热胁迫下蒙古冰草的调控网络和关键基因进行了全面分析和鉴定。本研究增进了我们对本地草耐热机制的了解,也为草类遗传改良的潜在应用提供了候选基因。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/10f0/7566159/f75b1727c264/12864_2020_7122_Fig6_HTML.jpg
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3
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4
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