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270 results on '"Salt Bridges"'

252. Mechanisms governing the fragmentation of glycerophospholipids containing choline and ethanolamine polar head groups.

Author

Colsch B, Fenaille F, Warnet A, Junot C, and Tabet JC

Subjects
Ions chemistry, Lipids chemistry, Molecular Structure, Spectrometry, Mass, Electrospray Ionization, Choline analysis, Ethanolamine analysis, Glycerophospholipids chemistry
Abstract

Glycerophospholipids are the major amphiphilic molecules found in the plasma membrane bilayer of all vertebrate cells. Involved in many biological processes, their huge structural diversity and large concentration scale make their thorough characterization extremely difficult in complex biological matrices. Mass spectrometry techniques are now recognized as being among the most powerful methods for the sensitive and comprehensive characterization of lipids. Depending on the experimental conditions used during electrospray ionization mass spectrometry experiments, glycerophospholipids can be detected as different molecular species (e.g. protonated, sodiated species) when analyzed either in positive or negative ionization modes or by direct introduction or hyphenated mass spectrometry-based methods. The observed ionized forms are characteristic of the corresponding phospholipid structures, and their formation is highly influenced by the polar head group. Although the fragmentation behavior of each phospholipid class has already been widely studied under low collision energy, there are no established rules based on charge-induced dissociation mechanisms for explaining the generation of fragment ions. In the present paper, we emphasize the crucial roles played by ion-dipole complexes and salt bridges within charge-induced dissociation processes. Under these conditions, we were able to readily explain almost all the fragment ions obtained under low-energy collision-induced dissociation for particular glycerophospholipids and lysoglycerophospholipids species including glycerophosphatidylcholines and glycerophosphatidylethanolamines. Thus, in addition to providing a basis for a better comprehension of phospholipid fragmentation processes, our work also highlighted some potentially new relevant diagnostic ions to signal the presence of particular lipid species.

Published
2017
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253. Gas-Phase Protein Salt Bridge Stabilities from Collisional Activation and Electron Transfer Dissociation.

Author

Zhang Z and Vachet RW

Abstract

The gas phase structures of several proteins have been studied by electron transfer dissociation (ETD) with and without prior collisional heating after electrospraying these proteins from native-like solutions into a quadrupole ion trap mass spectrometer. Without prior collisional heating, we find that ETD fragmentation is mostly limited to regions of the protein that are not spanned by the salt bridges known to form in solution. When protein ions are collisionally heated before ETD, new product ions are observed, and in almost all cases, these new ions arise from protein regions that are spanned by the salt bridges. Together these results confirm the existence of salt bridges in protein ions and demonstrate that a sufficient amount energy is required to disrupt these salt bridges in the gas phase. More interestingly, we also show that different salt bridges require different collisional activation voltages to be disrupted, suggesting that they have variable stabilities in the gas phase. These stabilities appear to be influenced by the gas-phase basicities of the involved residues and the presence of nearby charged residues. We also find that higher collisional activation voltages are needed to enable the formation of new product from sites spanned by multiple salt bridges.

Published
2017
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254. Salt-bridge networks within globular and disordered proteins: characterizing trends for designable interactions.

Author

Basu S and Mukharjee D

Abstract

There has been considerable debate about the contribution of salt bridges to the stabilization of protein folds, in spite of their participation in crucial protein functions. Salt bridges appear to contribute to the activity-stability trade-off within proteins by bringing high-entropy charged amino acids into close contacts during the course of their functions. The current study analyzes the modes of association of salt bridges (in terms of networks) within globular proteins and at protein-protein interfaces. While the most common and trivial type of salt bridge is the isolated salt bridge, bifurcated salt bridge appears to be a distinct salt-bridge motif having a special topology and geometry. Bifurcated salt bridges are found ubiquitously in proteins and interprotein complexes. Interesting and attractive examples presenting different modes of interaction are highlighted. Bifurcated salt bridges appear to function as molecular clips that are used to stitch together large surface contours at interacting protein interfaces. The present work also emphasizes the key role of salt-bridge-mediated interactions in the partial folding of proteins containing long stretches of disordered regions. Salt-bridge-mediated interactions seem to be pivotal to the promotion of "disorder-to-order" transitions in small disordered protein fragments and their stabilization upon binding. The results obtained in this work should help to guide efforts to elucidate the modus operandi of these partially disordered proteins, and to conceptualize how these proteins manage to maintain the required amount of disorder even in their bound forms. This work could also potentially facilitate explorations of geometrically specific designable salt bridges through the characterization of composite salt-bridge networks. Graphical abstract ᅟ.

