Yeojin Moon scite author profile

Sterols play critical roles in various membrane fusion events, including soluble NSF attachment protein receptor‐mediated membrane fusion, mainly by modulating the physical properties of biologic membranes; however, it remains unclear whether they also function in atlastin‐mediated endoplasmic reticulum (ER) membrane fusion. Although ergosterol, the major sterol in yeast, is essential for fusion of Sey1p (yeast atlastin)‐containing liposomes with an ER‐mimicking lipid composition, fusion of phosphatidylcholine/phosphatidylserine liposomes does not require sterols. Here, we examined whether sterols are important for Sey1p‐mediated ER fusion in Saccharomyces cerevisiae using an in vitro ER fusion assay with isolated yeast ER microsomes. Ergosterol‐specific ligands inhibited microsome fusion, indicating that ergosterol is critical for ER fusion. However, microsomes isolated from yeast strains lacking genes that encode enzymes involved in synthesis of ergosterol from lanosterol still fused, suggesting that other sterols can replace ergosterol and support Sey1p‐mediated ER fusion. Importantly, disruption of sterol‐binding motifs in the transmembrane regions of Sey1p markedly reduced ER fusion. Sey1p physically interacted with Erg11p and Erg4p, which function in ergosterol biosynthesis, suggesting that Sey1p recruits ergosterol‐synthesizing enzymes to fusion sites and thereby enriches ergosterol, which, in turn, may recruit more Sey1p. This positive feedback loop may facilitate ER membrane fusion by concentrating fusion factors at fusion sites.—Lee, M., Moon, Y., Lee, S., Lee, C., Jun, Y. Ergosterol interacts with Sey1p to promote atlastin‐mediated endoplasmic reticulum membrane fusion in Saccharomyces cerevisiae. FASEB J. 33, 3590–3600 (2019). http://www.fasebj.org

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Molecular mechanisms of atlastin-mediated ER membrane fusion revealed by a FRET-based single-vesicle fusion assay

Kim

Moon

Jang

et al. 2017

Sci Rep

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Homotypic fusion of endoplasmic reticulum membranes is driven by atlastin GTPases; however, the underlying mechanism remains largely unknown. Here, using a FRET-based single-vesicle fusion assay with liposomes bearing the yeast atlastin Sey1p, we investigated the molecular mechanisms of atlastin-mediated membrane tethering and fusion. Although Sey1p-bearing proteoliposomes frequently underwent membrane tethering in a GTP hydrolysis-dependent manner as reported in studies using bulk assays, only a small fraction of the tethered liposomes proceeded to fusion. Strikingly, the rest of the tethered liposomes failed to fuse or dissociate. This stable tethering, however, did not require continued GTP hydrolysis because GTP omission and magnesium chelation did not disrupt tethering. Interestingly, an increased Sey1p density on the membrane markedly accelerated tethering but barely affected the fusion rate of the tethered liposomes, indicating that Sey1p requires additional factors to support efficient fusion in vivo. Finally, the assay also revealed that Sey1p-mediated liposome fusion occurs through hemifusion, suggesting the mechanistic conservation between biological membrane fusion events despite the existence of diverse fusogens.

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The Effects of Regulatory Lipids on Intracellular Membrane Fusion Mediated by Dynamin-Like GTPases

Moon

Jun

2020

Front. Cell Dev. Biol.

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Membrane fusion mediates a number of fundamental biological processes such as intracellular membrane trafficking, fertilization, and viral infection. Biological membranes are composed of lipids and proteins; while lipids generally play a structural role, proteins mediate specific functions in the membrane. Likewise, although proteins are key players in the fusion of biological membranes, there is emerging evidence supporting a functional role of lipids in various membrane fusion events. Intracellular membrane fusion is mediated by two protein families: SNAREs and membrane-bound GTPases. SNARE proteins are involved in membrane fusion between transport vesicles and their target compartments, as well as in homotypic fusion between organelles of the same type. Membrane-bound GTPases mediate mitochondrial fusion and homotypic endoplasmic reticulum fusion. Certain membrane lipids, known as regulatory lipids, regulate these membrane fusion events by directly affecting the function of membranebound GTPases, instead of simply changing the biophysical and biochemical properties of lipid bilayers. In this review, we provide a summary of the current understanding of how regulatory lipids affect GTPase-mediated intracellular membrane fusion by focusing on the functions of regulatory lipids that directly affect fusogenic GTPases.

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Human atlastins are sufficient to drive the fusion of liposomes with a physiological lipid composition

Jang

Moon

Yoon

et al. 2023

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The dynamin-like GTPase atlastin is believed to be the minimal machinery required for homotypic endoplasmic reticulum (ER) membrane fusion, mainly because Drosophila atlastin is sufficient to drive liposome fusion. However, it remains unclear whether mammalian atlastins, including the three human atlastins, are sufficient to induce liposome fusion, raising doubts about their major roles in mammalian cells. Here, we show that all human atlastins are sufficient to induce fusion when reconstituted into liposomes with a lipid composition mimicking that of the ER. Although the fusogenic activity of ATL1, which is predominantly expressed in neuronal cells, was weaker than that of ATL2 or ATL3, the addition of M1-spastin, a neuron-specific factor, markedly increased ATL1-mediated liposome fusion. Although we observed efficient fusion between ER microsomes isolated from cultured, non-neuronal cells that predominantly express ATL2-1, an autoinhibited isoform of ATL2, ATL2-1 failed to support liposome fusion by itself as reported previously, indicating that cellular factors enable ATL2-1 to mediate ER fusion in vivo.

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Yeojin Moon

SNAREs support atlastin-mediated homotypic ER fusion in Saccharomyces cerevisiae

Ergosterol interacts with Sey1p to promote atlastin‐mediated endoplasmic reticulum membrane fusion inSaccharomyces cerevisiae

Molecular mechanisms of atlastin-mediated ER membrane fusion revealed by a FRET-based single-vesicle fusion assay

The Effects of Regulatory Lipids on Intracellular Membrane Fusion Mediated by Dynamin-Like GTPases

Human atlastins are sufficient to drive the fusion of liposomes with a physiological lipid composition

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