Toulouse Biotechnology Institute (TBI), Université de Toulouse, CNRS, INRA, INSA, Toulouse, France
Université Grenoble Alpes, Inria, Grenoble, France.
mSphere. 2020 May 20;5(3):e00276-20. doi: 10.1128/mSphere.00276-20.
Bacteria have to continuously adjust to nutrient fluctuations from favorable to less-favorable conditions and in response to carbon starvation. The glucose-acetate transition followed by carbon starvation is representative of such carbon fluctuations observed in in many environments. Regulation of gene expression through fine-tuning of mRNA pools constitutes one of the regulation levels required for such a metabolic adaptation. It results from both mRNA transcription and degradation controls. However, the contribution of transcript stability regulation in gene expression is poorly characterized. Using combined transcriptome and mRNA decay analyses, we investigated (i) how transcript stability changes in during the glucose-acetate-starvation transition and (ii) if these changes contribute to gene expression changes. Our work highlights that transcript stability increases with carbon depletion. Most of the stabilization occurs at the glucose-acetate transition when glucose is exhausted, and then stabilized mRNAs remain stable during acetate consumption and carbon starvation. Meanwhile, expression of most genes is downregulated and we observed three times less gene expression upregulation. Using control analysis theory on 375 genes, we show that most of gene expression regulation is driven by changes in transcription. Although mRNA stabilization is not the controlling phenomenon, it contributes to the emphasis or attenuation of transcriptional regulation. Moreover, upregulation of 18 genes (33% of our studied upregulated set) is governed mainly by transcript stabilization. Because these genes are associated with responses to nutrient changes and stress, this underscores a potentially important role of posttranscriptional regulation in bacterial responses to nutrient starvation. The ability to rapidly respond to changing nutrients is crucial for to survive in many environments, including the gut. Reorganization of gene expression is the first step used by bacteria to adjust their metabolism accordingly. It involves fine-tuning of both transcription (transcriptional regulation) and mRNA stability (posttranscriptional regulation). While the forms of transcriptional regulation have been extensively studied, the role of mRNA stability during a metabolic switch is poorly understood. Investigating genomewide transcriptome and mRNA stability during metabolic transitions representative of the carbon source fluctuations in many environments, we have documented the role of mRNA stability in the response to nutrient changes. mRNAs are globally stabilized during carbon depletion. For a few genes, this leads directly to expression upregulation. As these genes are regulators of stress responses and metabolism, our work sheds new light on the likely importance of posttranscriptional regulations in response to environmental stress.
细菌必须不断适应从有利条件到不利条件的营养波动,并对碳饥饿做出反应。葡萄糖-乙酸盐的转变伴随着碳饥饿,这代表了在许多环境中观察到的这种碳波动。通过精细调节 mRNA 池来调节基因表达是这种代谢适应所需的调节水平之一。它是由 mRNA 转录和降解控制共同作用的结果。然而,转录物稳定性调节在基因表达中的贡献还没有得到很好的描述。通过结合转录组和 mRNA 衰减分析,我们研究了(i)在葡萄糖-乙酸盐-饥饿转变过程中 中的转录物稳定性如何变化,以及(ii)这些变化是否有助于基因表达变化。我们的工作强调,转录物稳定性随着碳的消耗而增加。大部分稳定发生在葡萄糖耗尽时的葡萄糖-乙酸盐转变期间,然后在乙酸盐消耗和碳饥饿期间稳定的 mRNA 仍然稳定。同时,大多数基因的表达下调,我们观察到基因表达上调的倍数减少了三倍。使用 375 个基因的控制分析理论,我们表明大多数基因表达的调节是由转录变化驱动的。尽管 mRNA 稳定不是控制现象,但它有助于转录调节的强调或衰减。此外,18 个基因(我们研究的上调基因集的 33%)的上调主要由转录物稳定控制。由于这些基因与对营养变化和应激的反应有关,这突显了细菌对营养饥饿的反应中可能存在重要的转录后调节作用。快速响应不断变化的营养物质的能力对 在许多环境中生存至关重要,包括肠道。重新组织基因表达是细菌相应地调整其新陈代谢的第一步。它涉及转录(转录调节)和 mRNA 稳定性(转录后调节)的精细调整。虽然转录调节的形式已经得到了广泛的研究,但在代谢转换过程中 mRNA 稳定性的作用还知之甚少。通过研究在许多环境中代表碳源波动的代谢转换过程中的 全基因组转录组和 mRNA 稳定性,我们记录了 mRNA 稳定性在响应营养变化中的作用。在碳消耗期间,mRNA 整体上被稳定。对于一些基因,这直接导致表达上调。由于这些基因是应激反应和代谢的调节剂,我们的工作为环境应激反应中可能存在的重要转录后调节作用提供了新的视角。
