Project description:Neurotransmitter/sodium symporters (NSSs) couple the uptake of neurotransmitter with one or more sodium ions, removing neurotransmitter from the synaptic cleft. NSSs are essential to the function of chemical synapses, are associated with multiple neurological diseases and disorders, and are the targets of therapeutic and illicit drugs. LeuT, a prokaryotic orthologue of the NSS family, is a model transporter for understanding the relationships between molecular mechanism and atomic structure in a broad range of sodium-dependent and sodium-independent secondary transporters. At present there is a controversy over whether there are one or two high-affinity substrate binding sites in LeuT. The first-reported crystal structure of LeuT, together with subsequent functional and structural studies, provided direct evidence for a single, high-affinity, centrally located substrate-binding site, defined as the S1 site. Recent binding, flux and molecular simulation studies, however, have been interpreted in terms of a model where there are two high-affinity binding sites: the central, S1, site and a second, the S2 site, located within the extracellular vestibule. Furthermore, it was proposed that the S1 and S2 sites are allosterically coupled such that occupancy of the S2 site is required for the cytoplasmic release of substrate from the S1 site. Here we address this controversy by performing direct measurement of substrate binding to wild-type LeuT and to S2 site mutants using isothermal titration calorimetry, equilibrium dialysis and scintillation proximity assays. In addition, we perform uptake experiments to determine whether the proposed allosteric coupling between the putative S2 site and the S1 site manifests itself in the kinetics of substrate flux. We conclude that LeuT harbours a single, centrally located, high-affinity substrate-binding site and that transport is well described by a simple, single-substrate kinetic mechanism.

Project description:It is well known that Galpha(i1)(GDP) binds strongly to Gbetagamma subunits to form the Galpha(i1)(GDP)-Gbetagamma heterotrimer, and that activation to Galpha(i1)(GTP) results in conformational changes that reduces its affinity for Gbetagamma subunits. Previous studies of G protein subunit interactions have used stoichiometric amounts of the proteins. Here, we have found that Galpha(i1)(GDP) can bind a second Gbetagamma subunit with an affinity only 10-fold weaker than the primary site and close to the affinity between activated Galpha(i1) and Gbetagamma subunits. Also, we find that phospholipase Cbeta2, an effector of Gbetagamma, does not compete with the second binding site implying that effectors can be bound to the Galpha(i1)(GDP)-(Gbetagamma)(2) complex. Biophysical measurements and molecular docking studies suggest that this second site is distant from the primary one. A synthetic peptide having a sequence identical to the putative second binding site on Galpha(i1) competes with binding of the second Gbetagamma subunit. Injection of this peptide into cultured cells expressing eYFP-Galpha(i1)(GDP) and eCFP-Gbetagamma reduces the overall association of the subunits suggesting this site is operative in cells. We propose that this second binding site serves to promote and stabilize G protein subunit interactions in the presence of competing cellular proteins.

Project description:The first crystal structure of the neurotransmitter/sodium symporter homolog LeuT revealed an occluded binding pocket containing leucine and 2 Na(+); later structures showed tricyclic antidepressants (TCAs) in an extracellular vestibule approximately 11 A above the bound leucine and 2 Na(+). We recently found this region to be a second binding (S2) site and that binding of substrate to this site triggers Na(+)-coupled substrate symport. Here, we show a profound inhibitory effect of n-octyl-beta-d-glucopyranoside (OG), the detergent used for LeuT crystallization, on substrate binding to the S2 site. In parallel, we determined at 2.8 A the structure of LeuT-E290S, a mutant that, like LeuT-WT, binds 2 substrate molecules. This structure was similar to that of WT and clearly revealed an OG molecule in the S2 site. We also observed electron density at the S2 site in LeuT-WT crystals, and this also was accounted for by an OG molecule in that site. Computational analyses, based on the available crystal structures of LeuT, indicated the nature of structural arrangements in the extracellular region of LeuT that differentiate the actions of substrates from inhibitors bound in the S2 site. We conclude that the current LeuT crystal structures, all of which have been solved in OG, represent functionally blocked forms of the transporter, whereas a substrate bound in the S2 site will promote a different state that is essential for Na(+)-coupled symport.

