Vladimir V. Rogov

Nix is a selective autophagy receptor for mitochondrial clearance

Autophagy is the cellular homeostatic pathway that delivers large cytosolic materials for degradation in the lysosome. Recent evidence indicates that autophagy mediates selective removal of protein aggregates, organelles and microbes in cells. Yet, the specificity in targeting a particular substrate to the autophagy pathway remains poorly understood. Here, we show that the mitochondrial protein Nix is a selective autophagy receptor by binding to LC3/GABARAP proteins, ubiquitin‐like modifiers that are required for the growth of autophagosomal membranes. In cultured cells, Nix recruits GABARAP‐L1 to damaged mitochondria through its amino‐terminal LC3‐interacting region. Furthermore, ablation of the Nix:LC3/GABARAP interaction retards mitochondrial clearance in maturing murine reticulocytes. Thus, Nix functions as an autophagy receptor, which mediates mitochondrial clearance after mitochondrial damage and during erythrocyte differentiation.

Interactions between Autophagy Receptors and Ubiquitin-like Proteins Form the Molecular Basis for Selective Autophagy

Selective autophagy ensures recognition and removal of various cytosolic cargoes. Hence, aggregated proteins, damaged organelles, or pathogens are enclosed into the double-membrane vesicle, the autophagosome, and delivered to the lysosome for degradation. This process is mediated by selective autophagy receptors, such as p62/SQSTM1. These proteins recognize autophagic cargo and, via binding to small ubiquitin-like modifiers (UBLs)--Atg8/LC3/GABARAPs and ATG5--mediate formation of selective autophagosomes. Recently, it was found that UBLs can directly engage the autophagosome nucleation machinery. Here, we review recent findings on selective autophagy and propose a model for selective autophagosome formation in close proximity to cargo.

Structural basis for the selectivity of the external thioesterase of the surfactin synthetase

Non-ribosomal peptide synthetases (NRPS) and polyketide synthases (PKS) found in bacteria, fungi and plants use two different types of thioesterases for the production of highly active biological compounds. Type I thioesterases (TEI) catalyse the release step from the assembly line of the final product where it is transported from one reaction centre to the next as a thioester linked to a 4′-phosphopantetheine (4′-PP) cofactor that is covalently attached to thiolation (T) domains. The second enzyme involved in the synthesis of these secondary metabolites, the type II thioesterase (TEII), is a crucial repair enzyme for the regeneration of functional 4′-PP cofactors of holo-T domains of NRPS and PKS systems. Mispriming of 4′-PP cofactors by acetyl- and short-chain acyl-residues interrupts the biosynthetic system. This repair reaction is very important, because roughly 80% of CoA, the precursor of the 4′-PP cofactor, is acetylated in bacteria. Here we report the three-dimensional structure of a type II thioesterase from Bacillus subtilis free and in complex with a T domain. Comparison with structures of TEI enzymes shows the basis for substrate selectivity and the different modes of interaction of TEII and TEI enzymes with T domains. Furthermore, we show that the TEII enzyme exists in several conformations of which only one is selected on interaction with its native substrate, a modified holo-T domain.

Involvement of the ubiquitin-like domain of TBK1/IKK-i kinases in regulation of IFN-inducible genes.

TANK‐binding kinase 1 (TBK1/NAK/T2K) and I‐κB Kinase (IKK‐i/IKK‐ε) play important roles in the regulation of interferon (IFN)‐inducible genes during the immune response to bacterial and viral infections. Cell stimulation with ssRNA virus, dsDNA virus or gram‐negative bacteria leads to activation of TBK1 or IKK‐i, which in turn phosphorylates the transcription factors, IFN‐regulatory factor (IRF) 3 and IRF7, promoting their translocation in the nucleus. To understand the molecular basis of activation of TBK1, we analyzed the sequence of TBK1 and IKK‐i and identified a ubiquitin‐like domain (ULD) adjacent to their kinase domains. Deletion or mutations of the ULD in TBK1 or IKK‐i impaired activation of respective kinases, failed to induce IRF3 phosphorylation and nuclear localization and to activate IFN‐β or RANTES promoters. The importance of the ULD of TBK1 in LPS‐ or poly(I:C)‐stimulated IFN‐β production was demonstrated by reconstitution experiments in TBK1‐IKK‐i‐deficient cells. We propose that the ULD is a regulatory component of the TBK1/IKK‐i kinases involved in the control of the kinase activation, substrate presentation and downstream signaling pathways.

Characterization of the Interaction of GABARAPL-1 with the LIR Motif of NBR1

Selective autophagy requires the specific segregation of targeted proteins into autophagosomes. The selectivity is mediated by autophagy receptors, such as p62 and NBR1, which can bind to autophagic effector proteins (Atg8 in yeast, MAP1LC3 protein family in mammals) anchored in the membrane of autophagosomes. Recognition of autophagy receptors by autophagy effectors takes place through an LC3 interaction region (LIR). The canonical LIR motif consists of a WXXL sequence, N-terminally preceded by negatively charged residues. The LIR motif of NBR1 presents differences to this classical LIR motif with a tyrosine residue and an isoleucine residue substituting the tryptophan residue and the leucine residue, respectively. We have determined the structure of the GABARAPL-1/NBR1-LIR complex and studied the influence of the different residues belonging to the LIR motif for the interaction with several mammalian autophagy modifiers (LC3B and GABARAPL-1). Our results indicate that the presence of a tryptophan residue in the LIR motif increases the binding affinity. Substitution by other aromatic amino acids or increasing the number of negatively charged residues at the N-terminus of the LIR motif, however, has little effect on the binding affinity due to enthalpy-entropy compensation. This indicates that different LIRs can interact with autophagy modifiers with unique binding properties.

