Sugar-Induced Cell Death in the Yeast S. cerevisiae Is Accompanied by the Release of Octanoic Acid, Which Does Not Originate from the Fatty Acid Synthesis Type II Mitochondrial System

Applied microbiology Pub Date : 2023-07-12 DOI:10.3390/applmicrobiol3030050

A. Avtukh, B. Baskunov, V. Keshelava, A. Valiakhmetov

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Abstract

Incubation of the yeast S. cerevisiae with glucose, in the absence of other nutrients, leads to Sugar-Induced Cell Death (SICD), accompanied by the accumulation of Reactive Oxygen Species (ROS). Yeast acidifies the environment during glucose metabolism not only as a result of the activity of the H+-ATPase of the plasma membrane but also due to the release of carboxylic acids. Acetic acid is known to induce apoptosis in growing yeast. We analyzed the composition of the incubation medium and found octanoic acid (OA) but no other carboxylic acids. Its concentration (0.675 µM) was significantly lower than the one at which OA had a toxic effect on the cell. However, the theoretically calculated concentration of OA inside the cell (about 200 μM) was found to be high enough to lead to cell necrosis. To test the hypothesis that OA might cause SICD, we used a ΔACP1 strain incapable of synthesizing OA in the yeast mitochondrial Fatty Acid Synthesis type II system (FAS-II). The deletion of the ACP1 gene did not affect the OA content in the medium. But, on the other hand, OA is a precursor of lipoic acid, which has antioxidant properties. However, strains with deleted genes for lipoic acid biosynthesis from OA (ΔPPT2, ΔLIP2, ΔLIP5, and ΔSGV3) showed no change in ROS and SICD levels. Thus, lipoic acid synthesized in FAS-II does not protect cells from ROS accumulated during SICD. We conclude that OA synthesized in the mitochondrial FAS-II system and its derivative lipoic acid are not involved in SICD in yeast S. cerevisiae.

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糖诱导的酿酒酵母细胞死亡伴随着辛酸的释放，而辛酸并非来源于脂肪酸合成II型线粒体系统

在没有其他营养物质的情况下，将酿酒酵母与葡萄糖孵育，导致糖诱导细胞死亡(SICD)，并伴有活性氧(ROS)的积累。酵母在葡萄糖代谢过程中使环境酸化，这不仅是由于质膜上H+- atp酶的活性，而且还由于羧酸的释放。醋酸可诱导生长酵母细胞凋亡。我们分析了培养培养基的组成，发现了辛酸(OA)，但没有发现其他羧酸。其浓度(0.675µM)明显低于OA对细胞产生毒性作用的浓度。然而，理论计算的细胞内OA浓度(约200 μM)高到足以导致细胞坏死。为了验证OA可能导致SICD的假设，我们在酵母线粒体脂肪酸合成II型系统(FAS-II)中使用了一株不能合成OA的ΔACP1菌株。ACP1基因的缺失不影响培养基中OA的含量。但是，另一方面，OA是硫辛酸的前体，硫辛酸具有抗氧化特性。然而，缺失OA硫辛酸生物合成基因的菌株(ΔPPT2， ΔLIP2， ΔLIP5和ΔSGV3)的ROS和SICD水平没有变化。因此，在FAS-II中合成的硫辛酸不能保护细胞免受SICD期间积累的ROS。我们认为，在线粒体FAS-II系统中合成的OA及其衍生物硫辛酸与酿酒酵母的SICD无关。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Applied microbiology

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