Project description:Ubiquitin ligases (E3s) are pivotal specificity determinants in the ubiquitin system by selecting substrates and decorating them with distinct ubiquitin signals. Structure determination of the underlying, specific E3-substrate complexes, however, has proven challenging due to their transient nature. In particular, it is incompletely understood how members of the catalytic cysteine-driven class of HECT-type ligases position substrate proteins for modification. Here we report a cryo-EM structure of the full-length human HECT-type ligase HACE1, along with solution-based conformational analyses by small-angle X-ray scattering and hydrogen-deuterium exchange mass spectrometry. Structure-based functional analyses in vitro and in cells reveal that the activity of HACE1 is stringently regulated by dimerization-induced autoinhibition. The inhibition occurs at the first step of the catalytic cycle and is thus substrate-independent. We employ mechanism-based chemical crosslinking to reconstitute a complex of activated, monomeric HACE1 with its major substrate, RAC1, visualize its structure by cryo-EM, and validate the binding mode by solution-based analyses. Our findings explain how HACE1 achieves selectivity in ubiquitinating the active, GTP-loaded state of RAC1 and establish a framework for interpreting mutational alterations of the HACE1-RAC1 interplay in disease. More broadly, this work illuminates central unexplored aspects in the architecture, conformational dynamics, regulation, and specificity of full-length HECT-type ligases.

Project description:SARS-CoV-2, a human coronavirus, is the causative agent of the COVID-19 pandemic, entailing enormous disruption worldwide. Its ~30 kb RNA genome is translated into two large polyproteins subsequently cleaved by viral papain-like protease and main protease (Mpro/nsp5). Polyprotein processing is essential yet incompletely understood. We studied Mpro-mediated processing of the nsp7-10/11 polyprotein, whose mature products are cofactors of the viral replicase, identifying the order of cleavages: 1) nsp9-10, 2) nsp8-9/nsp10-11, and 3) nsp7-8. Integrative modeling based on mass spectrometry (including hydrogen-deuterium exchange and cross-linking) and X-ray scattering yielded three-dimensional models of the nsp7-10/11 polyprotein, and the data suggest that the nsp7-10/11 structure in complex with Mpro strongly resembles the unbound polyprotein. Our array of techniques supports the notion that interplay between polyprotein conformation and junction accessibility determine the preference and order of cleavages. Finally, we leveraged assays of limited proteolysis by Mpro of nsp7-11 using a series of inhibitors/binders to characterize Mpro inhibition using a polyprotein substrate.

Project description:Interrogration of impacts on Hydrogen Deuterium Exchange of ligand binding using heterobifunctional molecules ACBi1(SiTX-0038406), PROTAC1(SiTX-0038404) and PROTAC2(SiTX-0038405) on target proteins SMARCA2 and VHL both in the binary and Ternary modes.

Project description:The dopamine transporter facilitates dopamine reuptake from the extracellular space to terminate neurotransmission. The transporter belongs to the neurotransmitter:sodium symporter family, which includes transporters for serotonin, norepinephrine, and GABA that utilize the Na+ gradient to drive the uptake of substrate. Decades ago, it was shown that the serotonin transporter also antiports K+, but investigations of K+-coupled transport in other neurotransmitter:sodium symporters have been inconclusive. Here, we show that ligand binding to the drosophila- and human dopamine transporters are inhibited by K+, and the conformational dynamics of the drosophila dopamine transporter in K+ are divergent from the apo- and Na+-states. Furthermore, we found that K+ increased dopamine uptake by the drosophila dopamine transporter in liposomes, and visualized Na+ and K+ fluxes in single proteoliposomes using fluorescent ion indicators. Our results expand on the fundamentals of dopamine transport and prompt a reevaluation of the impact of K+ on other transporters in this pharmacologically important family.

Project description:Poly(A)-binding protein (Pab1), a canonical stress granule marker, condenses upon heat shock or starvation, promoting adaptation, The molecular basis of condensation has remained elusive due to a dearth of techniques to probe structure directly in condensates. Here we apply hydrogendeuterium exchange/mass spectrometry (HDX-MS) to investigate the molecular mechanism of Pab1’s condensation. We find that Pab1’s four RNA recognition motifs (RRMs) undergo different levels of partial unfolding upon condensation, and the changes are similar for thermal and pH stresses. Although structural heterogeneity is observed, the ability of MS to describe individual subpopulations allows us to identify which regions become partially unfolded and contribute to the condensate’s interaction network. Our data yield a clear molecular picture of Pab1’s stresstriggered condensation, which we term sequential activation, wherein each RRM becomes activated at a temperature where it partially unfolds and associates with other likewise activated RRMs to form the condensate. This model thus implies that sequential activation is dictated by the underlying free energy surface, an effect we refer to as thermodynamic specificity. Our study represents a methodological advance for elucidating the interactions that drive biomolecular condensation that we anticipate will be widely applicable. Furthermore, our findings demonstrate how condensation can use thermodynamic specificity to perform an acute response to multiple stresses, a potentially general mechanism for stress-responsive proteins.