Project description:Recent advances in quantitative proteomics show that WD40 proteins play a pivotal role in numerous cellular networks. Yet, they have been fairly unexplored and their physical associations with other proteins are ambiguous. A quantitative understanding of these interactions has wide-ranging significance. WD40 repeat protein 5 (WDR5) interacts with all members of human SET1/MLL methyltransferases, which regulate methylation of the histone 3 lysine 4 (H3K4). Here, using real-time binding measurements in a high-throughput setting, we identified the kinetic fingerprint of transient associations between WDR5 and 14-residue WDR5 interaction (Win) motif peptides of each SET1 protein (SET1Win). Our results reveal that the high-affinity WDR5-SET1Win interactions feature slow association kinetics. This finding is likely due to the requirement of SET1Win to insert into the narrow WDR5 cavity, also named the Win binding site. Furthermore, our explorations indicate fairly slow dissociation kinetics. This conclusion is in accordance with the primary role of WDR5 in maintaining the functional integrity of a large multisubunit complex, which regulates the histone methylation. Because the Win binding site is considered a key therapeutic target, the immediate outcomes of this study could form the basis for accelerated developments in medical biotechnology.

Project description:Early warning indicators based on critical slowing down have been suggested as a model-independent and low-cost tool to anticipate the (re)emergence of infectious diseases. We studied whether such indicators could reliably have anticipated the second COVID-19 wave in European countries. Contrary to theoretical predictions, we found that characteristic early warning indicators generally decreased rather than increased prior to the second wave. A model explains this unexpected finding as a result of transient dynamics and the multiple timescales of relaxation during a non-stationary epidemic. Particularly, if an epidemic that seems initially contained after a first wave does not fully settle to its new quasi-equilibrium prior to changing circumstances or conditions that force a second wave, then indicators will show a decreasing rather than an increasing trend as a result of the persistent transient trajectory of the first wave. Our simulations show that this lack of timescale separation was to be expected during the second European epidemic wave of COVID-19. Overall, our results emphasize that the theory of critical slowing down applies only when the external forcing of the system across a critical point is slow relative to the internal system dynamics.

Project description:A parallel quadruplex derived from the Myc promoter sequence was extended by a stem-loop duplex at either its 5'- or 3'-terminus to mimic a quadruplex-duplex (Q-D) junction as a potential genomic target. High-resolution structures of the hybrids demonstrate continuous stacking of the duplex on the quadruplex core without significant perturbations. An indoloquinoline ligand carrying an aminoalkyl side chain was shown to bind the Q-D hybrids with a very high affinity in the order Ka ?107 ?m-1 irrespective of the duplex location at the quadruplex 3'- or 5'-end. NMR chemical shift perturbations identified the tetrad face of the Q-D junction as specific binding site for the ligand. However, calorimetric analyses revealed significant differences in the thermodynamic profiles upon binding to hybrids with either a duplex extension at the quadruplex 3'- or 5'-terminus. A large enthalpic gain and considerable hydrophobic effects are accompanied by the binding of one ligand to the 3'-Q-D junction, whereas non-hydrophobic entropic contributions favor binding with formation of a 2:1 ligand-quadruplex complex in case of the 5'-Q-D hybrid.

