scholarly journals Conformational dynamics of androgen receptors bound to agonists and antagonists

2021 ◽  
Vol 11 (1) ◽  
Author(s):  
Hyo Jin Gim ◽  
Jiyong Park ◽  
Michael E. Jung ◽  
K. N. Houk
Keyword(s):  
Conformational Changes ◽  
Structural Changes ◽  
Structural Integrity ◽  
Structural Information ◽  
Close Contact ◽  
Conformational Dynamics ◽  
Principal Component ◽  
Binding Pocket ◽  
Structural Basis ◽  
Accelerated Molecular Dynamics

AbstractThe androgen receptor (AR) is critical in the progression of prostate cancer (PCa). Small molecule antagonists that bind to the ligand binding domain (LBD) of the AR have been successful in treating PCa. However, the structural basis by which the AR antagonists manifest their therapeutic efficacy remains unclear, due to the lack of detailed structural information of the AR bound to the antagonists. We have performed accelerated molecular dynamics (aMD) simulations of LBDs bound to a set of ligands including a natural substrate (dihydrotestosterone), an agonist (RU59063) and three antagonists (bicalutamide, enzalutamide and apalutamide) as well as in the absence of ligand (apo). We show that the binding of AR antagonists at the substrate binding pocket alter the dynamic fluctuations of H12, thereby disrupting the structural integrity of the agonistic conformation of AR. Two antagonists, enzalutamide and apalutamide, induce considerable structural changes to the agonist conformation of LBD, when bound close to H12 of AR LBD. When the antagonists bind to the pocket with different orientations having close contact with H11, no significant conformational changes were observed, suggesting the AR remains in the functionally activated (agonistic) state. The simulations on a drug resistance mutant F876L bound to enzalutamide demonstrated that the mutation stabilizes the agonistic conformation of AR LBD, which compromises the efficacy of the antagonists. Principal component analysis (PCA) of the structural fluctuations shows that the binding of enzalutamide and apalutamide induce conformational fluctuations in the AR, which are markedly different from those caused by the agonist as well as another antagonist, bicalutamide. These fluctuations could only be observed with the use of aMD.

scholarly journals Structural basis of mechano-chemical coupling by the mitotic kinesin KIF14

2020 ◽  
Author(s):  
Matthieu P.M.H. Benoit ◽  
Ana B. Asenjo ◽  
Mohammadjavad Paydar ◽  
Sabin Dhakal ◽  
Benjamin H. Kwok ◽  
...  
Keyword(s):  
Conformational Changes ◽  
Atp Hydrolysis ◽  
Structural Information ◽  
Nucleotide Binding ◽  
Binding Pocket ◽  
Structural Basis ◽  
Directed Movement ◽  
Microtubule Binding ◽  
Domain 3 ◽  
Linker Domain

AbstractKIF14 is a mitotic kinesin protein important for cytokinesis. Its overexpression is associated with a variety of cancers and mutations in KIF14 result in cerebral and renal development defects. Like other kinesins, KIF14 contains a highly conserved catalytic motor domain where the energy from ATP hydrolysis is converted to directed movement along microtubules. Although much is known regarding the molecular mechanism of kinesin motility, there is a lack of structural information of kinesin-microtubule interactions at sufficient resolution to unambiguously assess how conformational changes related to ATP hydrolysis, microtubule binding and translocation are coupled. Here we determined the near-atomic resolution cryo-electron microscopy structures of five different KIF14 constructs bound to microtubules in the presence of different nucleotide analogues mimicking distinct steps of the ATPase cycle. Eighteen independent structures together with supporting functional assays provide a comprehensive view of the kinesin conformational changes occurring with microtubule and nucleotide binding. Our data shows that: 1) microtubule binding induces opening of the KIF14 nucleotide binding pocket; 2) AMP-PNP and ADP-AlFx induce closure of the nucleotide binding pocket in microtubule bound KIF14 and this conformational change is allosterically controlled by the neck-linker domain; 3) the neck-linker domain when undocked prevents the nucleotide-binding-pocket to fully close and dampens ATP hydrolysis; 4) fifteen neck-linker residues are required to assume the docked conformation; 5) the nucleotide analogue ADP-AlFx adopts a distinct configuration in an open nucleotide-binding-pocket; 6) the neck-linker position controls the hydrolysis step rather than nucleotide binding in the KIF14 ATPase cycle; 7) the two motor domains of a KIF14 dimer adopt distinct conformations when simultaneously bound to the microtubule. These observations provide the structural basis for a coordinated chemo-mechanical kinesin plus end translocation model.