Project description:Tripartite resistance nodulation and cell division multidrug efflux pumps span the periplasm and are major drivers of multidrug resistance among Gram-negative bacteria. Cations, such as Mg2+, become concentrated within the periplasm and, in contrast to the cytoplasm, it’s pH is sensitive to conditions outside the cell. Here, we reveal an interplay between Mg2+ and pH in modulating the structural dynamics of the periplasmic adaptor protein, AcrA, and its function within the prototypical AcrAB-TolC multidrug pump from Escherichia coli. In the absence of Mg2+, AcrA becomes increasingly plastic within acidic conditions, but when Mg2+ is bound this is ameliorated, resulting instead in domain specific organisation. We establish a unique histidine residue directs these dynamics and is essential for sustaining pump activity across acidic, neutral, and basic regimes. Overall, we propose Mg2+ conserves AcrA structural mobility to ensure optimal AcrAB-TolC function within rapid changing environments commonly faced during bacterial infection and colonization.

Project description:Immunoglobulin Gs (IgGs) have become highly successful drug scaffolds by combining very specific target binding with the ability to induce cellular cytotoxicity. Of further advantage, IgGs possess unusually long half-lives in the blood (2-3 week). IgGs achieve such extraordinary half-lives through a pH-dependent interaction with the Neonatal Fc receptor (FcRn) whereby IgGs are recycled. No high-resolution structure of FcRn in complex with a full-length IgG is available, and the interaction was long thought to be mediated solely via the IgG Fc. However, some IgGs with identical Fc parts, but different Fab domains, exhibit different half-lives, suggesting involvement of the Fab domains in FcRn binding. Here, we have employed a combination of HDX-MS and cross-linking MS (XL-MS) to explore the interaction of a full-length IgG with FcRn. HDX-MS and XL-MS analysis confirms an interaction between FcRn and the Fc-domain of IgGs, as a reduction of HDX was observed in both the Fc-domain and FcRn upon complex formation, and three cross-links were identified between FcRn and the Fc-domain. However, FcRn-induced changes in HDX were also observed in the Fab domains, supported by multiple cross-links between the Fab domains and the C-terminal α3 domain of FcRn. Our results thus provide direct evidence for a Fab-FcRn interaction. We envision that these result could advance the engineering of therapeutic IgGs with tailored pharmacokinetics and enhanced efficacy.

Project description:Liver receptor homolog-1 (LRH-1) is a phospholipid-sensing nuclear receptor that has shown promise as a target for alleviat-ing intestinal inflammation and disease states characterized by metabolic dysregulation in the liver. LRH-1 contains an unu-sually large ligand binding pocket, and generating synthetic modulators has been challenging. Leveraging a hexahydropen-talene (6HP) core, we have had recent success in generating potent and efficacious agonists through two distinct strategies. We targeted residues deep within the pocket to enhance compound binding, while residues at the mouth of the pocket were targeted to mimic interactions made by endogenous phospholipids. Here, we unite these two designs into one hybrid mole-cule that is the most potent LRH-1 agonist to date. Through a combination of global transcriptomic, biochemical, and struc-tural studies, we show that selective modulation can be driven through contacting deep vs. surface polar regions in the pock-et. While deep pocket contacts convey high-affinity, contacts with the pocket mouth dominate allostery and provide a phos-pholipid-like transcriptional response in cultured cells.

Project description:Nicotinamide nucleotide transhydrogenases are integral membrane proteins that utilizes the proton motive force to reduce NADP+ to NADPH while converting NADH to NAD+. Atomic structures of various transhydrogenases in different ligand-bound states have become available, and it is clear that the molecular mechanism involves major conformational changes. Here we utilized hydrogen-deuterium-exchange mass spectrometry (HDX-MS) to map ligand binding sites and analyzed the structural dynamics of E. coli transhydrogenase. We found different allosteric effects on the protein depending on the bound ligand (NAD+, NADH, NADP+, NADPH). The binding of either NADP+ or NADPH to domain III had pronounced effects on the transmembrane helices comprising the proton-conducting channel in domain II. We also made use of cyclic ion mobility separation mass spectrometry (cyclic IMS-MS) to maximize coverage and sensitivity in the transmembrane domain, showing for the first time that this technique can be used for HDX-MS studies. Using cyclic IMS-MS, we increased sequence coverage from 68% to 73% in the transmembrane segments. Taken together, our results provide important new insights into the transhydrogenase reaction cycle and demonstrate the benefit of this new technique for HDX-MS to study ligand binding and conformational dynamics in membrane proteins.

Project description:Pyk2 is a multidomain non-receptor tyrosine kinase that undergoes a complex, multi-stage activation process. Ca2+-flux induces conformational rearrangements that relieve autoinhibitory FERM domain interactions. The kinase domain phosphorylates a key linker residue to recruit Src kinase. Pyk2 and Src mutually phosphorylate activation loop residues to confer full activation. While the mechanisms of autoinhibition are established, the conformational dynamics associated with autophosphorylation and Src recruitment remain unclear. Here, we employ hydrogen/deuterium exchange mass spectrometry (HDX-MS) to map the conformational changes associated with Src-mediated activation segment phosphorylation in a Pyk2 construct encompassing FERM and kinase domains (residues 20-692). Results reveal increased dynamics at regulatory interfaces spanning FERM and kinase domains. Phosphorylation of the activation segment stabilizes two antiparallel beta strands linking activation and catalytic loops. Increased dynamics of the C-terminal end of the activation loop propagate to the F-helix, explaining how phosphorylation prevents reversion to the autoinhibitory FERM interaction. HDX-guided site-directed mutagenesis and kinase activity profiling establish a mechanism for phosphorylation-induced active site sculpting to confer high activity.