The Intrinsically Disordered N Terminus in Atg12 from Yeast Is Necessary for the Functional Structure of the Protein.

The Atg12 protein in yeast is an indispensable polypeptide in the highly conserved ubiquitin-like conjugation system operating in the macroautophagy/autophagy pathway. Atg12 is covalently conjugated to Atg5 through the action of Atg7 and Atg10; the Atg12-Atg5 conjugate binds Atg16 to form an E3 ligase that functions in a separate conjugation pathway involving Atg8. Atg12 is comprised of a ubiquitin-like (UBL) domain preceded at the N terminus by an intrinsically disordered protein region (IDPR), a domain that comprises a major portion of the protein but remains elusive in its conformation and function. Here, we show that the IDPR in unconjugated Atg12 is positioned in proximity to the UBL domain, a configuration that is important for the functional structure of the protein. A major deletion in the IDPR disrupts intactness of the UBL domain at the unconjugated C terminus, and a mutation in the predicted α0 helix in the IDPR prevents Atg12 from binding to Atg7 and Atg10, which ultimately affects the protein function in the ubiquitin-like conjugation cascade. These findings provide evidence that the IDPR is an indispensable part of the Atg12 protein from yeast.

Theater in the Self-Cleaning Cell: Intrinsically Disordered Proteins or Protein Regions Acting with Membranes in Autophagy.

Intrinsically disordered proteins and protein regions (IDPs/IDPRs) are mainly involved in signaling pathways, where fast regulation, temporal interactions, promiscuous interactions, and assemblies of structurally diverse components including membranes are essential. The autophagy pathway builds, de novo, a membrane organelle, the autophagosome, using carefully orchestrated interactions between proteins and lipid bilayers. Here, we discuss molecular mechanisms related to the protein disorder-based interactions of the autophagy machinery with membranes. We describe not only membrane binding phenomenon, but also examples of membrane remodeling processes including membrane tethering, bending, curvature sensing, and/or fragmentation of membrane organelles such as the endoplasmic reticulum, which is an important membrane source as well as cargo for autophagy. Summary of the current state of knowledge presented here will hopefully inspire new studies. A profound understanding of the autophagic protein-membrane interface is essential for advancements in therapeutic interventions against major human diseases, in which autophagy is involved including neurodegeneration, cancer as well as cardiovascular, metabolic, infectious, musculoskeletal, and other disorders.

The RB1CC1 Claw-binding motif: a new piece in the puzzle of autophagy regulation.

RB1CC1/FIP200 is a subunit of the ULK1 complex in more complex eukaryotes. This large polypeptide was proposed to be a functional homolog of the Atg17 and Atg11 scaffolding proteins in yeast. Previous studies showed that RB1CC1 can bind to various proteins of the macroautophagy/autophagy machinery, where the RB1CC1 Claw domain directly interacts with a short linear segment of its interactors. A mechanistic insight into how the small globular RB1CC1 Claw domain can interact with such an array of structurally variable proteins has been elusive. The recent study by Zhou et al., discussed here, yields structural data that not only provide a unifying mechanistic explanation of these interactions, but also reveals previously unknown RB1CC1 interactors and opens a new field for exploration of autophagy regulation.Abbreviations: FIR: FIP200-interacting region; LIR: LC3-interacting region; pS/p-S: phosphorylated serine.

Membrane Binding and Homodimerization of Atg16 Via Two Distinct Protein Regions is Essential for Autophagy in Yeast.

Macroautophagy is a bulk degradation mechanism in eukaryotic cells. Efficiency of an essential step of this process in yeast, Atg8 lipidation, relies on the presence of Atg16, a subunit of the Atg12-Atg5-Atg16 complex acting as the E3-like enzyme in the ubiquitination-like reaction. A current view on the functional structure of Atg16 in the yeast S. cerevisiae comes from the two crystal structures that reveal the Atg5-interacting α-helix linked via a flexible linker to another α-helix of Atg16, which then assembles into a homodimer. This view does not explain the results of previous in vitro studies revealing Atg16-dependent deformations of membranes and liposome-binding of the Atg12-Atg5 conjugate upon addition of Atg16. Here we show that Atg16 acts as both a homodimerizing and peripheral membrane-binding polypeptide. These two characteristics are imposed by the two distinct regions that are disordered in the nascent protein. Atg16 binds to membranes in vivo via the amphipathic α-helix (amino acid residues 113-131) that has a coiled-coil-like propensity and a strong hydrophobic face for insertion into the membrane. The other protein region (residues 64-99) possesses a coiled-coil propensity, but not amphipathicity, and is dispensable for membrane anchoring of Atg16. This region acts as a Leu-zipper essential for formation of the Atg16 homodimer. Mutagenic disruption in either of these two distinct domains renders Atg16 proteins that, in contrast to wild type, completely fail to rescue the autophagy-defective phenotype of atg16Δ cells. Together, the results of this study yield a model for the molecular mechanism of Atg16 function in macroautophagy.

Dancing while self-eating: Protein intrinsic disorder in autophagy.

