Hydrogen-deuterium Exchange Research Articles

Hydrogen-Deuterium Exchange Mass Spectrometry Reveals Mechanistic Insights into RNA Oligonucleotide-Mediated Inhibition of TDP-43 Aggregation.

Deposits of aggregated TAR DNA-binding protein 43 (TDP-43) in the brain are associated with several neurodegenerative diseases. It is well established that binding of RNA/DNA to TDP-43 can prevent TDP-43 aggregation, but an understanding of the structure(s) and conformational dynamics of TDP-43, and TDP-43-RNA complexes, is lacking, including knowledge of how the solution environment modulates these properties. Here, we address this challenge using hydrogen-deuterium exchange-mass spectrometry. In the presence of RNA olignoucleotides, we observe protection from exchange in the RNA recognition motif (RRM) domains of TDP-43 and the linker region between the RRM domains, consistent with nucleic acid binding modulating interdomain interactions. Intriguingly, at elevated salt concentrations, the extent of protection from exchange is reduced in the RRM domains when bound to an RNA sequence derived from the 3' UTR of the TDP-43 mRNA (CLIP34NT) compared to when bound to a (UG)6 repeat sequence. Under these conditions, CLIP34NT is no longer able to prevent TDP-43 aggregation. This suggests that a salt-induced structural rearrangement occurs when bound to this RNA, which may play a role in facilitating aggregation. Additionally, upon RNA binding, we identify differences in exchange within the short α-helical region located in the C-terminal domain (CTD) of TDP-43. These allosterically altered regions may influence the ability of TDP-43 to aggregate and fine-tune its RNA binding repertoire. Combined, these data provide additional insights into the intricate interplay between TDP-43 aggregation and RNA binding, an understanding of which is crucial for unraveling the molecular mechanisms underlying TDP-43-associated neurodegeneration.

GPR180 is a new member of the Golgi-dynamics domain seven-transmembrane helix protein family

GOLD domain seven-transmembrane helix (GOST) proteins form a new protein family involved in trafficking of membrane-associated cargo. They share a characteristic extracellular/luminal Golgi-dynamics (GOLD) domain, possibly responsible for ligand recognition. Based on structural homology, GPR180 is a new member of this protein family, but little is known about the cellular role of GPR180. Here we show the X-ray structure of the N-terminal domain of GPR180 (1.9 Å) and can confirm the homology to GOLD domains. Using cellular imaging we show the localization of GPR180 in intracellular vesicular structures implying its exposure to acidic pH environments. With Hydrogen/Deuterium Exchange-Mass Spectrometry (HDX-MS) we identify pH-dependent conformational changes, which can be mapped to a putative ligand binding site in the transmembrane region. The results reveal GPR180’s role in intracellular vesicles and offer insights into the pH-dependent function of this conserved GOST protein.

Insights into the regulation of CHIP E3 ligase-mediated ubiquitination of neuronal protein BNIP-H

Abstract BCL2/adenovirus E1B 19-kDa protein-interacting protein 2 homolog (BNIP-H or Caytaxin), pivotal adaptor protein that facilitates cerebellar cortex growth and synaptic transmission, is post-translationally modified to regulate neuronal function. This study reports the ubiquitination of BNIP-H by CHIP (Carboxyl terminus of Hsc70-Interacting Protein), a U-box containing E3 ligase that is also regulated via autoubiquitination. Specifically, it was observed that CHIP autoubiquitinated itself primarily at Lys23 and Lys31 in-vitro. Mutation of these residues show the autoubiquitination of successive lysines of CHIP. In total, nine lysines on CHIP were identified as the autoubiquitination sites, the collective mutation of which completely terminated its autoubiquitination. Additionally, CHIP-mediated ubiquitination of BNIP-H is completely inhibited when BNIP-H bears arginine mutations at four key lysine residues. Next, using hydrogen deuterium exchange mass spectrometry a model of a plausible mechanism was proposed. The model suggests transient N-terminal interactions between the CHIP and BNIP-H which allows for the swinging of U-Box domain of CHIP to ubiquitinate BNIP-H. Following complex dissociation, BNIP-H population is regulated via the ubiquitin-proteasome pathway. Collectively, these results aid in our understanding of CHIP-mediated BNIP-H ubiquitination and provide further insight into the roles of these proteins in neuritogenesis and neurotransmission.