Published
2017
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255. Entropy Drives the Formation of Salt Bridges in the Protein GB3.

Author

Zhang N, Wang Y, An L, Song X, Huang Q, Liu Z, and Yao L

Subjects
Hydrogen-Ion Concentration, Magnetic Resonance Spectroscopy, Molecular Dynamics Simulation, Temperature, Entropy, Proteins chemistry, Salts chemistry
Abstract

Salt bridges are very common in proteins. But what drives the formation of protein salt bridges is not clear. In this work, we determined the strength of four salt bridges in the protein GB3 by measuring the ΔpK a values of the basic residues that constitute the salt bridges with a highly accurate NMR titration method at different temperatures. The results show that the ΔpK a values increase with temperature, thus indicating that the salt bridges are stronger at higher temperatures. Fitting of ΔpK a values to the van't Hoff equation yields positive ΔH and ΔS values, thus indicating that entropy drives salt-bridge formation. Molecular dynamics simulations show that the protein and solvent make opposite contributions to ΔH and ΔS. Specifically, the enthalpic gain contributed from the protein is more than offset by the enthalpic loss contributed from the solvent, whereas the entropic gain originates from the desolvation effect., (© 2017 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2017
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256. Harnessing D-amino acids for peptide motif designs. Synthesis and solution conformation of Boc-D-Glu-Ala-Gly-Lys-NHMe and Boc-L-Glu-Ala-Gly-Lys-NHMe

Author

Vivek Bobde, Susheel Durani, and Yellamraju U. Sasidhar

Subjects
Protein Folding, D-Amino Acid, Magnetic Resonance Spectroscopy, Secondary Structure, Stereochemistry, Protein Conformation, Fragments, Molecular Sequence Data, Peptide, Biochemistry, Sensitivity and Specificity, chemistry.chemical_compound, Protein structure, Beta-Turns, Drug Stability, Peptide synthesis, Denovo Design, Salt Bridges, Helix Design, Amino Acid Sequence, Amino Acids, Protein secondary structure, chemistry.chemical_classification, Tetrapeptide, Electrostatically Stabilized Peptides, Alpha-Helices, Temperature, Proteins, Water, Stereoisomerism, Nuclear magnetic resonance spectroscopy, Residues, Stabilization, Solutions, chemistry, Templates, Helix, 3(10)-Helical Conformation, Peptides, Alpha helix
Abstract

In examining the use of D-amino acids in designing specific peptide folding motifs, the tetrapeptide Boc-D-Glu-Ala-Gly-Lys-NHMe 1 and its analog 2 featuring L-Glu were synthesized for a comparison of their solution conformations by NMR spectroscopy. The temperature coefficients of amide proton resonances, NOE data, side-chain CH2 anisotropies and salt titration results suggest a weak type II reverse-turn conformation for peptide 2, and a tandem type II' turn-3(10)-helix conformation of appreciable conformational stability for peptide I in apolar solvents. The latter is of potential interest as the N-terminal helix cap that could support the design of longer 3(10) helices. Possible origins of appreciable difference in the conformational stabilities of the diastereomers are discussed. (C) Munksgaard 1994.