Autophagy is a major catabolic pathway that must be tightly regulated to maintain cellular homeostasis. Protein intrinsic disorder provides a very suitable conformation for regulation; accordingly, the molecular machinery of autophagy is significantly enriched in intrinsically disordered proteins and protein regions (IDPs/IDPRs). Despite experimental challenges that the characterization of IDPRs encounters, remarkable progress has been made in recent years in revealing various roles of IDPs/IDPRs in autophagy. This chapter describes the autophagy pathway from a specific point of view, that of IDPRs. It focuses in detail on structural and mechanistic functions in autophagy that are executed by disordered regions. Via a description of autophagosome biogenesis, linking the cargo to the autophagy machinery, as well as a discussion of certain post-translational regulations, this review reveals many indispensable roles of IDPRs in the functional autophagy pathway. Devastating pathologies such as neurodegeneration, cancer, or diabetes have been linked to a malfunction in IDPs/IDPRs. The same pathologies are associated with dysfunctional autophagy, indicating that autophagic IDPRs may be a paramount causative factor. Several disease-related mechanisms of the autophagy pathway involving protein intrinsic disorder are reported in this chapter, to illustrate a wide-ranging potential of IDPRs in the therapeutic modulation of autophagy.

Molecular dynamics simulations reveal how the reticulon-homology domain of the autophagy receptor RETREG1/FAM134B remodels membranes for efficient selective reticulophagy.

The autophagy receptor for selective reticulophagy, RETREG1/FAM134B is essential for ER maintenance, and its dysfunction is associated with neuronal disorders, vascular dementia, or viral infections. The protein consists of the reticulon-homology domain (RHD) that is flanked at the N- and C-termini by an intrinsically disordered protein region (IDPR), where the C terminal IDPR carries the indispensable LC3-interacting region (LIR) motif for the interaction with LC3. The RHD of RETREG1 is presumed to play a role in membrane remodeling, but the absence of a known 3D structure of this domain so far prevented researchers from gaining mechanistic insights into how the RETREG1 RHD curves membranes, and thereby facilities reticulophagy. The recent study by Bhaskara et al., which is described in this editor's corner article, used molecular dynamics (MD) simulations to create a structural model of the RETREG1 RHD. MD simulations along with in vitro liposome remodeling experiments reveal how the RHD domain acts on the ER membrane and, in concert with the C terminal IDPR, executes the function of RETREG1 in selective reticulophagy.Abbreviations: ER, endoplasmic reticulum; IDPR, intrinsically disordered protein region; LIR, LC3-interacting region; MD, molecular dynamics; RHD, reticulon-homology domain; TM, transmembrane.

Structural basis for extremely strong binding affinity of giant ankyrins to LC3/GABARAP and its application in the inhibition of autophagy.

The Atg8/LC3/GABARAP family of proteins binds its physiological binding partners, which function in macroautophagy (hereafter autophagy), via recognition of their short linear motif, also known as the LC3-interactiong region (LIR) or Atg8-interacting motif (AIM). The AIM/LIR motif, with the consensus sequence [W/F/Y]xx[L/I/V], utilizes the aromatic and hydrophobic residues that bind on the surface of Atg8/LC3/GABARAP. Despite modest binding affinity, this interaction is essential for efficient autophagy. Here we highlight the recent paper by Li and collaborators who discovered the structural basis for a much stronger interaction between the LIR motif-containing peptides and LC3/GABARAP. Moreover, they showed that these peptides are potent and selective inhibitors of autophagy in cultured cells and in C. elegans.

Kinetic and structural investigation of the cytokinin oxidase/dehydrogenase active site.

Cytokinins are hormones that regulate plant development and their environmental responses. Their levels are mainly controlled by the cytokinin oxidase/dehydrogenase (CKO), which oxidatively cleaves cytokinins using redox-active electron acceptors. CKO belongs to the group of flavoproteins with an 8α-N1-histidyl FAD covalent linkage. Here, we investigated the role of seven active site residues, H105, D169, E288, V378, E381, P427 and L492, in substrate binding and catalysis of the CKO1 from maize (Zea mays, ZmCKO1) combining site-directed mutagenesis with kinetics and X-ray crystallography. We identify E381 as a key residue for enzyme specificity that restricts substrate binding as well as quinone electron acceptor binding. We show that D169 is important for catalysis and that H105 covalently linked to FAD maintains the enzyme's structural integrity, stability and high rates with electron acceptors. The L492A mutation significantly modulates the cleavage of aromatic cytokinins and zeatin isomers. The high resolution X-ray structures of ZmCKO1 and the E381S variant in complex with N6-(2-isopentenyl)adenosine reveal the binding mode of cytokinin ribosides. Those of ZmCKO2 and ZmCKO4a contain a mobile domain, which might contribute to binding of the N9 substituted cytokinins.

Identification of Atg3 as an intrinsically disordered polypeptide yields insights into the molecular dynamics of autophagy-related proteins in yeast.

The mechanism of autophagy relies on complex cell signaling and regulatory processes. Each cell contains many proteins that lack a rigid 3-dimensional structure under physiological conditions. These dynamic proteins, called intrinsically disordered proteins (IDPs) and protein regions (IDPRs), are predominantly involved in cell signaling and regulation. Yet, very little is known about their presence among proteins of the core autophagy machinery. In this work, we characterized the autophagy protein Atg3 from yeast and human along with 2 variants to show that Atg3 is an IDPRs-containing protein and that disorder/order predicted for these proteins from their amino acid sequence corresponds to their experimental characteristics. Based on this consensus, we applied the same prediction methods to all known Atg proteins from Saccharomyces cerevisiae. The data presented here provide an insight into the structural dynamics of each Atg protein. They also show that intrinsic disorder at various levels has to be taken into consideration for about half of the Atg proteins. This work should become a useful tool that will facilitate and encourage exploration of protein intrinsic disorder in autophagy.