An inhibitory segment within G-patch activators tunes Prp43-ATPase activity during ribosome assembly

Mechanisms by which G-patch activators tune the processive multi-tasking ATP-dependent RNA helicase Prp43 (DHX15 in humans) to productively remodel diverse RNA:protein complexes remain elusive. Here, a comparative study between a herein and previously characterized activators, Tma23 and Pxr1, respectively, defines segments that organize Prp43 function during ribosome assembly. In addition to the activating G-patch, we discover an inhibitory segment within Tma23 and Pxr1, I-patch, that restrains Prp43 ATPase activity. Cryo-electron microscopy and hydrogen-deuterium exchange mass spectrometry show how I-patch binds to the catalytic RecA-like domains to allosterically inhibit Prp43 ATPase activity. Tma23 and Pxr1 contain dimerization segments that organize Prp43 into higher-order complexes. We posit that Prp43 function at discrete locations on pre-ribosomal RNA is coordinated through toggling interactions with G-patch and I-patch segments. This could guarantee measured and timely Prp43 activation, enabling precise control over multiple RNA remodelling events occurring concurrently during ribosome formation.

Hybrid Mass Spectrometry Applied across the Production of Antibody Biotherapeutics.

Post expression from the host cells, biotherapeutics undergo downstream processing steps before final formulation. Mass spectrometry and biophysical characterization methods are valuable for examining conformational and stoichiometric changes at these stages, although typically not used in biomanufacturing, where stability is assessed via bulk property studies. Here we apply hybrid MS methods to understand how solution condition changes impact the structural integrity of a biopharmaceutical across the processing pipeline. As an exemplar product, we use the model IgG1 antibody, mAb4. Flexibility, stability, aggregation propensity, and bulk properties are evaluated in relation to perfusion media, purification stages, and formulation solutions. Comparisons with Herceptin, an extensively studied IgG1 antibody, were conducted in a mass spectrometry-compatible solution. Despite presenting similar charge state distributions (CSD) in native MS, mAb4, and Herceptin show distinct unfolding patterns in activated ion mobility mass spectrometry (aIM-MS) and differential scanning fluorimetry (DSF). Herceptin's greater structural stability and aggregation onset temperature (Tagg) are attributed to heavier glycosylation and kappa-class light chains, unlike the lambda-class light chains in mAb4. Hydrogen-deuterium exchange mass spectrometry (HDX-MS) revealed that mAb4 undergoes substantial structural changes during purification, marked by high flexibility, low melting temperature (Tm), and prevalent repulsive protein-protein interactions but transitions to a compact and stable structure in high-salt and formulated environments. Notably, in formulation, the third constant domain (CH3) of the heavy chain retains flexibility and is a region of interest for aggregation. Future work could translate features of interest from comprehensive studies like this to targeted approaches that could be utilized early in the development stage to aid in decision-making regarding targeted mutations or to guide the design space of bioprocesses and formulation choices.

Rigidifying the β2-α2 Loop in the Mouse Prion Protein Slows down Formation of Misfolded Oligomers.

