Capturing Conformational States in Proteins Using Sparse Paramagnetic NMR Data

Capturing conformational changes in proteins or protein-protein complexes is a challenge for both experimentalists and computational biologists. Solution nuclear magnetic resonance (NMR) is unique in that it permits structural studies of proteins under greatly varying conditions, and thus allows us to monitor induced structural changes. Paramagnetic effects are increasingly used to study protein structures as they give ready access to rich structural information of orientation and long-range distance restraints from the NMR signals of backbone amides, and reliable methods have become available to tag proteins with paramagnetic metal ions site-specifically and at multiple sites. In this study, we show how sparse pseudocontact shift (PCS) data can be used to computationally model conformational states in a protein system, by first identifying core structural elements that are not affected by the environmental change, and then computationally completing the remaining structure based on experimental restraints from PCS. The approach is demonstrated on a 27 kDa two-domain NS2B-NS3 protease system of the dengue virus serotype 2, for which distinct closed and open conformational states have been observed in crystal structures. By changing the input PCS data, the observed conformational states in the dengue virus protease are reproduced without modifying the computational procedure. This data driven Rosetta protocol enables identification of conformational states of a protein system, which are otherwise difficult to obtain either experimentally or computationally.     

Conformational Control of Translation Termination on the 70S Ribosome

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Conformational Sampling of Aminoacyl-tRNA during Selection on the Bacterial Ribosome

Aminoacyl-tRNA (aa-tRNA), in a ternary complex with elongation factor-Tu and GTP, enters the aminoacyl (A) site of the ribosome via a multi-step, mRNA codon-dependent mechanism. This process gives rise to the preferential selection of cognate aa-tRNAs for each mRNA codon and, consequently, the fidelity of gene expression. The ribosome actively facilitates this process by recognizing structural features of the correct substrate, initiated in its decoding site, to accelerate the rates of elongation factor-Tu-catalyzed GTP hydrolysis and ribosome-catalyzed peptide bond formation. Here, the order and timing of conformational events underpinning the aa-tRNA selection process were investigated from multiple structural perspectives using single-molecule fluorescence resonance energy transfer. The time resolution of these measurements was extended to 2.5 and 10 ms, a 10- to 50-fold improvement over previous studies. The data obtained reveal that aa-tRNA undergoes fast conformational sampling within the A site, both before and after GTP hydrolysis. This suggests that the alignment of aa-tRNA with respect to structural elements required for irreversible GTP hydrolysis and peptide bond formation plays a key role in the fidelity mechanism. These observations provide direct evidence that the selection process is governed by motions of aa-tRNA within the A site, adding new insights into the physical framework that helps explain how the rates of GTP hydrolysis and peptide bond formation are controlled by the mRNA codon and other fidelity determinants within the system.     

High-Resolution Ribosome Profiling Defines Discrete Ribosome Elongation States and Translational Regulation during Cellular Stress

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Capturing the Conformational Ensemble of the Mixed Folded Polyglutamine Protein Ataxin-3

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在美国进行植物药开发的路径、要求及策略探讨

近年来,越来越多药企开始在美国进行植物药的临床试验申请和新药申报,美国 FDA 日益重视植物药的开发,于 2016 年 12 月 发布并实施了修订版的《行业指南:植物药》,为植物药后期开发提供更多专业建议。结合 FDA 已经批准的 2 个植物药案例,详细介绍 植物药 CMC(化学、生产、控制)、临床前研究和过往人用历史方面的基本要求,浅谈 FDA 的申报要求、审评思想和申报策略,以期 为中国中药企业的国际化开发和注册提供参考。     

Ligand-Induced Conformational Rearrangements Promote Interaction between the Escherichia coli Enterobactin Biosynthetic Proteins EntE and EntB

