McrBC is one of the three modification-dependent restriction enzymes encoded by the Escherichia coli K12 chromosome. Amongst restriction enzymes, McrBC and its close homologues are unique in employing the AAA+ domain for GTP hydrolysis-dependent activation of DNA cleavage. The GTPase activity of McrB is stimulated by the endonuclease subunit McrC. It had been reported previously that McrB and McrC subunits oligomerise together into a high molecular weight species. Here we conclusively demonstrate using size exclusion chromatography coupled multi-angle light scattering (SEC-MALS) and images obtained by electron cryomicroscopy that McrB exists as a hexamer in solution. Furthermore, based on SEC-MALS and SAXS analyses of McrBC and the structure of McrB, we propose that McrBC is a complex of two McrB hexamers bridged by two subunits of McrC, and that the complete assembly of this complex is integral to its enzymatic activity. We show that the nucleotide-dependent oligomerisation of McrB precedes GTP hydrolysis. Mutational studies show that, unlike other AAA+ proteins, the catalytic Walker B aspartate is required for oligomerisation.
One of the first molecular events in neurodegenerative diseases, regardless of etiology, is protein mislocalization. Protein mislocalization in neurons is often linked to proteostasis deficiencies leading to the build-up of misfolded proteins and/or organelles that contributes to cellular toxicity and cell death. By understanding how proteins mislocalize in neurons, we can develop novel therapeutics that target the earliest stages of neurodegeneration. A critical mechanism regulating protein localization and proteostasis in neurons is the protein-lipid modification S-acylation, the reversible addition of fatty acids to cysteine residues. S-acylation is more commonly referred to as S-palmitoylation or simply palmitoylation, which is the addition of the 16-carbon fatty acid palmitate to proteins. Like phosphorylation, palmitoylation is highly dynamic and tightly regulated by writers (i.e., palmitoyl acyltransferases) and erasers (i.e., depalmitoylating enzymes). The hydrophobic fatty acid anchors proteins to membranes; thus, the reversibility allows proteins to be re-directed to and from membranes based on local signaling factors. This is particularly important in the nervous system, where axons (output projections) can be meters long. Any disturbance in protein trafficking can have dire consequences. Indeed, many proteins involved in neurodegenerative diseases are palmitoylated, and many more have been identified in palmitoyl-proteomic studies. It follows that palmitoyl acyl transferase enzymes have also been implicated in numerous diseases. In addition, palmitoylation can work in concert with cellular mechanisms, like autophagy, to affect cell health and protein modifications, such as acetylation, nitrosylation, and ubiquitination, to affect protein function and turnover. Limited studies have further revealed a sexually dimorphic pattern of protein palmitoylation. Therefore, palmitoylation can have wide-reaching consequences in neurodegenerative diseases.
Protein aggregation is central to aging, disease and biotechnology. While there has been recent progress in defining structural features of cellular protein aggregates, many aspects remain unclear due to heterogeneity of aggregates presenting obstacles to characterization. Here we report high-resolution analysis of cellular inclusion bodies (IBs) of immature human superoxide dismutase (SOD1) mutants using NMR quenched amide hydrogen/deuterium exchange (qHDX), FTIR and Congo red binding. The extent of aggregation is correlated with mutant global stability and, notably, the free energy of native dimer dissociation, indicating contributions of native-like monomer associations to IB formation. This is further manifested by a common pattern of extensive protection against H/D exchange throughout nine mutant SOD1s despite their diverse characteristics. These results reveal multiple aggregation-prone regions in SOD1 and illuminate how aggregation may occur via an ensemble of pathways.
Protein aggregation is central to aging, disease and biotechnology. While there has been recent progress in defining structural features of cellular protein aggregates, many aspects remain unclear due to heterogeneity of aggregates presenting obstacles to characterization. Here we report high-resolution analysis of cellular inclusion bodies (IBs) of immature human superoxide dismutase (SOD1) mutants using NMR quenched amide hydrogen/deuterium exchange (qHDX), FTIR and Congo red binding. The extent of aggregation is correlated with mutant global stability and, notably, the free energy of native dimer dissociation, indicating contributions of native-like monomer associations to IB formation. This is further manifested by a common pattern of extensive protection against H/D exchange throughout nine mutant SOD1s despite their diverse characteristics. These results reveal multiple aggregation-prone regions in SOD1 and illuminate how aggregation may occur via an ensemble of pathways.
Inclusion bodies (IBs) – insoluble structures that can form upon overexpression of proteins‐ have wide relevance in research, industrial settings, and disease. In addition to their use in protein purification, IBs provide a tractable model to elucidate the molecular mechanisms of protein aggregation in cells, as also occurs in neurodegenerative disorders such as amyotrophic lateral sclerosis (ALS), Parkinson's, and Alzheimer's diseases. The aggregation of Cu, Zn superoxide dismutase (SOD1) variants is associated with ALS, yet the relationships between mutant characteristics and disease properties remain obscure. Here, we report a systematic investigation of SOD1 IBs using two powerful complementary methods to analyze the structures of these cellular aggregates and their changes upon mutation. Quenched amide hydrogen‐deuterium exchange (HDX) measurements by NMR for individual residues throughout SOD1 reveal IB structural features and similarities, whereas quantitative conformation specific antibody binding assays highlight notable differences in surface features between mutant IBs. Taken together, these data provide a valuable new high‐resolution view of cellular aggregation. These powerful HDX and quantitative antibody binding methods are widely applicable to other proteins to define the molecular determinants of their aggregation and solubility.
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