The ESCRT-III complex contributes to macromitophagy in yeast.

IF 3.6 3区 生物学 Q3 CELL BIOLOGY Traffic Pub Date : 2021-08-01 Epub Date: 2021-06-16 DOI:10.1111/tra.12805
Zulin Wu, Haiqian Xu, Junze Liu, Fan Zhou, Yongheng Liang
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引用次数: 3

Abstract

Mitochondria play important roles in energy generation and homeostasis maintenance in eukaryotic cells. The damaged or superfluous mitochondria can be nonselectively or selectively removed through the autophagy/lysosome pathway, which was referred as mitophagy. According to the molecular machinery for degrading mitochondria, the selectively removed mitochondria can occur through macromitophagy or micromitophagy. In this study, we show that the endosomal sorting complex required for transport III (ESCRT-III) in budding yeast regulates macromitophagy induced by nitrogen starvation, but not by the post-logarithmic phase growth in lactate medium by monitoring a mitochondrial marker, Om45. Firstly, loss of ESCRT-III subunit Snf7 or Vps4-Vta1 complex subunit Vps4, two representative subunits of the ESCRT complex, suppresses the delivery and degradation of Om45-GFP to vacuoles. Secondly, we show that the mitochondrial marker Om45 and mitophagy receptor Atg32 accumulate on autophagosomes marked with Atg8 (mitophagosomes, MPs) in ESCRT mutants. Moreover, the protease-protection assay indicates that Snf7 and Vps4 are involved in MP closure. Finally, Snf7 interacts with Atg11, which was detected by two ways, glutathione-S-transferase (GST) pulldown and bimolecular fluorescence complementation (BiFC) assay, and this BiFC interaction happens on mitochondrial reticulum. Therefore, we proposed that the ESCRT-III machinery mediates nitrogen starvation-induced macromitophagy by the interaction between Snf7 and Atg11 so that Snf7 is recruited to Atg32-marked MPs by the known Atg11-Atg32 interaction to seal them. These results reveal that the ESCRT-III complex plays a new role in yeast on macromitophagy.

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ESCRT-III复合体有助于酵母的巨噬细胞。
线粒体在真核细胞的能量产生和稳态维持中起着重要的作用。受损或多余的线粒体可以通过自噬/溶酶体途径非选择性或选择性地去除,这被称为线粒体自噬。根据线粒体降解的分子机制,选择性去除的线粒体可通过巨丝自噬或微丝自噬两种方式发生。在这项研究中,我们通过监测线粒体标记物Om45,发现出芽酵母中运输III所需的内体分选复合体(ESCRT-III)调节氮饥饿诱导的巨噬细胞,而不是乳酸培养基中对数期后生长的巨噬细胞。首先,ESCRT复合物的两个代表性亚基ESCRT- iii亚基Snf7或Vps4- vta1复合物亚基Vps4的缺失会抑制Om45-GFP向液泡的传递和降解。其次,我们发现在ESCRT突变体中,线粒体标记物Om45和线粒体自噬受体Atg32在标记有Atg8(线粒体自噬体,MPs)的自噬体上积累。此外,蛋白酶保护实验表明Snf7和Vps4参与了MP的关闭。最后,Snf7与Atg11相互作用,通过谷胱甘肽- s -转移酶(GST)下拉和双分子荧光互补(BiFC)两种方法检测,这种BiFC相互作用发生在线粒体网上。因此,我们提出ESCRT-III机制通过Snf7和Atg11之间的相互作用介导氮饥饿诱导的巨噬,从而Snf7通过已知的Atg11- atg32相互作用被招募到atg32标记的MPs中以封闭它们。这些结果表明ESCRT-III复合物在酵母巨噬细胞中发挥了新的作用。
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来源期刊
Traffic
Traffic 生物-细胞生物学
CiteScore
8.10
自引率
2.20%
发文量
50
审稿时长
2 months
期刊介绍: Traffic encourages and facilitates the publication of papers in any field relating to intracellular transport in health and disease. Traffic papers span disciplines such as developmental biology, neuroscience, innate and adaptive immunity, epithelial cell biology, intracellular pathogens and host-pathogen interactions, among others using any eukaryotic model system. Areas of particular interest include protein, nucleic acid and lipid traffic, molecular motors, intracellular pathogens, intracellular proteolysis, nuclear import and export, cytokinesis and the cell cycle, the interface between signaling and trafficking or localization, protein translocation, the cell biology of adaptive an innate immunity, organelle biogenesis, metabolism, cell polarity and organization, and organelle movement. All aspects of the structural, molecular biology, biochemistry, genetics, morphology, intracellular signaling and relationship to hereditary or infectious diseases will be covered. Manuscripts must provide a clear conceptual or mechanistic advance. The editors will reject papers that require major changes, including addition of significant experimental data or other significant revision. Traffic will consider manuscripts of any length, but encourages authors to limit their papers to 16 typeset pages or less.
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