Transmissible Spongiform Encephalopathies are fatal neurodegenerative diseases caused by the misfolding of the cellular prion protein (PrPC) into its pathological isoform (PrPSc). Efficient transmission of PrPSc occurs within the same species, but a species barrier limits interspecies transmission. While PrP structure is largely conserved among mammals, variations at the β2-α2 loop are observed, and even minor changes in the amino acid sequence of the β2-α2 loop can significantly affect transmission efficiency. The present study shows that the introduction of the elk/deer-specific amino acid substitutions at positions 169 (Ser to Asn) and 173 (Asn to Thr) into the mouse prion protein, which are associated with the structural rigidity of the β2-α2 loop, has a substantial impact on protein dynamics as well as on the misfolding pathways of the protein. Native state hydrogen-deuterium exchange studies coupled with mass spectrometry, show that the rigid loop substitutions stabilize not only the β2-α2 loop but also the C-terminal end of α3, suggesting that molecular interactions between these two segments are strengthened. Moreover, the energy difference between the native state and multiple misfolding-prone partially unfolded forms (PUFs) present at equilibrium, is increased. The decreased accessibility of the PUFs from the native state leads to a slowing down of the misfolding of the protein. The results of this study provide important insights into the early events of conformational conversion of prion protein into β-rich oligomers, and add to the evidence that the β2-α2 loop is a key determinant in prion protein aggregation.

The mechanism of allosteric regulation of calcium-independent phospholipase A2 by ATP and calmodulin binding to the ankyrin domain

Group VIA calcium-independent phospholipase A2 (iPLA2) is a member of the PLA2 superfamily that exhibits calcium-independent activity in contrast to the other two major types, secreted phospholipase A2 (sPLA2) and cytosolic phospholipase A2 (cPLA2), which both require calcium for their enzymatic activity. Adenosine triphosphate (ATP) has been reported to allosterically activate iPLA2, and this has now been verified with a lipidomics-based mixed-micelle assay, but its mechanism of action has been unknown. Hydrogen/deuterium exchange mass spectrometry (HDX-MS) was employed to identify ATP interaction peptide regions located within the ankyrin repeat domain at which ATP interacts. Molecular dynamics simulations revealed the mechanism by which ATP binds to its site and the main residues that interact. Site-directed mutagenesis was used to verify the importance of these residues in the role of ATP in regulating iPLA2 activity. Importantly, calcium was found to abolish the enhancing regulatory function of ATP and to promote the inhibitory activity by calmodulin. Given previous evidence that calcium does not bind directly to iPLA2, its effect appears to be indirect via association with ATP and/or calmodulin. Using HDX-MS, we found that calmodulin interacts with the N terminus peptide region of iPLA2 consisting of residues 20 to 28. These two regulatory iPLA2 sites open the road to the development of potential targets for therapeutic intervention.

Allosteric regulation of the tyrosine phosphatase PTP1B by a protein-protein interaction.

Protein-protein interactions are critical for cell signaling. The interaction between the phosphatase PTP1B and adaptor protein Grb2 co-localizes PTP1B with its substrates, thereby enhancing their dephosphorylation. We show that Grb2 binding also directly modulates PTP1B activity through an allosteric mechanism involving the proline-rich region of PTP1B. Our study reveals a novel mode of PTP1B regulation through a protein-protein interaction that is likely to be exploited by other cellular interactors of this important signaling enzyme.

Decreasing the Uncertainty in the Comparison of Molecular Fingerprints of Organic Aerosols with H/D Exchange Mass Spectrometry.

High-resolution mass spectrometry (HRMS) has become an indispensable tool in the characterization of organic aerosols (OA) providing information on air quality, health assessment, climate trends, reactions, and source apportionment. Spectra-derived lists of formulas and their relative abundances are used to compare ambient OA from different sources or to monitor secondary OA formation under controlled laboratory conditions in smog chamber experiments. Various techniques are implemented to visualize common and unique features, series of precursors, and products. The disadvantage of this conventional approach is in associating elemental compositions to specific compounds, while due to several analytical limitations, the structural information remains hidden. We argue that some of the conclusions derived from this data analysis can be misleading. In this study, we applied in-ESI source H/D exchange (HDX), which facilitated enumeration of labile protons in molecules behind elemental compositions of OA. We applied this technique to compare OA from three different locations representing urban, forest, and marine environments and to examine tentative chemical information derived from Kendrick mass defect (KMD) series analysis. Significant discrepancies were found between numbers of labile protons in protogenic functional groups and the stoichiometry of chemical reactions, which are associated with KMD series. Only a portion of chemical pairs matched target stoichiometries, which highlights the existing limitations in environmental applications of conventional formula-based HRMS data interpretation strategies.