scholarly journals Structural basis of mechano-chemical coupling by the mitotic kinesin KIF14

2021 ◽  
Vol 12 (1) ◽  
Author(s):  
Matthieu P.M.H. Benoit ◽  
Ana B. Asenjo ◽  
Mohammadjavad Paydar ◽  
Sabin Dhakal ◽  
Benjamin H. Kwok ◽  
...  
Keyword(s):  
Conformational Changes ◽  
Structural Changes ◽  
Atp Hydrolysis ◽  
Nucleotide Binding ◽  
Binding Pocket ◽  
Bound State ◽  
Structural Basis ◽  
Coupling Mechanism ◽  
Developmental Defects ◽  
Microtubule Binding

AbstractKIF14 is a mitotic kinesin whose malfunction is associated with cerebral and renal developmental defects and several cancers. Like other kinesins, KIF14 couples ATP hydrolysis and microtubule binding to the generation of mechanical work, but the coupling mechanism between these processes is still not fully clear. Here we report 20 high-resolution (2.7–3.9 Å) cryo-electron microscopy KIF14-microtubule structures with complementary functional assays. Analysis procedures were implemented to separate coexisting conformations of microtubule-bound monomeric and dimeric KIF14 constructs. The data provide a comprehensive view of the microtubule and nucleotide induced KIF14 conformational changes. It shows that: 1) microtubule binding, the nucleotide species, and the neck-linker domain govern the transition between three major conformations of the motor domain; 2) an undocked neck-linker prevents the nucleotide-binding pocket to fully close and dampens ATP hydrolysis; 3) 13 neck-linker residues are required to assume a stable docked conformation; 4) the neck-linker position controls the hydrolysis rather than the nucleotide binding step; 5) the two motor domains of KIF14 dimers adopt distinct conformations when bound to the microtubule; and 6) the formation of the two-heads-bound-state introduces structural changes in both motor domains of KIF14 dimers. These observations provide the structural basis for a coordinated chemo-mechanical kinesin translocation model.

Crystal structures of Magnaporthe oryzae trehalose-6-phosphate synthase (MoTps1) suggest a model for catalytic process of Tps1

2019 ◽  
Vol 476 (21) ◽  
pp. 3227-3240 ◽  
Author(s):  
Shanshan Wang ◽  
Yanxiang Zhao ◽  
Long Yi ◽  
Minghe Shen ◽  
Chao Wang ◽  
...  
Keyword(s):  
Crystal Structures ◽  
Conformational Changes ◽  
Magnaporthe Oryzae ◽  
Structural Information ◽  
Complex Structure ◽  
Critical Role ◽  
Catalytic Process ◽  
Structural Basis ◽  
Salt Bridges ◽  
Terminal Domain

Trehalose-6-phosphate (T6P) synthase (Tps1) catalyzes the formation of T6P from UDP-glucose (UDPG) (or GDPG, etc.) and glucose-6-phosphate (G6P), and structural basis of this process has not been well studied. MoTps1 (Magnaporthe oryzae Tps1) plays a critical role in carbon and nitrogen metabolism, but its structural information is unknown. Here we present the crystal structures of MoTps1 apo, binary (with UDPG) and ternary (with UDPG/G6P or UDP/T6P) complexes. MoTps1 consists of two modified Rossmann-fold domains and a catalytic center in-between. Unlike Escherichia coli OtsA (EcOtsA, the Tps1 of E. coli), MoTps1 exists as a mixture of monomer, dimer, and oligomer in solution. Inter-chain salt bridges, which are not fully conserved in EcOtsA, play primary roles in MoTps1 oligomerization. Binding of UDPG by MoTps1 C-terminal domain modifies the substrate pocket of MoTps1. In the MoTps1 ternary complex structure, UDP and T6P, the products of UDPG and G6P, are detected, and substantial conformational rearrangements of N-terminal domain, including structural reshuffling (β3–β4 loop to α0 helix) and movement of a ‘shift region' towards the catalytic centre, are observed. These conformational changes render MoTps1 to a ‘closed' state compared with its ‘open' state in apo or UDPG complex structures. By solving the EcOtsA apo structure, we confirmed that similar ligand binding induced conformational changes also exist in EcOtsA, although no structural reshuffling involved. Based on our research and previous studies, we present a model for the catalytic process of Tps1. Our research provides novel information on MoTps1, Tps1 family, and structure-based antifungal drug design.