Siderophores are small-molecule iron chelators that many bacteria synthesize and secrete in order to survive in iron-depleted environments. Biosynthesis of enterobactin, the Escherichia coli catecholate siderophore, requires adenylation of 2,3-dihydroxybenzoic acid (2,3-DHB) by the cytoplasmic enzyme EntE. The DHB-AMP product is then transferred to the active site of holo-EntB subsequent to formation of an EntE-EntB complex. Here we investigate the binding of 2,3-DHB to EntE and how DHB binding affects EntE-EntB interaction. We overexpressed and purified recombinant forms of EntE and EntB with N-terminal hexahistidine tags (H6-EntE and H6-EntB). Isothermal titration calorimetry showed that 2,3-DHB binds to H6-EntE with a 1:1 stoichiometry and a K_d of 7.4 μM. Fluorescence spectra revealed enhanced 2,3-DHB emission at 440 nm (λ_ex = 280 nm) when bound to H6-EntE due to fluorescence resonance energy transfer (FRET) between EntE intrinsic fluorophore donors and bound 2,3-DHB acceptor. A FRET signal was not observed when H6-EntE was mixed with either 2,5-dihydroxybenzoic acid or 3,5-dihydroxybenzoic acid. The H6-EntE-2,3-DHB FRET signal was quenched by H6-EntB in a concentration-dependent manner. From these data, we were able to determine the EC₅₀ of EntE-EntB interaction to be approximately 1.5 μM. We also found by fluorescence and CD measurements that H6-EntB can bind 2,3-DHB, resulting in conformational changes in the protein. Additional alterations in H6-EntB near-UV and far-UV CD spectra were observed upon mixture with H6-EntE and 2,3-DHB, suggesting that further conformational rearrangements occur in EntB upon interaction with substrate-loaded EntE. We also found that H6-EntB as a bait protein pulled down a higher concentration of chromosomally expressed EntE in the presence of exogenous 2,3-DHB. Taken together, our results show that binding of 2,3-DHB to EntE and EntB primes these proteins for efficient complexation, thus facilitating direct channeling of the siderophore precursor 2,3-DHB-AMP.     

Conformational Transition Pathway in the Inhibitor Binding Process of Human Monoacylglycerol Lipase

Human monoacylglycerol lipase (MGL) catalyzes the hydrolysis of 2-arachidonoylglycerol to arachidonic and glycerol, which plays a pivotal role in the normal biological processes of brain. Co-crystal structure of the MGL in complex with its inhibitor, compound 1, shows that the helix α4 undergoes large-scale conformational changes in response to the compound 1 binding compared to the apo MGL. However, the detailed conformational transition pathway of the helix α4 in the inhibitor binding process of MGL has remained unclear. Here, conventional molecular dynamics (MD) and nudged elastic band (NEB) simulations were performed to explore the conformational transition pathway of the helix α4. Conventional MD simulations unveiled that the compound 1 induced the closed conformation of the active site of MGL, reduced the conformational flexibility of the helix α4, and elicited the large-scale conformational rearrangement of the helix α4, leading to the complete folding of the helix α4. Moreover, NEB simulations revealed that the conformational transition pathway of helix α4 underwent an almost 180° counter-clockwise rotation of the helix α4. Our computational results advance the structural and mechanistic understanding of the inhibitory mechanism.     

Selectively Modulating Conformational States of USP7 Catalytic Domain for Activation

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Many Local Motions Cooperate to Produce the Adenylate Kinase Conformational Transition

Conformational transitions are functionally important in many proteins. In the enzyme adenylate kinase (AK), two small domains (LID and NMP) close over the larger CORE domain; the reverse (opening) motion limits the rate of catalytic turnover. Here, using double-well Gō simulations of Escherichia coli AK, we elaborate on previous investigations of the AK transition mechanism by characterizing the contributions of rigid-body (Cartesian), backbone dihedral, and contact motions to transition-state (TS) properties. In addition, we compare an apo simulation to a pseudo-ligand-bound simulation to reveal insights into allostery. In Cartesian space, LID closure precedes NMP closure in the bound simulation, consistent with prior coarse-grained models of the AK transition. However, NMP-first closure is preferred in the apo simulation. In backbone dihedral space, we find that, as expected, backbone fluctuations are reduced in the O/C transition in parts of all three domains. Among these “quenching” residues, most in the CORE, especially residues 11–13, are rigidified in the TS of the bound simulation, while residues 42–44 in the NMP are flexible in the TS. In contact space, in both apo and bound simulations, one nucleus of closed-state contacts includes parts of the NMP and CORE; CORE–LID contacts are absent in the TS of the apo simulation but formed in the TS of the bound simulation. From these results, we predict mutations that will perturb the opening and/or closing transition rates by changing the entropy of dihedrals and/or the enthalpy of contacts. Furthermore, regarding allostery, the fully closed structure is populated in the apo simulation, but our contact results imply that ligand binding shifts the preferred O/C transition pathway, thus precluding a simple conformational selection mechanism. Finally, the analytical approach and the insights derived from this work may inform the rational design of flexibility and allostery in proteins.     

