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dc.contributor.authorLi, Yue
dc.description.abstractAutophagy is a lysosomal degradation pathway wherein cytoplasmic components not needed by or harmful to the cell are degraded and recycled. BECN homologs are key autophagy proteins consisting of an intrinsically disordered region (IDR), flexible helical domain (FHD), coiled-coil domain (CCD) and β-α repeated, autophagy-specific domain (BARAD). Diverse proteins modulate autophagy by binding BECN1. Understanding the mechanisms by which these proteins regulate BECN1-mediated autophagy is important for developing therapeutics targeting these proteins. Toward this goal, we have developed purification protocols for multi-domain BECN1 fragments to explore the conformational flexibility and interactions. We show that a BECN1 helix transitions between mutually exclusive packing states, wherein it either forms part of the CCD homodimer or packs against the BARAD, but predominantly packs against the BARAD. The same set of residues on this helix contribute to the CCD homodimer or packing with the BARAD, and mutation of these residues abrogates starvation-induced up-regulation of autophagy. Next, we show the equatorial groove of GAPR-1 may be responsible for binding BECN1. The five conserved residues lining the GAPR-1 equatorial groove are essential for the interaction, as mutation of these residues disrupts GAPR-1:BECN1 interaction. We also solved the structure of this pentad mutant, which indicates the changes in the equatorial groove and the improved dimerization of pentad mutant likely abrogates BECN1-binding. We then show that BH3D is not required for BECN1 to up-regulate autophagy, though it is required for binding BCL2 homologs. Therefore, we investigated the interactions between BH3D-containing BECN1 fragments and the BCL2 homolog, M11. BECN1 regions outside the BH3D increase binding to M11 by 5-10 fold. In addition, M11-binding increases flexibility of the nuclear export sequence (NES). Further, homodimerization and thermostability of BECN1 BH3D-FHD-CCD increases upon M11-binding. Lastly, the M11:BH3D-FHD-CCD complex appears to fluctuate between two major types of conformations, which may be mediated by the increased flexibility of BECN1 NES upon binding M11. Lastly, we investigated the interactions between BH3D-containing BECN1 fragments and Bcl-XL. Our results indicate that BECN1 regions outside the BH3D do not affect BECN1 interaction with Bcl-XL. Together, these studies are important for better understanding how proteins down-regulate BECN1-mediate autophagy.en_US
dc.publisherNorth Dakota State Universityen_US
dc.titleInvestigating Selected Mechanisms of Modulation of BECN1-mediated Autophagyen_US
dc.typeDissertationen_US
dc.typeVideoen_US
dc.date.accessioned2019-05-23T17:57:07Z
dc.date.available2019-05-23T17:57:07Z
dc.date.issued2019en_US
dc.identifier.urihttps://hdl.handle.net/10365/29775
dc.subjectautophagyen_US
dc.subjectBCL2/Bcl-XL/M11en_US
dc.subjectBECN1en_US
dc.subjectflexibilityen_US
dc.subjectstructureen_US
dc.description.sponsorshipNIH: RO3 NS090939, R15 GM122035, P20 RR015566, and R21 AI078198 (S.S). R15 GM113227, P30 GM103332-01, P41 GM103622, and P41 GM103403.; NSF: MCB-1413525 (S.S.); ND Dept. of Commerce: Award #14-11-J1-73 (S.S.)en_US
ndsu.degreeDoctor of Philosophy (PhD)en_US
ndsu.collegeScience and Mathematicsen_US
ndsu.departmentChemistry and Biochemistryen_US
ndsu.programBiochemistryen_US
ndsu.advisorSinha, Sangita


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