Published
1994

257. Conversion of an instantaneous activating K + channel into a slow activating inward rectifier.

Author

Baumeister D, Hertel B, Schroeder I, Gazzarrini S, Kast SM, Van Etten JL, Moroni A, and Thiel G

Subjects
Green Fluorescent Proteins metabolism, HEK293 Cells, Humans, Kinetics, Models, Biological, Mutant Proteins metabolism, Recombinant Fusion Proteins metabolism, Temperature, Ion Channel Gating, Potassium Channels metabolism, Potassium Channels, Inwardly Rectifying metabolism
Abstract

The miniature channel, Kcv, is a structural equivalent of the pore of all K + channels. Here, we follow up on a previous observation that a largely voltage-insensitive channel can be converted into a slow activating inward rectifier after extending the outer transmembrane domain by one Ala. This gain of rectification can be rationalized by dynamic salt bridges at the cytosolic entrance to the channel; opening is favored by voltage-sensitive formation of salt bridges and counteracted by their disruption. Such latent voltage sensitivity in the pore could be relevant for the understanding of voltage gating in complex Kv channels., (© 2016 Federation of European Biochemical Societies.)

Published
2017
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258. A comparison of X-ray and calculated structures of the enzyme MTH1.

Author

Ryan H, Carter M, Stenmark P, Stewart JJ, and Braun-Sand SB

Subjects
Binding Sites, Catalytic Domain, Crystallography, X-Ray, DNA Repair Enzymes metabolism, Guanosine Monophosphate chemistry, Guanosine Monophosphate metabolism, Humans, Hydrogen Bonding, Hydrolysis, Models, Molecular, Molecular Structure, Phosphoric Monoester Hydrolases metabolism, Protein Binding, Protein Domains, Substrate Specificity, Thermodynamics, Computational Biology methods, DNA Repair Enzymes chemistry, Guanosine Monophosphate analogs & derivatives, Phosphoric Monoester Hydrolases chemistry
Abstract

Modern computational chemistry methods provide a powerful tool for use in refining the geometry of proteins determined by X-ray crystallography. Specifically, computational methods can be used to correctly place hydrogen atoms unresolved by this experimental method and improve bond geometry accuracy. Using the semiempirical method PM7, the structure of the nucleotide-sanitizing enzyme MTH1, complete with hydrolyzed substrate 8-oxo-dGMP, was optimized and the resulting geometry compared with the original X-ray structure of MTH1. After determining hydrogen atom placement and the identification of ionized sites, the charge distribution in the binding site was explored. Where comparison was possible, all the theoretical predictions were in good agreement with experimental observations. However, when these were combined with additional predictions for which experimental observations were not available, the result was a new and alternative description of the substrate-binding site interaction. An estimate was made of the strengths and weaknesses of the PM7 method for modeling proteins on varying scales, ranging from overall structure to individual interatomic distances. An attempt to correct a known fault in PM7, the under-estimation of steric repulsion, is also described. This work sheds light on the specificity of the enzyme MTH1 toward the substrate 8-oxo-dGTP; information that would facilitate drug development involving MTH1. Graphical Abstract Overlay of the backbone traces of the two MTH1 protein chains (green and orange respectively) in PDB 3ZR0 and the equivalent PM7 structures (magenta and cyan respectively) each optimized separately.

Published
2016
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259. Salt Bridge Rearrangement (SaBRe) Explains the Dissociation Behavior of Noncovalent Complexes.

Author

Loo RR and Loo JA

Subjects
Gases, Ions, Proteins chemistry, Spectrometry, Mass, Electrospray Ionization
Abstract

