Mapping Critical Residues in ATG11’s Coiled-Coil 2 Domain that Block Multiple Interactions and Disrupt Selective Autophagy

Meyer, Mitchell D.; Winzeler, Jasmine; Taylor, Sophia M.; Kilgore, Alex; Edicha, Kimberly; Chitwood, Chase; Spearin, Zachary; Silvia, S. K. Nadia Rahman; Chakraborty, Ronith; Smith, Jesse E.; Kennedy, Brian; Zois, Carson; Cawthon, Hayley; Gilruth, Mukiri; Backues, Steven K.

doi:10.3389/fcell.2021.775364

Cited by 2 publications

References 48 publications

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Reconstitution of autophagosomal membrane tethering reveals that the ability of Atg11 to bind membranes is important for mitophagy

Andhare,

Katzenell,

Najera

et al. 2023

Preprint

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Membrane tethering is essential for the generation of organelle contact sites and to anchor incoming vesicles to their target membranes before vesicle fusion. During autophagy in yeast, tethering of 30 nm vesicles to cargo is one of the first steps in the generation of the isolation membrane that engulfs the cargo to be degraded. While membrane tethering is critical for cellular function, many of the current biochemical techniques to assay for membrane tethering rely on indirect readouts and are limited in their ability to monitor protein localization at sites of tethering. As such, we developed a fluorescence-microscopy-basedGUV liposome tethering assay (GLT) to directly visualize membrane tethering and monitor protein localization at tethering sites simultaneously. We initially used GLT with engineered membrane tethers to demonstrate the ease of use, versatility and sensitivity of the assay. We also demonstrated that the selective autophagy scaffolding protein Atg11 can bind, and tether negatively charged membranes but is unable to bind GUVs mimicking the charge of the outer mitochondrial membrane. Atg11 instead requires the selective autophagy receptor Atg32 to be recruited to mitochondrial membranes. Lastly, we demonstrate that Atg11 bound to Atg32 on GUVs can tether negatively charged vesicles to GUVs. Collectively, our results reconstitute one of the first steps during the initiation of mitochondrial autophagy and highlight the versatility of GLT to study a range of membrane tethering events biochemically.

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Reconstitution of autophagosomal membrane tethering reveals that the ability of Atg11 to bind membranes is important for mitophagy

Andhare,

Katzenell,

Najera

et al. 2023

Preprint

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Analysis of Atg proteins involved in the formation of the Atg1 complex, their interaction with the Atg8 protein during autophagosome maturation

Bulgakov,

Rayevsky

2023

Fakt. eksp. evol. org.

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Aim. Relying on the data from numerous researches on the representatives of ATG proteins from H.sapiens and S.cerevisiae organisms, we decided to explore the difference between ATG proteins from plant organism. Subsequent stages comprised the determination of in silico phosphorylation effects on the native structure of the protein model and the possible influences on the stability of the three-dimensional complex by the molecular dynamics method. Methods. Methodologically, one can highlight the process of models elaboration on known sequences in AlphaFold 2.0 program and subsequent mechanistic review of molecular mobility of the obtained conformational models through the molecular dynamics in Gromacs 4.5 program and Charmm36 force field. Results. As a result of the model development and exploring the process of ATG-protein complexation, the geometrical specificities of the structures under investigation revealed the binding sites on the surface of the Atg1 complex components. We also suggested some areas for the intermolecular interactions based on the already published data on experimentl mutagenesis. Additively, we performed an analysis of the molecular dynamics simulations in the case of phosphorylation and its effect on the conformational mobility of these objects. Conclusions. Applying the computer simulation modelling methods we created the Atg1 complex elements and then analyzed these four proteins participating in the process.

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Mapping Critical Residues in ATG11’s Coiled-Coil 2 Domain that Block Multiple Interactions and Disrupt Selective Autophagy

Cited by 2 publications

References 48 publications

Reconstitution of autophagosomal membrane tethering reveals that the ability of Atg11 to bind membranes is important for mitophagy

Reconstitution of autophagosomal membrane tethering reveals that the ability of Atg11 to bind membranes is important for mitophagy

Analysis of Atg proteins involved in the formation of the Atg1 complex, their interaction with the Atg8 protein during autophagosome maturation

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