Project description:The homodimer NGF (nerve growth factor) exerts its neuronal activity upon binding to either or both distinct transmembrane receptors TrkA and p75(NTR). Functionally relevant interactions between NGF and these receptors have been proposed, on the basis of binding and signaling experiments. Namely, a ternary TrkA/NGF/p75(NTR) complex is assumed to be crucial for the formation of the so-called high-affinity NGF binding sites. However, the existence, on the cell surface, of direct extracellular interactions is still a matter of controversy. Here, supported by a small-angle x-ray scattering solution study of human NGF, we propose that it is the oligomerization state of the secreted NGF that may drive the formation of the ternary heterocomplex. Our data demonstrate the occurrence in solution of a concentration-dependent distribution of dimers and dimer of dimers. A head-to-head molecular assembly configuration of the NGF dimer of dimers has been validated. Overall, these findings prompted us to suggest a new, to our knowledge, model for the transient ternary heterocomplex, i.e., a TrkA/NGF/p75(NTR) ligand/receptors molecular assembly with a (2:4:2) stoichiometry. This model would neatly solve the problem posed by the unconventional orientation of p75(NTR) with respect to TrkA, as being found in the crystal structures of the TrkA/NGF and p75(NTR)/NGF complexes.

Project description:A common strategy for exploring the biological roles of deubiquitinating enzymes (DUBs) in different pathways is to study the effects of replacing the wild-type DUB with a catalytically inactive mutant in cells. We report here that a commonly studied DUB mutation, in which the catalytic cysteine is replaced with alanine, can dramatically increase the affinity of some DUBs for ubiquitin. Overexpression of these tight-binding mutants thus has the potential to sequester cellular pools of monoubiquitin and ubiquitin chains. As a result, cells expressing these mutants may display unpredictable dominant negative physiological effects that are not related to loss of DUB activity. The structure of the SAGA DUB module bound to free ubiquitin reveals the structural basis for the 30-fold higher affinity of Ubp8C146A for ubiquitin. We show that an alternative option, substituting the active site cysteine with arginine, can inactivate DUBs while also decreasing the affinity for ubiquitin.

Project description:We have previously identified a cyclic peptide called meditope which binds to the central cavity of the Fab portion of cetuximab and shown that this peptide binding site can be grafted, or 'meditope-enabled', onto trastuzumab. This peptide has been shown to act as a hitch for the non-covalent attachment of imaging agents to meditope-enabled antibodies. Herein, we explore the process of grafting this peptide binding site onto M5A, an anti-CEA antibody in clinical trials for cancer diagnostics. In order to explore the contributions of the amino acids, we sequentially introduced pairs of amino acid substitutions into the Fab and then we reverse-substituted key residues in the presence of the other substitutions. We demonstrate that Pro40Thr, Gly41Asn, Phe83Ile and Thr85Asp in the light chain are sufficient to recreate the meditope binding site in M5A with single-digit micromolar affinity. We show that Pro40 abrogates peptide binding in the presence of the other 12 residue substitutions, and that the presence of all 13 substitutions does not interfere with antibody:antigen recognition. Collectively, these studies provide detailed insight for defining and fine-tuning the binding affinity of the meditope binding site within an antibody.

Project description:Kainate receptors are allosterically regulated by sodium ions. Removal of Na+ from the extracellular solution, or replacement of Na+ by larger monovalent cations, inhibits kainate receptor activity. Sodium binds at a negatively charged cavity in the extracellular neurotransmitter binding domain that is capped by a small hydrophobic residue. Prior work revealed that introduction of aspartic acid at this site strongly reduces GluK2 sensitivity to monovalent cations of different size. We found that the GluK2 M739D mutant is also insensitive to substitution of Na+ by the large organic cations Tris and NMDG. Because these are excluded from the Na+ binding site by steric hindrance, we investigated the possibility that divalent cations can substitute for Na+. We show that in Na+ free solutions with low concentrations of Ca2+ and Mg2+ the GluK2 M739D mutant is inhibited by EDTA; that divalent ions in the micromolar concentration range act as positive allosteric modulators; and that the chemistry of the mutant cation binding site is typical of Ca2+ and Mg2+ binding sites found in protein crystal structures. Hence, the apparent insensitivity of the M739D mutant to monovalent cations is due to the adventitious allosteric effects of divalent ions at physiological concentrations and below.