Native electrospray ionization-mass spectrometry, with gas-phase activation and solution compositions that partially release subcomplexes, can elucidate topologies of macromolecular assemblies. That so much complexity can be preserved in gas-phase assemblies is remarkable, although a long-standing conundrum has been the differences between their gas- and solution-phase decompositions. Collision-induced dissociation of multimeric noncovalent complexes typically distributes products asymmetrically (i.e., by ejecting a single subunit bearing a large percentage of the excess charge). That unexpected behavior has been rationalized as one subunit "unfolding" to depart with more charge. We present an alternative explanation based on heterolytic ion-pair scission and rearrangement, a mechanism that inherently partitions charge asymmetrically. Excessive barriers to dissociation are circumvented in this manner, when local charge rearrangements access a lower-barrier surface. An implication of this ion pair consideration is that stability differences between high- and low-charge state ions usually attributed to Coulomb repulsion may, alternatively, be conveyed by attractive forces from ion pairs (salt bridges) stabilizing low-charge state ions. Should the number of ion pairs be roughly inversely related to charge, symmetric dissociations would be favored from highly charged complexes, as observed. Correlations between a gas-phase protein's size and charge reflect the quantity of restraining ion pairs. Collisionally-facilitated salt bridge rearrangement (SaBRe) may explain unusual size "contractions" seen for some activated, low charge state complexes. That some low-charged multimers preferentially cleave covalent bonds or shed small ions to disrupting noncovalent associations is also explained by greater ion pairing in low charge state complexes. Graphical Abstract ᅟ.

Published
2016
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260. Secondary Binding Interactions in a Synthetic Receptor for Trimethyllysine.

Author

Pinkin NK, Liu I, Abron JD, and Waters ML

Subjects
Binding Sites, Humans, Protein Binding, Receptors, Artificial chemistry, Thermodynamics, Arginine chemistry, Lysine analogs & derivatives, Lysine chemistry, Receptors, Artificial chemical synthesis
Abstract

We have systematically studied how secondary interactions with neighboring lysine (Lys) and arginine (Arg) residues influence the binding and selectivity of the synthetic receptor A2 N for trimethyllysine (Kme3 ). Multiple secondary binding sites on A2 N are formed by carboxylates rigidly positioned over aromatic rings, a motif that has been shown to stabilize salt bridges. We varied the spacing between KmeX (X=0, 3) and an ancillary Lys or Arg and measured binding by isothermal titration calorimetry (ITC). These studies revealed that both neighboring residues improve the binding of A2 N to KmeX by approximately 1 kcal mol(-1) , with little influence of the spacing. Nonetheless, the improvement in affinity caused by Arg is enthalpically driven, while for Lys it is entropically driven, suggesting different mechanisms by which the residues interact with the secondary binding site., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2015
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261. Physicochemical Properties of Ion Pairs of Biological Macromolecules.

Author

Iwahara J, Esadze A, and Zandarashvili L

Subjects
Entropy, Hydrogen Bonding, Nucleic Acids chemistry, Proteins chemistry, Static Electricity, Thermodynamics, Nucleic Acids metabolism, Proteins metabolism
Abstract

Ion pairs (also known as salt bridges) of electrostatically interacting cationic and anionic moieties are important for proteins and nucleic acids to perform their function. Although numerous three-dimensional structures show ion pairs at functionally important sites of biological macromolecules and their complexes, the physicochemical properties of the ion pairs are not well understood. Crystal structures typically show a single state for each ion pair. However, recent studies have revealed the dynamic nature of the ion pairs of the biological macromolecules. Biomolecular ion pairs undergo dynamic transitions between distinct states in which the charged moieties are either in direct contact or separated by water. This dynamic behavior is reasonable in light of the fundamental concepts that were established for small ions over the last century. In this review, we introduce the physicochemical concepts relevant to the ion pairs and provide an overview of the recent advancement in biophysical research on the ion pairs of biological macromolecules.

Published
2015
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262. Identification and analysis of the salt tolerant property of AHL lactonase (AiiATSAWB ) of Bacillus species.