An antibody against human interleukin-2 showing minimal binding to neonatal Fc receptor: potent anti-tumor activity and reduced systemic toxicity in mice

The anti-tumor efficacy of immune checkpoint inhibitors can be enhanced by combining them with interleukin-2 (IL-2), which promotes the clonal expansion of antigen-activated CD8+ T cells and natural killer cells. However, IL-2 can simultaneously bind to endothelial cells and regulatory T cells to induce adverse and immunosuppressive effects. Such off-target binding can be inhibited by co-administering IL-2 with anti-IL-2 antibodies, but these antibodies can interact with neonatal Fc receptor to protect the IL-2 from lysosomal degradation, leading to substantial toxicity. Here we developed and humanized a mouse monoclonal antibody against human IL-2 and introduced two mutations (H310A and H435Q) in the Fc segment in order to weaken binding to the neonatal Fc receptor. The humanized antibody bound tightly to IL-2 but minimally to neonatal Fc receptor. Hydrogen deuterium exchange mass spectrometry indicated that the antibody binds to IL-2 at the site where the cytokine binds to subunit α (CD25) of the trimeric IL-2 receptor. Co-administering the antibody with human IL-2 improved the cytokine's ability to slow growth of two types of colorectal tumor xenografts (CT26, MC38) in immunocompetent mice. Co-administration to mice with CT26 xenografts strongly expanded CD8+ T cells, without expanding regulatory T cells in spleen or blood. Co-administration to mice with MC38 xenografts downregulated PD-1 and CD44, while upregulating CD62L and CD69, on tumor-infiltrating CD8+ T cells. Notably, co-administration synergized with anti-PD-1 antibody to slow growth of MC38 xenografts. Our results suggest that the combination of human IL-2 and our novel antibody shows promise for providing more effective, less toxic cancer immunotherapy.

Computational Tools for Hydrogen-Deuterium Exchange Mass Spectrometry Data Analysis.

Hydrogen-deuterium exchange (HDX) has become a pivotal method for investigating the structural and dynamic properties of proteins. The versatility and sensitivity of mass spectrometry (MS) made the technique the ideal companion for HDX, and today HDX-MS is addressing a growing number of applications in both academic research and industrial settings. The prolific generation of experimental data has spurred the concurrent development of numerous computational tools, designed to automate parts of the workflow while employing different strategies to achieve common objectives. Various computational methods are available to perform automated peptide searches and identification; different statistical tests have been implemented to quantify differences in the exchange pattern between two or more experimental conditions; alternative strategies have been developed to deconvolve and analyze peptides showing multimodal behavior; and different algorithms have been proposed to computationally increase the resolution of HDX-MS data, with the ultimate aim to provide information at the level of the single residue. This review delves into a comprehensive examination of the merits and drawbacks associated with the diverse strategies implemented by software tools for the analysis of HDX-MS data.

Conformational Differences in the Light Chain Constant Domain of Immunoglobulin G and Free Light Chain May Influence Proteolysis in AL Amyloidosis

Immunoglobulin light chain amyloidosis (AL) is a life-threatening disease caused by the deposition of light chain (LC) and its fragments containing variable (VL) and portions of constant (CL) domains. AL patients feature either monoclonal free LCs (FLCs) circulating as covalent and noncovalent homodimers, or monoclonal immunoglobulin (Ig) wherein the LC and heavy chain (HC) form disulfide-linked heterodimers, or both. The role of full-length Ig in AL amyloidosis is unclear as prior studies focused on FLC or VL domain. We used a mammalian cell-based expression system to generate four AL patient-derived full-length IgGs, two non-AL IgG controls, and six corresponding FLC proteins derived from an IGLV6-57 germline precursor. Comparison of proteins’ secondary structure, thermal stability, proteolytic susceptibility, and disulfide link reduction suggested the importance of local vs. global conformational stability. Analysis of IgGs vs. corresponding FLCs using hydrogen–deuterium exchange mass spectrometry revealed major differences in the local conformation/dynamics of the CL domain. In all IgGs vs. FLCs, segments containing β-strand and α-helix βAC-αACBC were more dynamic/exposed while segment βDC-βEC was less dynamic/exposed. Notably, these segments overlapped proteolysis-prone regions whose in vivo cleavage generates LC fragments found in AL deposits. Altogether, the results suggest that preferential cleavage in segments βAC-αACBC of FLC or βDC-βEC of LC in IgG helps generate amyloid protein precursors. We propose that protecting these segments using small-molecule stabilizers, which bind to the interfacial cavities CL-CL in FLC and/or CL-CH1 in IgG, is a potential therapeutic strategy to complement current approaches targeting VL-VL or VL-CL stabilization of LC dimer.

