Department of Biology, University of Florence, Florence, Italy.
Dipartimento di Scienze Chimiche, University of Naples, Napoli, Italy.
mSystems. 2023 Apr 27;8(2):e0112422. doi: 10.1128/msystems.01124-22. Epub 2023 Feb 27.
Microbial communities experience continuous environmental changes, with temperature fluctuations being the most impacting. This is particularly important considering the ongoing global warming but also in the "simpler" context of seasonal variability of sea-surface temperature. Understanding how microorganisms react at the cellular level can improve our understanding of their possible adaptations to a changing environment. In this work, we investigated the mechanisms through which metabolic homeostasis is maintained in a cold-adapted marine bacterium during growth at temperatures that differ widely (15 and 0°C). We have quantified its intracellular and extracellular central metabolomes together with changes occurring at the transcriptomic level in the same growth conditions. This information was then used to contextualize a genome-scale metabolic reconstruction, and to provide a systemic understanding of cellular adaptation to growth at 2 different temperatures. Our findings indicate a strong metabolic robustness at the level of the main central metabolites, counteracted by a relatively deep transcriptomic reprogramming that includes changes in gene expression of hundreds of metabolic genes. We interpret this as a transcriptomic buffering of cellular metabolism, able to produce overlapping metabolic phenotypes, despite the wide temperature gap. Moreover, we show that metabolic adaptation seems to be mostly played at the level of few key intermediates (e.g., phosphoenolpyruvate) and in the cross talk between the main central metabolic pathways. Overall, our findings reveal a complex interplay at gene expression level that contributes to the robustness/resilience of core metabolism, also promoting the leveraging of state-of-the-art multi-disciplinary approaches to fully comprehend molecular adaptations to environmental fluctuations. This manuscript addresses a central and broad interest topic in environmental microbiology, i.e. the effect of growth temperature on microbial cell physiology. We investigated if and how metabolic homeostasis is maintained in a cold-adapted bacterium during growth at temperatures that differ widely and that match measured changes on the field. Our integrative approach revealed an extraordinary robustness of the central metabolome to growth temperature. However, this was counteracted by deep changes at the transcriptional level, and especially in the metabolic part of the transcriptome. This conflictual scenario was interpreted as a transcriptomic buffering of cellular metabolism, and was investigated using genome-scale metabolic modeling. Overall, our findings reveal a complex interplay at gene expression level that contributes to the robustness/resilience of core metabolism, also promoting the use of state-of-the-art multi-disciplinary approaches to fully comprehend molecular adaptations to environmental fluctuations.
微生物群落不断经历环境变化,其中温度波动的影响最大。这一点非常重要,不仅考虑到正在发生的全球变暖,还考虑到海洋表面温度季节性变化这一“更简单”的情况。了解微生物在细胞水平上的反应可以帮助我们更好地理解它们可能对不断变化的环境的适应。在这项工作中,我们研究了在生长温度差异很大(15 和 0°C)的情况下,一种冷适应海洋细菌如何维持代谢稳态的机制。我们一起定量测定了其细胞内和细胞外的中心代谢组以及在相同生长条件下发生的转录组水平的变化。然后,我们将这些信息用于情境化基因组规模的代谢重建,并提供对细胞适应两种不同温度生长的系统理解。我们的研究结果表明,在主要中心代谢物水平上存在很强的代谢稳健性,但伴随着转录组的相对深度重编程,包括数百个代谢基因的表达变化。我们将其解释为细胞代谢的转录组缓冲,尽管温度差距很大,但仍能产生重叠的代谢表型。此外,我们还表明,代谢适应似乎主要发生在少数关键中间产物(例如磷酸烯醇丙酮酸)和主要中心代谢途径之间的相互作用上。总体而言,我们的研究结果揭示了基因表达水平上的复杂相互作用,有助于核心代谢的稳健性/弹性,同时也促进了利用最先进的多学科方法来全面理解微生物对环境波动的分子适应。本文涉及环境微生物学中的一个核心和广泛关注的主题,即生长温度对微生物细胞生理学的影响。我们研究了在生长温度差异很大且与野外测量变化相匹配的情况下,一种冷适应细菌如何维持代谢稳态。我们的综合方法揭示了中心代谢组对生长温度的非凡稳健性。然而,这与转录水平的深刻变化,特别是转录组的代谢部分相矛盾。这种矛盾的情况被解释为细胞代谢的转录组缓冲,并使用基因组规模的代谢建模进行了研究。总体而言,我们的研究结果揭示了基因表达水平上的复杂相互作用,有助于核心代谢的稳健性/弹性,同时也促进了利用最先进的多学科方法来全面理解微生物对环境波动的分子适应。