Author

Easwaran N, Karthikeyan S, Sridharan B, and Gothandam KM

Subjects
Carboxylic Ester Hydrolases chemistry, Carboxylic Ester Hydrolases genetics, Cluster Analysis, Cystic Fibrosis complications, DNA, Bacterial chemistry, DNA, Bacterial genetics, Humans, Models, Molecular, Molecular Sequence Data, Phylogeny, Protein Conformation, Pseudomonas Infections therapy, Respiratory Tract Infections therapy, Sequence Analysis, DNA, Sequence Homology, Bacillus enzymology, Carboxylic Ester Hydrolases metabolism, Enzyme Inhibitors metabolism, Salts metabolism
Abstract

Bacterial biofilms communicate by a process called Quorum Sensing. Gram negative bacterial pathogens specifically talk through the production, detection, and response to the signal or autoinducer called Acyl Homoserine Lactones. Bacterial lactonases are important AHL hydrolysing or quorum quenching enzymes. The present study deals with ten endospore forming gram positive isolates of the saltern soil. Preliminary screening for Quorum Quenching activity with the QS Inhibition indicator strain Chromobacterium violaceum ATCC 12472, showed positive activity in four isolates namely TS2, TS16, TSAWB, and TS53B. AHL lactonase (AiiA) specific primers amplified Acyl Homoserine Lactone lactonase gene in the TSAWB genome alone. Phylogenetic relationship of the identified AiiATSAWB confirmed its evolutionary relationship with bacterial AiiA like AHL lactonase of the metallo-beta-lactamase super family. Our in vitro AHL hydrolysis assay under wide percentage (0-5) of salt solutions with TSAWB isolate and also its intracellular soluble protein fraction showed halotolerant AHL hydrolysis ability of the AiiATSAWB enzyme. In silico determination of putative tertiary structure, the ESBRI derived conserved salt bridges, aminoacid residue characterization with high mole percent of acidic and hydrophobic residues reaffirmed the halotolerant ability of the enzyme. So we propound the future use of purified AiiATSAWB , as hypertonic suspension for inhalation to substitute the action of inactivated host's paraoxonase in treating Pseudomonas aeruginosa infection in cystic fibrosis patients., (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2015
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263. Molecular architecture of protein-RNA recognition sites.

Author

Barik A, C N, Pilla SP, and Bahadur RP

Subjects
Algorithms, Amino Acids chemistry, Amino Acids metabolism, Binding Sites, Hydrogen Bonding, Macromolecular Substances chemistry, Macromolecular Substances metabolism, Models, Molecular, Protein Binding, Protein Structure, Secondary, RNA metabolism, RNA, Transfer chemistry, RNA, Transfer metabolism, RNA-Binding Proteins metabolism, Static Electricity, Nucleic Acid Conformation, Protein Structure, Tertiary, RNA chemistry, RNA-Binding Proteins chemistry
Abstract

The molecular architecture of protein-RNA interfaces are analyzed using a non-redundant dataset of 152 protein-RNA complexes. We find that an average protein-RNA interface is smaller than an average protein-DNA interface but larger than an average protein-protein interface. Among the different classes of protein-RNA complexes, interfaces with tRNA are the largest, while the interfaces with the single-stranded RNA are the smallest. Significantly, RNA contributes more to the interface area than its partner protein. Moreover, unlike protein-protein interfaces where the side chain contributes less to the interface area compared to the main chain, the main chain and side chain contributions flipped in protein-RNA interfaces. We find that the protein surface in contact with the RNA in protein-RNA complexes is better packed than that in contact with the DNA in protein-DNA complexes, but loosely packed than that in contact with the protein in protein-protein complexes. Shape complementarity and electrostatic potential are the two major factors that determine the specificity of the protein-RNA interaction. We find that the H-bond density at the protein-RNA interfaces is similar with that of protein-DNA interfaces but higher than the protein-protein interfaces. Unlike protein-DNA interfaces where the deoxyribose has little role in intermolecular H-bonds, due to the presence of an oxygen atom at the 2' position, the ribose in RNA plays significant role in protein-RNA H-bonds. We find that besides H-bonds, salt bridges and stacking interactions also play significant role in stabilizing protein-nucleic acids interfaces; however, their contribution at the protein-protein interfaces is insignificant.