Structural basis for phosphorylation-triggered autophagic clearance of Salmonella

Selective autophagy is mediated by the interaction of autophagy modifiers and autophagy receptors that also bind to ubiquitinated cargo. Optineurin is an autophagy receptor that plays a role in the clearance of cytosolic Salmonella. The interaction between receptors and modifiers is often relatively weak, with typical values for the dissociation constant in the low micromolar range. The interaction of optineurin with autophagy modifiers is even weaker, but can be significantly enhanced through phosphorylation by the TBK1 {TANK [TRAF (tumour-necrosis-factor-receptor-associated factor)-associated nuclear factor κB activator]-binding kinase 1}. In the present study we describe the NMR and crystal structures of the autophagy modifier LC3B (microtubule-associated protein light chain 3 beta) in complex with the LC3 interaction region of optineurin either phosphorylated or bearing phospho-mimicking mutations. The structures show that the negative charge induced by phosphorylation is recognized by the side chains of Arg¹¹ and Lys⁵¹ in LC3B. Further mutational analysis suggests that the replacement of the canonical tryptophan residue side chain of autophagy receptors with the smaller phenylalanine side chain in optineurin significantly weakens its interaction with the autophagy modifier LC3B. Through phosphorylation of serine residues directly N-terminally located to the phenylalanine residue, the affinity is increased to the level normally seen for receptor-modifier interactions. Phosphorylation, therefore, acts as a switch for optineurin-based selective autophagy.

TECPR2 Cooperates with LC3C to Regulate COPII-Dependent ER Export

Hereditary spastic paraplegias (HSPs) are a diverse group of neurodegenerative diseases that are characterized by axonopathy of the corticospinal motor neurons. A mutation in the gene encoding for Tectonin β-propeller containing protein 2 (TECPR2) causes HSP that is complicated by neurological symptoms. While TECPR2 is a human ATG8 binding protein and positive regulator of autophagy, the exact function of TECPR2 is unknown. Here, we show that TECPR2 associates with several trafficking components, among them the COPII coat protein SEC24D. TECPR2 is required for stabilization of SEC24D protein levels, maintenance of functional ER exit sites (ERES), and efficient ER export in a manner dependent on binding to lipidated LC3C. TECPR2-deficient HSP patient cells display alterations in SEC24D abundance and ER export efficiency. Additionally, TECPR2 and LC3C are required for autophagosome formation, possibly through maintaining functional ERES. Collectively, these results reveal that TECPR2 functions as molecular scaffold linking early secretion pathway and autophagy.

A Universal Expression Tag for Structural and Functional Studies of Proteins

Modified ubiquitin sequences, each completed with a His tag and a TEV cleavage site, were designed to enhance the expression of protein/peptide targets. With this new system we have been able to characterize several peptide-protein interactions by ITC and by NMR and CD spectroscopic methods, including the interactions of LIR domains with autophagy modifiers.

Phosphorylation of the mitochondrial autophagy receptor Nix enhances its interaction with LC3 proteins

The mitophagy receptor Nix interacts with LC3/GABARAP proteins, targeting mitochondria into autophagosomes for degradation. Here we present evidence for phosphorylation-driven regulation of the Nix:LC3B interaction. Isothermal titration calorimetry and NMR indicate a ~100 fold enhanced affinity of the serine 34/35-phosphorylated Nix LC3-interacting region (LIR) to LC3B and formation of a very rigid complex compared to the non-phosphorylated sequence. Moreover, the crystal structure of LC3B in complex with the Nix LIR peptide containing glutamic acids as phosphomimetic residues and NMR experiments revealed that LIR phosphorylation stabilizes the Nix:LC3B complex via formation of two additional hydrogen bonds between phosphorylated serines of Nix LIR and Arg11, Lys49 and Lys51 in LC3B. Substitution of Lys51 to Ala in LC3B abrogates binding of a phosphomimetic Nix mutant. Functionally, serine 34/35 phosphorylation enhances autophagosome recruitment to mitochondria in HeLa cells. Together, this study provides cellular, biochemical and biophysical evidence that phosphorylation of the LIR domain of Nix enhances mitophagy receptor engagement.

Solution structure and dynamics of the functional domain of Paracoccus denitrificans cytochrome c(552) in both redox states.

A soluble and fully functional 10.5 kDa fragment of the 18.2 kDa membrane-bound cytochrome c(552) from Paracoccus denitrificans has been heterologously expressed and (13)C/(15)N-labeled to study the structural features of this protein in both redox states. Well-resolved solution structures of both the reduced and oxidized states have been determined using high-resolution heteronuclear NMR. The overall protein topology consists of two long terminal helices and three shorter helices surrounding the heme moiety. No significant redox-induced structural differences have been observed. (15)N relaxation rates and heteronuclear NOE values were determined at 500 and 600 MHz. Several residues located around the heme moiety display increased backbone mobility in both oxidation states, while helices I, III, and V as well as the two concatenated beta-turns between Leu30 and Arg36 apparently form a less flexible domain within the protein structure. Major redox-state-dependent differences of the internal backbone mobility on the picosecond-nanosecond time scale were not evident. Hydrogen exchange experiments demonstrated that the slow-exchanging amide proton resonances mainly belong to the helices and beta-turns, corresponding to the regions with high order parameters in the dynamics data. Despite this correlation, the backbone amide protons of the oxidized cytochrome c(552) exchange considerably faster with the solvent compared to the reduced protein. Using both differential scanning calorimetry as well as temperature-dependent NMR spectroscopy, a significant difference in the thermostabilities of the two redox states has been observed, with transition temperatures of 349.9 K (76.8 degrees C) for reduced and 307.5 K (34.4 degrees C) for oxidized cytochrome c(552). These results suggest a clearly distinct backbone stability between the two oxidation states.