Ion-Controlled Conformational Dynamics in the Outward-Open Transition from an Occluded State of LeuT

Neurotransmitter:sodium symporter (NSS) proteins are secondary Na⁺-driven active transporters that terminate neurotransmission by substrate uptake. Despite the availability of high-resolution crystal structures of a bacterial homolog of NSSs—Leucine Transporter (LeuT)—and extensive computational and experimental structure-function studies, unanswered questions remain regarding the transport mechanisms. We used microsecond atomistic molecular-dynamics (MD) simulations and free-energy computations to reveal ion-controlled conformational dynamics of LeuT in relation to binding affinity and selectivity of the more extracellularly positioned Na⁺ binding site (Na1 site). In the course of MD simulations starting from the occluded state with bound Na⁺, but in the absence of substrate, we find a spontaneous transition of the extracellular vestibule of LeuT into an outward-open conformation. The outward opening is enhanced by the absence of Na1 and modulated by the protonation state of the Na1-associated Glu-290. Consistently, the Na⁺ affinity for the Na1 site is inversely correlated with the extent of outward-open character and is lower than in the occluded state with bound substrate; however, the Na1 site retains its selectivity for Na⁺ over K⁺ in such conformational transitions. To the best of our knowledge, our findings shed new light on the Na⁺-driven transport cycle and on the symmetry in structural rearrangements for outward- and inward-open transitions.     

Conformational Rearrangements in the Pro-apoptotic Protein,Bax, as It Inserts into Mitochondria: A CELLULAR DEATH SWITCH*

The B-cell lymphoma 2 (Bcl-2) family of proteins regulates the activation of apoptosis through the mitochondria pathway. Pro- and anti-apoptotic members of this family keep each other in check until the correct time to commit to apoptosis. The point of no return for this commitment is the permeabilization of the outer mitochondrial membrane. Translocation of the pro-apoptotic member, Bax, from the cytosol to the mitochondria is the molecular signature of this event. We employed a novel method to reliably detect Förster resonance energy transfer (FRET) between pairs of fluorophores to identify intra-molecular conformational changes and inter-molecular contacts in Bax as this translocation occurs in live cells. In the cytosol, our FRET measurement indicated that the C-terminal helix is exposed instead of tucked away in the core of the protein. In addition fluorescence correlation spectroscopy (FCS) showed that cytosolic Bax diffuses much slower than expected, suggesting possible complex formation or transient membrane interaction. Cross-linking the C-terminal helix (α9) to helix α4 reduced the potential of those interactions to occur. After translocation, our FRET measurements showed that Bax molecules form homo-oligomers in the mitochondria through two distinct interfaces involving the BH3 domain (helix α2) and the C-terminal helix. These findings have implications for possible contacts with other Bcl-2 proteins necessary for the regulation of apoptosis.     

Synaptotagmin’s Role in Neurotransmitter Release Likely Involves Ca-induced Conformational Transition

Neuronal exocytosis is mediated by a Ca²⁺-triggered membrane fusion event that joins synaptic vesicles and presynaptic membrane. In this event, synaptotagmin I plays a key role as a Ca²⁺ sensor protein that binds to and bends the presynaptic membrane with its C2B domain, and thereby initiates membrane fusion. We report free energy calculations according to which C2B-induced membrane bending is preceded by a Ca²⁺- and membrane-dependent conformational transition. In this transition C2B attaches to the membrane, moves its C-terminal helix from the orientation seen in the available (but membrane-free) crystal/NMR structures as pointing away from the membrane (helix-up), to an orientation pointing toward the membrane (helix-down). In the C2B helix-down state, lipid tails in the proximal membrane bilayer leaflet interact with the moved helix and become disordered, whereas tails in the distal leaflet, to keep in contact with the proximal leaflet, become stretched and ordered. The difference in lipid tail packing between the two leaflets results in an imbalance of pressure across the membrane, and thereby causes membrane bending. The lipid-disordering monitored in the simulations is well suited to facilitate Ca²⁺-triggered membrane fusion.