Ligand-induced conformational changes in the β1-adrenergic receptor revealed by hydrogen-deuterium exchange mass spectrometry.

G Protein Coupled Receptors (GPCRs) constitute the largest family of signalling proteins responsible for translating extracellular stimuli into intracellular functions. They play crucial roles in numerous physiological processes and are major targets for drug discovery. Dysregulation of GPCRs is implicated in various diseases, making understanding their structural dynamics critical for therapeutic development. Here, we use Hydrogen Deuterium Exchange Mass Spectrometry (HDX-MS) to explore the structural dynamics of the turkey β1-adrenergic receptor (tβ1AR) bound with nine different ligands, including agonists, partial agonists, and antagonists. We find that these ligands induce distinct dynamic patterns across the receptor, which can be grouped by compound modality. Notably, full agonist binding destabilises the intracellular loop 1 (ICL1), while antagonist binding stabilises it, highlighting ICL1's role in G protein recruitment. Our findings indicate that the conserved L72 residue in ICL1 is crucial for maintaining receptor structural integrity and stabilising the GDP-bound state. Overall, our results provide a platform for determining drug modality and highlight how HDX-MS can be used to dissect receptor ligand interaction properties and GPCR mechanism.

Peptide Activator Stabilizes DJ-1 Structure and Enhances Its Activity

DJ-1 is a vital enzyme involved in the maintenance of mitochondrial health, and its mutation has been associated with an increased risk of Parkinson’s disease (PD). Effective regulation of DJ-1 activity is essential for the well-being of mitochondria, and DJ-1 is thus a potential target for PD drug development. In this study, two peptides (15EEMETIIPVDVMRRA29 and 47SRDVVICPDA56) were utilized with the aim of enhancing the activity of DJ-1. The mechanisms underlying the activity enhancement by these two peptides were investigated using hydrogen/deuterium exchange mass spectrometry (HDXMS). The HDXMS results revealed distinct mechanisms. Peptide 1 obstructs the access of solvent to the dimer interface and stabilizes the α/β hydrolase structure, facilitating substrate binding to a stabilized active site. Conversely, peptide 2 induces a destabilization of the α/β hydrolase core, enhancing substrate accessibility and subsequently increasing DJ-1 activity. The binding of these two peptides optimizes the activity site within the dimeric structure. These findings offer valuable insights into the mechanisms underlying the activity enhancement of DJ-1 by the two peptides, potentially aiding the development of new drugs that can enhance the activity of DJ-1 and, consequently, advance PD treatment.

Strategies for Top-Down Hydrogen Deuterium Exchange-Mass Spectrometry: A Mini Review and Perspective.