Published
2015
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264. Do we see what we should see? Describing non-covalent interactions in protein structures including precision.

Author

Gurusaran M, Shankar M, Nagarajan R, Helliwell JR, and Sekar K

Abstract

The power of X-ray crystal structure analysis as a technique is to 'see where the atoms are'. The results are extensively used by a wide variety of research communities. However, this 'seeing where the atoms are' can give a false sense of security unless the precision of the placement of the atoms has been taken into account. Indeed, the presentation of bond distances and angles to a false precision (i.e. to too many decimal places) is commonplace. This article has three themes. Firstly, a basis for a proper representation of protein crystal structure results is detailed and demonstrated with respect to analyses of Protein Data Bank entries. The basis for establishing the precision of placement of each atom in a protein crystal structure is non-trivial. Secondly, a knowledge base harnessing such a descriptor of precision is presented. It is applied here to the case of salt bridges, i.e. ion pairs, in protein structures; this is the most fundamental place to start with such structure-precision representations since salt bridges are one of the tenets of protein structure stability. Ion pairs also play a central role in protein oligomerization, molecular recognition of ligands and substrates, allosteric regulation, domain motion and α-helix capping. A new knowledge base, SBPS (Salt Bridges in Protein Structures), takes these structural precisions into account and is the first of its kind. The third theme of the article is to indicate natural extensions of the need for such a description of precision, such as those involving metalloproteins and the determination of the protonation states of ionizable amino acids. Overall, it is also noted that this work and these examples are also relevant to protein three-dimensional structure molecular graphics software.

Published
2013
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265. Concerning the structure of apoE.

Author

Frieden C and Garai K

Subjects
Alzheimer Disease metabolism, Apolipoprotein E3 genetics, Apolipoprotein E4 metabolism, Humans, Models, Molecular, Mutation, Protein Conformation, Protein Isoforms chemistry, Protein Isoforms metabolism, Protein Structure, Secondary, Protein Structure, Tertiary, Alzheimer Disease etiology, Apolipoprotein E3 chemistry, Apolipoprotein E3 metabolism, Apolipoprotein E4 chemistry, Apolipoprotein E4 genetics
Abstract

Apolipoprotein E (apoE), first described in 1973, is a truly fascinating protein. While studies initially focused on its role in cholesterol and lipid metabolism, one apoE isoform (apoE4) is a major risk factor for development of late onset Alzheimer's disease. Yet the difference between apoE3, the common form, and apoE4 is a single amino acid of the 299 in this 34 kDa protein. Structure determination of the two domain full length apoE3 protein was only accomplished in 2011 and supports the notion that mutations in the N-terminal domain can be propagated through the structure to the C-terminal domain. Understanding the structural differences between apoE3 and apoE4 is critical for finding ways to modulate the deleterious effect of apoE4., (© 2013 The Protein Society.)

Published
2013
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266. 2.0 å structure of indole-3-glycerol phosphate synthase from the hyperthermophile Sulfolobus solfataricus: possible determinants of protein stability

Author

Johan N. Jansonius, Michael Hennig, Reinhard Sterner, B. Darimont, and Kasper Kirschner

Subjects
Models, Molecular, Protein Denaturation, Chemical Phenomena, Structural similarity, archaea, Recombinant Fusion Proteins, helix stabilization, salt bridges, ved/biology.organism_classification_rank.species, Molecular Sequence Data, Indole-3-Glycerol-Phosphate Synthase, medicine.disease_cause, Arginine, Crystallography, X-Ray, Phosphates, Sulfolobus, Hydrophobic effect, Bacterial Proteins, Species Specificity, Structural Biology, medicine, Escherichia coli, Phosphofructokinase 2, Amino Acid Sequence, Molecular Biology, Binding Sites, ATP synthase, biology, Base Sequence, Sequence Homology, Amino Acid, ved/biology, Chemistry, Physical, Sulfolobus solfataricus, (β/α)8 barrel, Aldehyde Oxidoreductases, Hyperthermophile, Crystallography, biology.protein, Sequence Alignment
Abstract

