Project description:The ATP-dependent chaperones of the Hsp70 class (DnaK in E. coli) function in protein folding in cooperation with J proteins and nucleotide exchange factors (DnaJ and GrpE in E. coli, respectively). Hsp70 prevents protein aggregation, increasing the folding yield, but whether it also enhances the rate of folding is unclear. Equilibrium hydrogen/deuterium exchange – mass spectrometry showed that DnaK stabilizes a poorly structured state of firefly luciferase (FLuc). Pulsed-label experiments, together with orthogonal analyses by spFRET, identified compact inter-domain misfolded states of FLuc that convert slowly to the native state. DnaK binding expands the misfolded region and thereby resolves the kinetically-trapped intermediates, with folding occurring upon GrpE-mediated release. By resolving misfolding and accelerating folding the Hsp70 system can maintain proteins in their native states under otherwise denaturing stress conditions.

Project description:WWP2 is a HECT E3 ligase that targets protein Lys residues for ubiquitination. As a member of the NEDD4 family of E3 ligases, WWP2 is comprised of an N-terminal C2 domain, four central WW domains, and a C-terminal catalytic HECT domain. The peptide segment between the middle WW domains, the 2,3-linker, can autoinhibit the catalytic domain and this can be relieved by phosphorylation at Tyr369. Several protein substrates of WWP2 have been identified, including the tumor suppressor lipid phosphatase PTEN, but the full substrate landscape and biological functions of WWP2 remain to be elucidated. Here we use protein microarray technology and the activated enzyme phosphomimetic mutant WWP2Y369E to identify potential WWP2 substrates. We identified 31 substrate hits for WWP2Y369E using protein microarrays of which three are the autophagy receptors, NDP52, OPTN, and SQSTM1. These three hits were validated with in vitro and cell-based transfection assays and the Lys ubiquitination sites on these proteins were mapped by mass spectrometry. Among the mapped ubiquitin sites on these autophagy receptors, many were previously identified in studies on the endogenous proteins. WWP2 knockout SH-SH5Y neuroblastoma cells using CRISPR-Cas9 showed a defect in mitophagy in a fashion that could be rescued by WWP2Y369E transfection. These studies suggest that WWP2-mediated ubiquitination of the autophagy receptors NDP52, OPTN, and SQSTM1 may positively contribute to the regulation of autophagy.

Project description:NCX proteins (Na+/Ca2+ exchangers) are allosterically regulated by cytosolic Ca2+ and Na+ to feedback ion signaling in diverse cell types. The recently discovered cryo-EM structure of the cardiac NCX1.1 provided breakthrough information on the mammalian NCX structure, although the structure-dynamic basis of allosteric regulation remains unresolved. Here, we analyzed the apo, Ca2+-, and Na+ -bound species of the brain NCX1.4 variant using hydrogen-deuterium exchange mass spectrometry (HDX-MS) in conjunction with molecular dynamics (MD) simulations. We show that Ca2+ binding to the regulatory CBD domains dramatically rigidifies the intracellular regulatory loop (5L6) and promotes its interaction with the membrane. Either Na+ or Ca2+ stabilizes the intracellular portions of TM3, TM4, TM9, TM10, and their connecting loops (3L4 and 9L10), exposing a putative cation binding site for allosteric regulation. Either Ca2+ or Na+ rigidifies TMH2, encompassing the palmitoylation domain, and the neighboring two-helix TM1/TM6 bundle(governing the alternating access transitions) to control the ion transport rates. Collectively, our results uncovered important details of allosteric regulation in mammalian NCX, while highlighting structure-dynamic features of functional regions not resolved in the cryo-EM structure. The present outcomes provide useful clues toward resolving the structure-dynamic determinants of regulatory diversity in NCX isoform/splice variants.

Project description:Human phosphoglycerate kinase 1 is a key glycolytic enzyme that regulates the balance between ADP and ATP concentrations inside the cell. Phosphorylation of hPGK1 at S203 and S256 has been associated with enzyme import from the cytosol to the mitochondria and the nucleus, respectively. These changes in subcellular location drive tumorigenesis and are likely associated with site-specific changes in protein stability. In this work, we investigate the effects of site-specific phosphorylation on thermal and kinetic stability and protein structural dynamics by hydrogen-deuterium exchange (HDX). We also investigate the binding of 3-phosphoglycerate and Mg-ADP using these approaches. We show that the phosphomimetic mutation S256D reduces hPGK1 kinetic stability by 50-fold, with no effect of the mutation S203D. Calorimetric studies of ligand binding show a large decrease in affinity for Mg-ADP in the S256D variant whereas Mg-ADP binding to the WT and S203D can be accurately investigated using protein kinetic stability and binding thermodynamic models. HDX studies structurally confirmed the destabilization caused by the mutation S256D (with some long-range effects on stability) and its reduced affinity for Mg-ADP due to the strong destabilization of its binding site (particularly in the apo-state). Our work thus support that alterations in protein stability might facilitate import of hPGK1 to the nucleus in cancer, whereas the structural and energetic basis of its mitochondrial import remain unknown. The general implications of our work for protein import to certain subcellular locations are discussed in a wider context.