New insights into the structural basis of integrin activation

Blood ◽  
2003 ◽  
Vol 102 (4) ◽  
pp. 1155-1159 ◽  
Author(s):  
Jian-Ping Xiong ◽  
Thilo Stehle ◽  
Simon L. Goodman ◽  
M. Amin Arnaout
Keyword(s):  
Conformational Changes ◽  
Structural Changes ◽  
Structural Basis ◽  
Integrin Activation ◽  
Cellular Functions ◽  
Electron Microscopic ◽  
The Past ◽  
Intracellular Signals ◽  
Bidirectional Signaling ◽  
New Hypothesis

Abstract Integrins are cell adhesion receptors that communicate biochemical and mechanical signals in a bidirectional manner across the plasma membrane and thus influence most cellular functions. Intracellular signals switch integrins into a ligand-competent state as a result of elicited conformational changes in the integrin ectodomain. Binding of extracellular ligands induces, in turn, structural changes that convey distinct signals to the cell interior. The structural basis of this bidirectional signaling has been the focus of intensive study for the past 3 decades. In this perspective, we develop a new hypothesis for integrin activation based on recent crystallographic, electron microscopic, and biochemical studies.

scholarly journals Protein-assisted RNA fragment docking (RnaX) for modeling RNA–protein interactions using ModelX

2019 ◽  
Vol 116 (49) ◽  
pp. 24568-24573 ◽  
Author(s):  
Javier Delgado Blanco ◽  
Leandro G. Radusky ◽  
Damiano Cianferoni ◽  
Luis Serrano
Keyword(s):  
Conformational Changes ◽  
Protein Design ◽  
Protein Interactions ◽  
Rna Binding ◽  
Structural Information ◽  
Conformational Dynamics ◽  
Computational Cost ◽  
Regulation Of Transcription ◽  
Sequence Specificity ◽  
Protein Interfaces

RNA–protein interactions are crucial for such key biological processes as regulation of transcription, splicing, translation, and gene silencing, among many others. Knowing where an RNA molecule interacts with a target protein and/or engineering an RNA molecule to specifically bind to a protein could allow for rational interference with these cellular processes and the design of novel therapies. Here we present a robust RNA–protein fragment pair-based method, termed RnaX, to predict RNA-binding sites. This methodology, which is integrated into the ModelX tool suite (http://modelx.crg.es), takes advantage of the structural information present in all released RNA–protein complexes. This information is used to create an exhaustive database for docking and a statistical forcefield for fast discrimination of true backbone-compatible interactions. RnaX, together with the protein design forcefield FoldX, enables us to predict RNA–protein interfaces and, when sufficient crystallographic information is available, to reengineer the interface at the sequence-specificity level by mimicking those conformational changes that occur on protein and RNA mutagenesis. These results, obtained at just a fraction of the computational cost of methods that simulate conformational dynamics, open up perspectives for the engineering of RNA–protein interfaces.

scholarly journals Comparative Analyses of theβ-Tubulin Gene and Molecular Modeling Reveal Molecular Insight into the Colchicine Resistance in Kinetoplastids Organisms

2013 ◽  
Vol 2013 ◽  
pp. 1-8 ◽  
Author(s):  
Luis Luis ◽  
María Luisa Serrano ◽  
Mariana Hidalgo ◽  
Alexis Mendoza-León
Keyword(s):  
Conformational Changes ◽  
Mammalian Cells ◽  
Structural Changes ◽  
Differential Susceptibility ◽  
Binding Pocket ◽  
Crystallographic Structure ◽  
Tubulin Gene ◽  
Colchicine Binding Site ◽  
Colchicine Resistance ◽  
Leishmania Spp

Differential susceptibility to microtubule agents has been demonstrated between mammalian cells and kinetoplastid organisms such asLeishmania spp. andTrypanosoma spp. The aims of this study were to identify and characterize the architecture of the putative colchicine binding site ofLeishmania spp. and investigate the molecular basis of colchicine resistance. We cloned and sequenced theβ-tubulin gene ofLeishmania (Viannia) guyanensisand established the theoretical 3D model of the protein, using the crystallographic structure of the bovine protein as template. We identified mutations on theLeishmania  β-tubulin gene sequences on regions related to the putative colchicine-binding pocket, which generate amino acid substitutions and changes in the topology of this region, blocking the access of colchicine. The same mutations were found in theβ-tubulin sequence of kinetoplastid organisms such asTrypanosoma cruzi,T. brucei, andT. evansi. Using molecular modelling approaches, we demonstrated that conformational changes include an elongation and torsion of anα-helix structure and displacement to the inside of the pocket of oneβ-sheet that hinders access of colchicine. We propose that kinetoplastid organisms show resistance to colchicine due to amino acids substitutions that generate structural changes in the putative colchicine-binding domain, which prevent colchicine access.

