An iterative knowledge‐based scoring function for protein–protein recognition

Huang, Sheng‐You; Zou, Xiaoqin

doi:10.1002/prot.21949

Cited by 273 publications

(330 citation statements)

References 78 publications

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“…Then, the three flexible segments around the D367 binding site were remodeled by sampling possible conformations using the LOOPY modeling program (37). To further construct a model for Ca 2+ -bound RCK1-RCK2 complex, the modeled Ca 2+ -bound RCK1 and the experimental Ca 2+ -bound RCK2 of 3MT5 (10) were docked together by using our proteinprotein docking program MDockPP (38). The docked RCK1-RCK2 complex was further optimized/minimized by using Amber force fields (39).…”

Section: +mentioning

confidence: 99%

Ion sensing in the RCK1 domain of BK channels

Zhang

Huang

Yang

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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BK-type K + channels are activated by voltage and intracellular Ca 2+ , which is important in modulating muscle contraction, neural transmission, and circadian pacemaker output. Previous studies suggest that the cytosolic domain of BK channels contains two different Ca 2+ binding sites, but the molecular composition of one of the sites is not completely known. Here we report, by systematic mutagenesis studies, the identification of E535 as part of this Ca 2+ binding site. This site is specific for binding to Ca 2+ but not Cd 2+. Experimental results and molecular modeling based on the X-ray crystallographic structures of the BK channel cytosolic domain suggest that the binding of Ca 2+ by the side chains of E535 and the previously identified D367 changes the conformation around the binding site and turns the side chain of M513 into a hydrophobic core, providing a basis to understand how Ca 2+ binding at this site opens the activation gate of the channel that is remotely located in the membrane. ] i . Because of this function, BK channels are important modulators of muscle contraction (1), neuronal spike frequency adaptation (2), neurotransmitter release (3), and circadian pacemaker output (4). BK channels are formed by four Slo1 subunits (5, 6). Each Slo1 contains a membrane-spanning domain, which comprises the pore-gate domain (PGD) and the voltage sensing domain (VSD), and a cytosolic domain (CTD) (7,8), which is made of two regulating domains for K + conductance (RCK1 and RCK2) (9, 10). Intracellular Ca 2+ binds to the CTD to activate the channel by enhancing the open probability of the activation gate located in the membrane-spanning PGD.Previous studies have identified two putative Ca 2+ binding sites in the CTD of BK channels, one is the Ca 2+ bowl located in the RCK2 domain (10-13) and the other is located in the RCK1 domain including the residue D367 (14). The existence of two distinctively different high-affinity Ca 2+ binding sites that are responsible for Ca 2+ -dependent activation of BK channels has been demonstrated in various experimental studies (15). These studies demonstrated that Ca 2+ binding to the two sites activates channel independently with only a small cooperativity (14,16,17), and the two sites show differences in various properties including affinities for Ca 2+ (14, 17), voltage dependence (17), and the molecular mechanisms of coupling to the activation gate (18). The distinction between the properties of the two putative Ca 2+ binding sites may lead to different physiological roles of these sites. For instance, a mutation in Slo1 that is associated with epilepsy and dyskinesia in human (19) specifically enhances the coupling of the RCK1 site to the activation gate to increase Ca 2+ sensitivity of channel activation (18). Although previous studies showed that the Ca 2+ binding site in RCK1 is important for physiological functions, its molecular identity is less certain than that of the Ca 2+ bowl. In the Ca 2+ bowl, previous mutagenesis studies (13) and a recently published X-ray cr...

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Section: +mentioning

confidence: 99%

Ion sensing in the RCK1 domain of BK channels

Zhang

Huang

Yang

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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“…An ideal scoring function should recognize favourable native contacts as found in the bound complex and discriminate those from non-native contacts with lower scores. Scoring can be based on a physical force field with optimized weights on the energetic contributions (Dominguez et al, 2003;Bonvin, 2006;Audie, 2009) or can involve knowledge-based statistical potentials derived from known protein protein complex structures (Gottschalk et al, 2004;Zhang et al, 2005;Huang & Zou, 2008). Often a single descriptor (e.g.…”

Section: Flexible Refinement and Rescoring Of Docking Solutionsmentioning

confidence: 99%

“…Based on these statistics it is possible to design knowledge-based scoring functions which in general compare the frequency of contact pairs in known interfaces with the expected frequency if residues or atoms would randomly distributed at interfaces. Effective knowledge-based potentials have been developed that are based on contact preferences of amino acids at known interfaces compared to interfaces of non-native decoy complexes (Huang & Zou, 2008;Ravikant & Elber, 2009;Kowalsman & Eisenstein, 2009). The resulting contact or distance dependent pair-potentials can improve the scoring of near-native complexes.…”

Section: Flexible Refinement and Rescoring Of Docking Solutionsmentioning

confidence: 99%

Flexible Protein-Protein Docking

Schneider¹,

Zacharias²

2011

Selected Works in Bioinformatics

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“…The first approach uses a linear combination of energy terms, while the second approach is statistics-based or "knowledge-based", as it uses properties derived from experimental structures of protein-protein complexes, usually embodied in atom-atom or residue-residue potentials. CONSRANK thus deeply differs from other valuable algorithms in the field [22][23][24][25][26][27][28][29][30][31][32][33][34][35], as it uses neither knowledge-based nor physics-based energy functions. Application of CONSRANK to the ranking of over 110 targets from different sources showed a very good performance, as it was able to consistently enrich the top ranked positions in correct solutions, provided that they represented an appreciable fraction of the total models [21,36].…”

Section: Introductionmentioning

confidence: 99%

Analysis and Ranking of Protein-Protein Docking Models Using Inter-Residue Contacts and Inter-Molecular Contact Maps

2015

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Abstract:In view of the increasing interest both in inhibitors of protein-protein interactions and in protein drugs themselves, analysis of the three-dimensional structure of protein-protein complexes is assuming greater relevance in drug design. In the many cases where an experimental structure is not available, protein-protein docking becomes the method of choice for predicting the arrangement of the complex. However, reliably scoring protein-protein docking poses is still an unsolved problem. As a consequence, the screening of many docking models is usually required in the analysis step, to possibly single out the correct ones. Here, making use of exemplary cases, we review our recently introduced methods for the analysis of protein complex structures and for the scoring of protein docking poses, based on the use of inter-residue contacts and their visualization in inter-molecular contact maps. We also show that the ensemble of tools we developed can be used in the context of rational drug design targeting protein-protein interactions.

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An iterative knowledge‐based scoring function for protein–protein recognition

Cited by 273 publications

References 78 publications

Ion sensing in the RCK1 domain of BK channels

Ion sensing in the RCK1 domain of BK channels

Flexible Protein-Protein Docking

Analysis and Ranking of Protein-Protein Docking Models Using Inter-Residue Contacts and Inter-Molecular Contact Maps

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