Project description:Primary hyperoxaluria type I (PH1) is a genetic disease caused by a deficiency in the peroxisomal alanine:glyoxylate aminotransferase (AGT) activity. Mutations in AGT mostly cause protein mistargeting and enhanced aggregation, although the molecular and structural basis of these mechanisms are unknown. In this work, we use hydrogen-deuterium exchange monitored by mass spectrometry (HDX-MS) to provide novel insight into these pathogenic mechanisms. We characterize the wild-type (WT) protein, the LM variant (containing the mutations P11L and I340M, a haplotype more frequent in PH1 patients) and the LM G170R (the most common genotype in PH1, introducing the G170R mutation on the LM background). Our study provides the first experimental analysis of the local stability and dynamics of AGT, showing that stability is heterogeneous in the native state and providing a blueprint for frustrated regions with potentially functional relevance. The LM and LM G170R variants destabilize locally the structure. Enzymatic transamination of the PLP bound to AGT hardly affects stability. Our study thus supports that AGT misfolding is not caused by dramatic effects on the stability and dynamics of the holo-protein.

Project description:C2 Domain DMS

Project description:To provide additional insight into the molecular mechanisms underlying p110 phosphorylation we carried out hydrogen deuterium exchange mass spectrometry (HDX-MS) experiments on p110 and phosphorylated p110 (90.8% phosphorylated S594/595, 92% phosphorylated S582. When we compared phosphorylated p110 (>90.8% as measured by mass spectrometry at both sites) to unphosphorylated p110 we observed extensive increases in dynamics in the C2, helical domain and kinase domain (Fig. 4A-D). The largest increases in exchange upon phosphorylation were located in the N-terminal region of the helical domain, with the peptides directly adjacent to the phosphorylation site showing almost complete deuterium incorporation at the earliest time points of exchange. This is indicative of significant disruption of the alpha helical secondary structure in this region.

Project description:Eukaryotic innate immune systems use pattern recognition receptors (PRRs) to sense infection by detecting pathogen-associated molecular patterns, which then triggers an immune response. Bacteria have similarly evolved immunity proteins that sense certain components of their viral predators known as bacteriophages1–6. Although different immunity proteins can recognize distinct phage-encoded triggers, individual bacterial immunity proteins have only been found to sense a single trigger, suggesting a one-to-one relationship between bacterial PRRs and their ligands7–11. Here, we demonstrate that the anti-phage defense protein CapRelSJ46 in Escherichia coli can directly bind and sense two completely unrelated and structurally different proteins using the same sensory domain, with overlapping but distinct interfaces. Here we tried to find the epitope between capRel and gp54 with HDX-MS.

Project description:The conserved human secreted glycoprotein Clusterin (aka Apolipoprotein-J, ApoJ) is an abundant component of body fluids such as blood plasma and cerebrospinal fluid. Clusterin is thought to function as an extracellular molecular chaperone stabilizing misfolded proteins in solution. In addition, clusterin forms lipoprotein complexes and fractions with HDL particles in plasma. Variants of the clusterin gene constitute the third most important risk factor for late-onset Alzheimer's disease. To better understand it structure and functions, the crystal structure of a mutant form of Clusterin was determined. In order to validate the structural data, hydrogen-deuterium exchange kinetics followed by pepsin proteolysis and mass spectrometry analysis of recombinant mutant and wildtype protein were performed (Part 1 of the deposited data). Based on the structure, rational mutants were designed and subjected to functional tests such as chaperone activity, cellular uptake and receptor binding and lipoprotein complex formation. In order to probe the conformation of Clusterin in the lipoprotein complex, free and lipid-bound protein were subjected to limited proteolysis with chymotrypsin and the resultant fragments analyzed by LC/MS proteomics (Part 2 of the deposited data).

Project description:Retinoic Acid Receptors (RARs) as a functional heterodimer with Retinoid X Receptors (RXRs), bind a diverse series of RA-response elements (RAREs) in regulated genes. Among them, the non-canonical DR0 elements are bound by RXR-RAR with comparable affinities to DR5 elements but DR0 elements do not act transcriptionally as independent RAREs. In this work, we present structural insight for the recognition of DR5 and DR0 elements by RXR-RAR heterodimer using x-ray crystallography, small angle x-ray scattering, and hydrogen/deuterium exchange coupled to mass spectrometry. We solved the crystal structure of RXR-RAR DNA-binding domain in complex with the Rarb2 DR5 and RXR DNA-binding domain in complex with Hoxb13 DR0. While cooperative binding was observed on DR5, on DR0 the two molecules bound non-cooperatively on opposite sides of the DNA. In addition, our data unveil the structural organization and dynamics of the multi-domain RXR-RAR DNA complexes providing evidence for DNA-dependent allosteric communication between domains. Differential binding mode between DR0 and DR5 were observed leading to differences in the conformation and structural dynamics of the multi-domain RXR-RAR DNA complex. These results reveal that the topological organization of the RAR binding element confer regulatory information by modulating the overall topology and structural dynamics of the RXR-RAR heterodimers.