Background: Recent efforts to understand the basis of protein stability have focussed attention on comparative studies of proteins from hyperthermophilic and mesophilic organisms. Most work to date has been on either oligomeric enzymes or monomers comprising more than one domain. Such studies are hampered by the need to distinguish between stabilizing interactions acting between subunits or domains from those acting within domains. In order to simplify the search for determinants of protein stability we have chosen to study the monomeric enzyme indole-3-glycerol phosphate synthase from the hyperthermophilic archaeon Sulfolobus solfataricus (sIGPS), which grows optimally at 90°C. Results The 2.0 a crystal structure of sIGPS was determined and compared with the known 2.0 a structure of the IGPS domain of the bifunctional enzyme from the mesophilic bacterium Escherichia coli (eIGPS). sIGPS and eIGPS have only 30% sequence identity, but share high structural similarity. Both are single-domain ( β / α ) 8 barrel proteins, with one (eIGPS) or two (sIGPS) additional helices inserted before the first β strand. The thermostable sIGPS has many more salt bridges than eIGPS. Several salt bridges crosslink adjacent α helices or participate in triple or quadruple salt-bridge clusters. The number of helix capping, dipole stabilizing and hydrophobic interactions is also increased in sIGPS. Conclusion The higher stability of sIGPS compared with eIGPS seems to be the result of several improved interactions. These include a larger number of salt bridges, stabilization of α helices and strengthening of both polypeptide chain termini and solvent-exposed loops.

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267. ESBRI: a web server for evaluating salt bridges in proteins.

Author

Costantini S, Colonna G, and Facchiano AM

Abstract

Unlabelled: Salt bridges can play important roles in protein structure and function and have stabilizing and destabilizing effects in protein folding. ESBRI is a software available as web tool which analyses the salt bridges in a protein structure, starting from the atomic coordinates. In the case of protein complexes, the salt bridges between protein chains can be evaluated, as well as those among specific charged amino acids and the different protein subunits, in order to obtain useful information regard the protein-protein interaction., Availability: The service is available at the URL: http://bioinformatica.isa.cnr.it/ESBRI/

Published
2008
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269. The importance of α-CT and salt bridges in the formation of insulin and its receptor complex by computational simulation

Author

marzieh dehghan shasaltaneh, Lanjanian, H., Riazi, G. H., and Masoudi-Nejad, A.

Subjects
Conformational changes, Salt bridges, Insulin, Original Article, HADDOCK, Insulin receptor
Abstract

Insulin hormone is an important part of the endocrine system. It contains two polypeptide chains and plays a pivotal role in regulating carbohydrate metabolism. Insulin receptors (IR) located on cell surface interacts with insulin to control the intake of glucose. Although several studies have tried to clarify the interaction between insulin and its receptor, the mechanism of this interaction remains elusive because of the receptor's structural complexity and structural changes during the interaction. In this work, we tried to fractionate the interactions. Therefore, sequential docking method utilization of HADDOCK was used to achieve the mentioned goal, so the following processes were done: the first, two pdb files of IR i.e., 3LOH and 3W11 were concatenated using modeller. The second, flexible regions of IR were predicted by HingeProt. Output files resulting from HingeProt were uploaded into HADDOCK. Our results predict new salt bridges in the complex and emphasize on the role of salt bridges to maintain an inverted V structure of IR. Having an inverted V structure leads to activate intracellular signaling pathway. In addition to presence salt bridges to form a convenient structure of IR, the importance of α-chain of carboxyl terminal (α-CT) to interact with insulin was surveyed and also foretokened new insulin/IR contacts, particularly at site 2 (rigid parts 2 and 3). Finally, several conformational changes in residues Asn711-Val715 of α-CT were occurred, we suggest that α-CT is a suitable situation relative to insulin due to these conformational alterations.

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