Hydrogen deuterium-exchange mass spectrometry (HDX-MS) is commonly used in the study of protein dynamics and protein interactions. By measuring the isotopic exchange of backbone amide hydrogens in solution, HDX-MS offers valuable structural insights into challenging biological systems. Traditional HDX-MS approaches utilize bottom-up (BU) proteomics, in which deuterated proteins are digested before MS analysis. BU-HDX enables the characterization of proteins with various sizes in simple protein mixtures or complex biological samples such as cell lysates. However, BU methods are inherently limited by the inability to resolve protein sub-populations arising from different protein conformations, such as those arising from post-translational modifications (PTMs). Alternatively, top-down (TD) HDX-MS detects the global deuterium uptake at the intact proteoform level, allowing direct probing of structural changes due to protein-protein interactions, PTMs, or conformational changes. Combining TD-HDX-MS with electron-based fragmentation techniques, such as electron capture dissociation (ECD) and electron transfer dissociation (ETD), has demonstrated the feasibility of studying intact protein interactions with amino acid-level resolution. Here, we present a brief overview of methodologies, limitations, and applications of TD-HDX-MS using direct infusion techniques and LC-based approaches. Furthermore, we conclude with a perspective on the future directions for TD-HDX-MS.

Small Molecule Assembly Agonist Alters the Dynamics of Hepatitis B Virus Core Protein Dimer and Capsid.

Chronic hepatitis B virus (HBV) poses a significant public health burden worldwide, encouraging the search for curative antivirals. One approach is capsid assembly modulators (CAMs), which are assembly agonists. CAMs lead to empty and defective capsids, inhibiting the formation of new viruses, and can also lead to defects in the release of the viral genome, inhibiting new infections. In this study, we employed hydrogen-deuterium exchange mass spectrometry (HDX-MS) to assess the impact of one such CAM, HAP18, on HBV dimers, capsids composed of 120 (or 90) capsid protein dimers, and cross-linked capsids (xl-capsids). HDX analysis revealed hydrogen bonding networks within and between the dimers. HAP18 disrupted the hydrogen bonding network of dimers, demonstrating a previously unappreciated impact on the dimer structure. Conversely, HAP18 stabilized both unmodified and cross-linked capsids. Intriguingly, cross-linking the capsid, which was accomplished by forming disulfides between an engineered C-terminal cysteine, increased the overall rate of HDX. Moreover, HAP18 binding induced conformational changes beyond the binding sites. Our findings provide evidence for allosteric communication within and between capsid protein dimers. These results show that CAMs are capable of harnessing this allosteric network to modulate the dimer and capsid dynamics.

Quantitative Assessment of Conformational Heterogeneity in Apolipoprotein E4 Using Hydrogen-Deuterium Exchange Mass Spectrometry.

Apolipoprotein E4 (apoE4) is the strongest genetic risk factor for Alzheimer's disease (AD). However, structural differences between apoE4 and the AD-neutral isoform, apoE3, still remain unclear. Recent studies suggest that apoE4 harbors intermediates. However, the biophysical properties and isoform specificity of these intermediates are not known. Here, we use the kinetics of hydrogen-deuterium exchange by mass spectrometry (HDX-MS) to examine the conformational heterogeneities in apoE3 and apoE4. First, we use numerical simulations to compute the HDX-mass spectra of a protein following mixed EX1/EX2 kinetics. The results indicate that in the presence of EX1 kinetics, which is an indicator of conformational heterogeneity, time evolution of the standard deviation (σ(t)) of the spectra exhibits a clear peak, which is dependent on the number of residues (NEX1) and the rate constant of EX1 kinetics (kEX1). Then, we performed experiments with several variants of the apoE proteins and compared them with simulation to estimate NEX1 and kEX1. Kinetics of the mean deuteration is found to be faster for apoE4, consistent with its poorer stability than apoE3. Importantly, in the case of apoE4, σ(t) exhibits a clear peak at t ∼ 60 s, but apoE3 shows only a small peak at 1800 s. Therefore, both NEX1 and kEX1 are larger for apoE4, indicating greater conformational heterogeneity. Notably, the partial EX1 kinetics is observed in both the isolated N-terminal fragment and the full-length form of apoE4, although it is more pronounced in the full-length protein. Moreover, it is enhanced at higher pH and in the presence of bis-ANS. Mutations such as R61T and R112I diminish the EX1 kinetics, making apoE4 behave more like apoE3. Thus, the amino acid substitution at position 112 alters the structural dynamics of the N-terminal domain of apoE4; the changes are further propagated and amplified in the full-length protein. We conclude that HDX-MS is a label-free and robust methodology to characterize structural heterogeneities of proteins even under native conditions. This opens opportunities for screening of the "structure corrector" drug molecules that could convert apoE4 to apoE3-like.