scholarly journals Conformational flexibility of adenine riboswitch aptamer in apo and bound states using NMR and an X-ray free electron laser

2019 ◽  
Vol 73 (8-9) ◽  
pp. 509-518
Author(s):  
Jienv Ding ◽  
Monalisa Swain ◽  
Ping Yu ◽  
Jason R. Stagno ◽  
Yun-Xing Wang
Keyword(s):  
Conformational Changes ◽  
Free Electron ◽  
Free Electron Laser ◽  
Messenger Rna ◽  
Bound States ◽  
Conformational Dynamics ◽  
Thermal Fluctuation ◽  
Binding Pocket ◽  
X Ray ◽  
Aptamer Domain

Abstract Riboswitches are structured cis-regulators mainly found in the untranslated regions of messenger RNA. The aptamer domain of a riboswitch serves as a sensor for its ligand, the binding of which triggers conformational changes that regulate the behavior of its expression platform. As a model system for understanding riboswitch structures and functions, the add adenine riboswitch has been studied extensively. However, there is a need for further investigation of the conformational dynamics of the aptamer in light of the recent real-time crystallographic study at room temperature (RT) using an X-ray free electron laser (XFEL) and femtosecond X-ray crystallography (SFX). Herein, we investigate the conformational motions of the add adenine riboswitch aptamer domain, in the presence or absence of adenine, using nuclear magnetic resonance relaxation measurements and analysis of RT atomic displacement factors (B-factors). In the absence of ligand, the P1 duplex undergoes a fast exchange where the overall molecule exhibits a motion at kex ~ 319 s−1, based on imino signals. In the presence of ligand, the P1 duplex adopts a highly ordered conformation, with kex~ 83 s−1, similar to the global motion of the molecule, excluding the loops and binding pocket, at 84 s−1. The µs–ms motions in both the apo and bound states are consistent with RT B-factors. Reduced spatial atomic fluctuation, ~ 50%, in P1 upon ligand binding coincides with significantly attenuated temporal dynamic exchanges. The binding pocket is structured in the absence or presence of ligand, as evidenced by relatively low and similar RT B-factors. Therefore, despite the dramatic rearrangement of the binding pocket, those residues exhibit similar spatial thermal fluctuation before and after binding.

scholarly journals Crystal Structures of Two Coronavirus ADP-Ribose-1″-Monophosphatases and Their Complexes with ADP-Ribose: a Systematic Structural Analysis of the Viral ADRP Domain

2008 ◽  
Vol 83 (2) ◽  
pp. 1083-1092 ◽  
Author(s):  
Yuanyuan Xu ◽  
Le Cong ◽  
Cheng Chen ◽  
Lei Wei ◽  
Qi Zhao ◽  
...  
Keyword(s):  
Structural Analysis ◽  
Crystal Structures ◽  
Structural Information ◽  
Large Family ◽  
Binding Pocket ◽  
Structural Basis ◽  
Active Site Residues ◽  
Replication Process ◽  
Functional Studies ◽  
Group I

ABSTRACT The coronaviruses are a large family of plus-strand RNA viruses that cause a wide variety of diseases both in humans and in other organisms. The coronaviruses are composed of three main lineages and have a complex organization of nonstructural proteins (nsp's). In the coronavirus, nsp3 resides a domain with the macroH2A-like fold and ADP-ribose-1"-monophosphatase (ADRP) activity, which is proposed to play a regulatory role in the replication process. However, the significance of this domain for the coronaviruses is still poorly understood due to the lack of structural information from different lineages. We have determined the crystal structures of two viral ADRP domains, from the group I human coronavirus 229E and the group III avian infectious bronchitis virus, as well as their respective complexes with ADP-ribose. The structures were individually solved to elucidate the structural similarities and differences of the ADRP domains among various coronavirus species. The active-site residues responsible for mediating ADRP activity were found to be highly conserved in terms of both sequence alignment and structural superposition, whereas the substrate binding pocket exhibited variations in structure but not in sequence. Together with data from a previous analysis of the ADRP domain from the group II severe acute respiratory syndrome coronavirus and from other related functional studies of ADRP domains, a systematic structural analysis of the coronavirus ADRP domains was realized for the first time to provide a structural basis for the function of this domain in the coronavirus replication process.

scholarly journals RNA Packaging Motor: From Structure to Quantum Mechanical Modelling and Sequential-Stochastic Mechanism

