Department of Microbiology, The Ohio State University, Columbus, Ohio, USA.
Department of Microbiology, The Ohio State University, Columbus, Ohio, USA
mBio. 2018 Apr 10;9(2):e00407-18. doi: 10.1128/mBio.00407-18.
5'-Methyl-thioadenosine (MTA) is a dead-end, sulfur-containing metabolite and cellular inhibitor that arises from adenosyl-l-methionine-dependent reactions. Recent studies have indicated that there are diverse bacterial ethionine alvage athways (MSPs) for MTA detoxification and sulfur salvage. Here, via a combination of gene deletions and directed metabolite detection studies, we report that under aerobic conditions the facultatively anaerobic bacterium employs both an MTA-isoprenoid shunt identical to that previously described in and a second novel MSP, both of which generate a methanethiol intermediate. The additional aerobic MSP, a dihydroxyacetone phosphate (DHAP)-methanethiol shunt, initially converts MTA to 2-(methylthio)ethanol and DHAP. This is identical to the initial steps of the recently reported anaerobic ethylene-forming MSP, the DHAP-ethylene shunt. The aerobic DHAP-methanethiol shunt then further metabolizes 2-(methylthio)ethanol to methanethiol, which can be directly utilized by O-acetyl-l-homoserine sulfhydrylase to regenerate methionine. This is in contrast to the anaerobic DHAP-ethylene shunt, which metabolizes 2-(methylthio)ethanol to ethylene and an unknown organo-sulfur intermediate, revealing functional diversity in MSPs utilizing a 2-(methylthio)ethanol intermediate. When MTA was fed to aerobically growing cells, the rate of volatile methanethiol release was constant irrespective of the presence of sulfate, suggesting a general housekeeping function for these MSPs up through the methanethiol production step. Methanethiol and dimethyl sulfide (DMS), two of the most important compounds of the global sulfur cycle, appear to arise not only from marine ecosystems but from terrestrial ones as well. These results reveal a possible route by which methanethiol might be biologically produced in soil and freshwater environments. Biologically available sulfur is often limiting in the environment. Therefore, many organisms have developed methionine salvage pathways (MSPs) to recycle sulfur-containing by-products back into the amino acid methionine. The metabolically versatile bacterium is unusual in that it possesses two RuBisCOs and two RuBisCO-like proteins. While RuBisCO primarily serves as the carbon fixation enzyme of the Calvin cycle, RuBisCOs and certain RuBisCO-like proteins have also been shown to function in methionine salvage. This work establishes that only one of the RuBisCO-like proteins functions as part of an MSP. Moreover, in the presence of oxygen, to salvage sulfur, employs two pathways, both of which result in production of volatile methanethiol, a key compound of the global sulfur cycle. When total available sulfur was plentiful, methanethiol was readily released into the environment. However, when sulfur became limiting, methanethiol release decreased, presumably due to methanethiol utilization to regenerate needed methionine.
5'-甲基硫代腺苷(MTA)是一种无出路的含硫代谢物和细胞抑制剂,它来源于依赖腺苷-L-甲硫氨酸的反应。最近的研究表明,存在多种细菌乙硫氨酸回收途径(MSP)来解毒 MTA 和回收硫。在这里,我们通过基因缺失和定向代谢物检测研究的结合,报告在有氧条件下,兼性厌氧细菌 既采用了先前在 中描述的 MTA-异戊烯基分流途径,又采用了第二种新的 MSP,这两种途径都产生了甲硫醇中间体。额外的有氧 MSP,即二羟丙酮磷酸(DHAP)-甲硫醇分流途径,最初将 MTA 转化为 2-(甲硫基)乙醇和 DHAP。这与最近报道的厌氧乙烯形成 MSP,即 DHAP-乙烯分流途径的初始步骤相同。然后,有氧 DHAP-甲硫醇分流途径进一步将 2-(甲硫基)乙醇代谢为甲硫醇,甲硫醇可被 O-乙酰-L-高丝氨酸硫基转移酶直接利用来再生蛋氨酸。这与厌氧 DHAP-乙烯分流途径形成鲜明对比,后者将 2-(甲硫基)乙醇代谢为乙烯和一种未知的有机硫中间产物,这表明利用 2-(甲硫基)乙醇中间产物的 MSP 具有功能多样性。当将 MTA 喂给需氧生长的细胞时,挥发性甲硫醇的释放速率是恒定的,与硫酸盐的存在与否无关,这表明这些 MSP 具有一般的管家功能,直到甲硫醇的产生步骤。甲硫醇和二甲硫醚(DMS)是全球硫循环中最重要的两种化合物,它们似乎不仅来自海洋生态系统,也来自陆地生态系统。这些结果揭示了一种可能的途径,通过该途径,甲硫醇可能在土壤和淡水环境中被生物产生。生物可利用的硫在环境中通常是有限的。因此,许多生物体已经开发出蛋氨酸回收途径(MSP),将含硫副产物回收回氨基酸蛋氨酸中。代谢多功能的细菌 很不寻常,因为它拥有两种 RuBisCO 和两种 RuBisCO 样蛋白。虽然 RuBisCO 主要作为卡尔文循环的碳固定酶,但 RuBisCO 和某些 RuBisCO 样蛋白也被证明在蛋氨酸回收中发挥作用。这项工作表明,只有一种 RuBisCO 样蛋白作为 MSP 的一部分发挥作用。此外,在氧气存在的情况下,为了回收硫, 采用了两种途径,这两种途径都导致挥发性甲硫醇的产生,甲硫醇是全球硫循环的关键化合物。当总可用硫丰富时,甲硫醇很容易释放到环境中。然而,当硫变得有限时,甲硫醇的释放减少,可能是由于甲硫醇的利用来再生所需的蛋氨酸。