Mechanistic insight into multiple antibody binding to ADAMTS13 in immune thrombotic thrombocytopenic purpura

BackgroundAntibody-mediated inhibition of von Willebrand factor (VWF) cleavage by ADAMTS-13 results in immune thrombotic thrombocytopenic purpura (iTTP). However, the effects of multiple antibody binding to ADAMTS-13 are not fully understood. ObjectivesTo determine how multiple antibodies affect ADAMTS13 activity under various conditions. MethodsSingle-chain fragments of the variable region isolated via phage display from patients with iTTP, FRETS-VWF73, native ADAMTS-13 in normal human plasma, and hydrogen-deuterium exchange plus mass spectrometry were used. ResultsWe found that 2 stimulatory antibodies affect ADAMTS-13 turnover rate more than its substrate recognition. Hydrogen-deuterium exchange plus mass spectrometry revealed that 1 of these 2 stimulatory antibodies bound to the CUB2 domain that presumably interacts with the spacer domain of ADAMTS-13. Spacer domain is targeted by most inhibitory antibodies in iTTP. Both inhibitory and stimulating antibodies could bind ADAMTS-13 simultaneously but when both were present the inhibitory activity predominates. The antibody-mediated stimulation was lost, but the inhibition persisted when a modified substrate with the amino acid residue leucine at position 1603 of VWF was replaced by an alanine (VWF73-L1603A), interfering with active site binding. ConclusionThese results support the hypothesis that the mechanism of action of both stimulatory and inhibitory anti-ADAMTS-13 antibodies in iTTP is through allosteric modification of the catalytic domain and that inhibition of ADAMTS-13 dominates when both are present. Our findings may provide a new avenue of exploration to develop targeted diagnostic and therapeutic approaches in the management of iTTP.

Catalysis on Mono- and Bimetallic Nanoparticles of the Silver–Copper System Cu<sub><i>n</i></sub>Ag<sub><i>m</i></sub>

The purpose of this work is to study the catalytic properties of mono- and bimetallic nanoparticles of the copper-silver system of variable composition supported on aluminum oxide in the conversion reactions of protium modifications and deuterium-hydrogen exchange. From a comparison of the temperature dependences of the specific catalytic activity of the samples in the two reactions under study, a conclusion was drawn about different reaction mechanisms. It has been shown that, compared to bulk metals, nanoparticles of the CunAgm composition have catalytic properties in a wide temperature range, up to 77 K. In the chemical reaction of isotope exchange in molecular hydrogen, a synergistic effect is observed, which indicates the interaction of metals in biparticles.

Activation of parkin by a molecular glue

Mutations in parkin and PINK1 cause early-onset Parkinson’s disease (EOPD). The ubiquitin ligase parkin is recruited to damaged mitochondria and activated by PINK1, a kinase that phosphorylates ubiquitin and the ubiquitin-like domain of parkin. Activated phospho-parkin then ubiquitinates mitochondrial proteins to target the damaged organelle for degradation. Here, we present the mechanism of activation of a new class of small molecule allosteric modulators that enhance parkin activity. The compounds act as molecular glues to enhance the ability of phospho-ubiquitin (pUb) to activate parkin. Ubiquitination assays and isothermal titration calorimetry with the most active compound (BIO-2007817) identify the mechanism of action. We present the crystal structure of a closely related compound (BIO-1975900) bound to a complex of parkin and two pUb molecules. The compound binds next to pUb on RING0 and contacts both proteins. Hydrogen-deuterium exchange mass spectrometry (HDX-MS) experiments confirm that activation occurs through release of the catalytic Rcat domain. In organello and mitophagy assays demonstrate that BIO-2007817 partially rescues the activity of parkin EOPD mutants, R42P and V56E, offering a basis for the design of activators as therapeutics for Parkinson’s disease.