2008 ◽  
Vol 9 (3-4) ◽  
pp. 351-369 ◽  
Author(s):  
Jelena Telenius ◽  
Anders E. Wallin ◽  
Michal Straka ◽  
Hongbo Zhang ◽  
Erika J. Mancini ◽  
...  
Keyword(s):  
Conformational Changes ◽  
Atp Hydrolysis ◽  
Structural Information ◽  
Molecular Motor ◽  
Structural Similarity ◽  
Binding Pocket ◽  
Reaction Coordinate ◽  
Rna Packaging ◽  
Cooperative Action ◽  
Empty Capsid

The bacteriophages of theCystoviridaefamily package their single stranded RNA genomic precursors into empty capsid (procapsids) using a hexameric packaging ATPase motor (P4). This molecular motor shares sequence and structural similarity with RecA-like hexameric helicases. A concerted structural, mutational and kinetic analysis helped to define the mechanical reaction coordinate,i.e.the conformational changes associated with RNA translocation. The results also allowed us to propose a possible scheme of coupling between ATP hydrolysis and translocation which requires the cooperative action of three consecutive subunits. Here, we first test this model by preparing hexamers with defined proportions of wild type and mutant subunits and measuring their activity. Then, we develop a stochastic kinetic model which accounts for the catalytic cooperativity of the P4 hexamer. Finally, we use the available structural information to construct a quantum-chemical model of the chemical reaction coordinate and obtain a detailed description of the electron density changes during ATP hydrolysis. The model explains the results of the mutational analyses and yields new insights into the role of several conserved residues within the ATP binding pocket. These hypotheses will guide future experimental work.

scholarly journals Structural Basis of Vitamin K Antagonism

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 482-482
Author(s):  
Weikai Li ◽  
Shixuan Liu ◽  
Shuang Li
Keyword(s):  
Vitamin K ◽  
Conformational Changes ◽  
Conflicts Of Interest ◽  
Bone Mineralization ◽  
Vitamin K Antagonists ◽  
Membrane Surface ◽  
Warfarin Dose ◽  
Binding Pocket ◽  
Structural Basis ◽  
Vitamin K Cycle

The vitamin K cycle supports blood coagulation, bone mineralization, and vascular calcium homeostasis. A key enzyme in this cycle, vitamin K epoxide reductase (VKOR), is the target of vitamin K antagonists (VKAs). Despite their extensive clinical use, the dose of VKAs (e.g., warfarin) is hard to regulate and overdose can lead to fatal bleeding. Improving the dose regulation requires understanding how VKAs inhibit VKOR, which is a membrane-embedded enzyme difficult to characterize with structural and biochemical studies. Here we achieve a long-standing goal of obtaining crystal structures of human VKOR with warfarin, which represents coumarin-based VKAs; with phenindione, which represents indandione-based VKAs; with superwarfarins, the most commonly used rodenticides; and with vitamin K epoxide in a reaction intermediate state. We have also solved structures of a VKOR-like homolog with warfarin, with vitamin K substrates, and without ligand. These structures show that human VKOR adopts an overall fold with four transmembrane helices (TM) and a large ER-luminal region. VKAs are bound at the active site of HsVKOR, which is formed by the surrounding four-TM bundle and a cap domain on top. The cap domain is stabilized by a linked anchor domain that interacts with the membrane surface. VKOR binds specifically to VKAs through hydrogen bonding to their diketone groups. Mutating VKOR residues recognizing the diketones render strong warfarin resistance. Except the hydrogen bonds, the binding pocket is largely hydrophobic. This pocket is incompatible with warfarin metabolite, explaining the inactivation of warfarin through CYP2C9 metabolism; CYP2C9 and VKOR genotypes can explain 30-50% of the patient variability in warfarin dose. In addition, the high potency of superwarfarins is due to the interaction of their side group with a tunnel where the isoprenyl chain of vitamin K is bound. For VKOR catalysis, the same residues affording the VKA-binding specificity also facilitate substrate reduction Initiation of the catalysis requires a reactive cysteine to form a substrate adduct. Interactions from this stably bound adduct induces a closed conformation, thereby triggering electron transfer to reduce the substrate. Importantly, the open to closed conformational change during catalysis similar to that induced by the binding of VKAs. Taken together, VKAs achieve inhibition through mimicking key interactions and conformational changes required for VKOR catalytic cycle. Understanding of these mechanisms will enable improved strategy to regulate warfarin dose and have a broad impact on thromboembolic diseases and bone disorders. Disclosures No relevant conflicts of interest to declare.

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