Acevedo-López José, González-Madrid Gabriela, Navarro Claudio A, Jerez Carlos A
Laboratory of Molecular Microbiology and Biotechnology, Department of Biology, Faculty of Sciences, University of Chile, Santiago 7800003, Chile.
Microorganisms. 2024 Dec 18;12(12):2627. doi: 10.3390/microorganisms12122627.
Polyphosphates are biopolymers composed of phosphate monomers linked by high-energy phosphoanhydride bonds. They are present across all life domains, serving as a source of energy, metal chelators, and playing a crucial role in stress defense. In , polyphosphates also function as inorganic molecular chaperones. The present study aims to investigate whether polyphosphate serves a similar chaperone function in archaea, using as a model organism. To this end, polyphosphate was extracted and quantified, the ADP/ATP ratio was determined, insoluble protein extracts were analyzed at different time points after copper exposure, and qPCR was performed to measure the expression of stress-related genes. PolyP was extracted after exposing the archaeon to different copper concentrations. We determined that polyP degradation is directly correlated with metal concentration. At the minimum inhibitory concentration (MIC) of 2 mM Cu, polyP degradation stabilized 2 h after exposure and showed no recovery even after 24 h. The ADP/ATP ratio was measured and showed differences in the presence or absence of polyP. The analysis of proteins precipitated under copper stress showed a higher proportion of insoluble proteins at an elevated metal concentration. On the other hand, increased protein precipitation was detected in the absence of polyP. Gene expression analysis via qPCR was conducted to assess the expression of genes involved in chaperone and chaperonin production, copper resistance, oxidative stress response, and phosphate metabolism under prolonged copper exposure, both in the presence and absence of polyP. The results indicated an upregulation of all the chaperonins measured in the presence of polyP. Interestingly, just some of these genes were upregulated in polyP's absence. Despite copper stress, there was no upregulation of superoxide dismutase in our conditions. These results highlight the role of polyP in the copper stress response in , particularly to prevent protein precipitation, likely due to its function as an inorganic chaperone. Additionally, the observed protein precipitation could be attributable to interactions between copper and some amino acids on the protein structures rather than oxidative stress induced by copper exposure, as previously described in . Our present findings provide new insights into the protective role of polyP as an inorganic chaperone in and emphasize its importance in maintaining cellular homeostasis under metal stress conditions.
多聚磷酸盐是由通过高能磷酸酐键连接的磷酸单体组成的生物聚合物。它们存在于所有生命域中,作为能量来源、金属螯合剂,并在应激防御中发挥关键作用。在古菌中,多聚磷酸盐还作为无机分子伴侣发挥作用。本研究旨在以嗜盐嗜碱古菌为模式生物,研究多聚磷酸盐在古菌中是否具有类似的伴侣功能。为此,提取并定量了多聚磷酸盐,测定了ADP/ATP比值,在铜暴露后的不同时间点分析了不溶性蛋白质提取物,并进行了qPCR以测量应激相关基因的表达。将嗜盐嗜碱古菌暴露于不同铜浓度后提取多聚磷酸盐。我们确定多聚磷酸盐的降解与金属浓度直接相关。在2 mM Cu的最小抑菌浓度(MIC)下,多聚磷酸盐降解在暴露后2小时稳定下来,即使在24小时后也没有恢复。测量了ADP/ATP比值,结果显示在有无多聚磷酸盐的情况下存在差异。对铜胁迫下沉淀的蛋白质进行分析,结果表明在金属浓度升高时不溶性蛋白质的比例更高。另一方面,在没有多聚磷酸盐的情况下检测到蛋白质沉淀增加。通过qPCR进行基因表达分析,以评估在长时间铜暴露下,无论有无多聚磷酸盐,参与伴侣蛋白和伴侣素产生、铜抗性、氧化应激反应和磷酸盐代谢的基因的表达。结果表明,在有多聚磷酸盐存在的情况下,所有测定的伴侣素均上调。有趣的是,在没有多聚磷酸盐的情况下,只有其中一些基因上调。尽管存在铜胁迫,但在我们的实验条件下超氧化物歧化酶没有上调。这些结果突出了多聚磷酸盐在嗜盐嗜碱古菌铜胁迫反应中的作用,特别是防止蛋白质沉淀,这可能归因于其作为无机伴侣的功能。此外,观察到的蛋白质沉淀可能归因于铜与蛋白质结构上的一些氨基酸之间的相互作用,而不是如先前在文献中所描述的由铜暴露诱导的氧化应激。我们目前的研究结果为多聚磷酸盐作为无机伴侣在嗜盐嗜碱古菌中的保护作用提供了新的见解,并强调了其在金属胁迫条件下维持细胞稳态的重要性。
