Basis for the reduced affinity of beta T- and gamma T-thrombin for hirudin

Partial proteolysis of human alpha-thrombin by trypsin results in the formation of beta T-thrombin and gamma T-thrombin which have a reduced affinity for the inhibitor hirudin and the cell-surface cofactor thrombomodulin as well as reduced activity with fibrinogen. The basis of the reduction in affinity of these thrombin derivatives for hirudin has been investigated by examining their kinetics of interaction with a number of hirudin mutants differing in their C-terminal charge properties as well as with a truncated form of hirudin. The results indicate that the reduced affinity of beta T-thrombin for hirudin is most likely due to a decrease in the strength of nonionic interactions between thrombin and the C-terminal region of hirudin. No decrease in the strength of ionic interactions was observed with beta T-thrombin. In contrast, the reduced affinity of gamma T-thrombin was due to a decrease in the strength of both ionic and nonionic interactions. The N-terminal core region of hirudin, which interacts predominantly with the active-site cleft of thrombin, exhibited similar affinities for alpha-, beta T-, and gamma T-thrombin, indicating that thrombin-hirudin interactions within the active site are largely preserved in beta T- and gamma T-thrombin.     

Deciphering the role of the electrostatic interactions in the alpha-tropomyosin head-to-tail complex

Skeletal alpha-tropomyosin (Tm) is a dimeric coiled-coil protein that forms linear assemblies under low ionic strength conditions in vitro through head-to-tail interactions. A previously published NMR structure of the Tm head-to-tail complex revealed that it is formed by the insertion of the N-terminal coiled-coil of one molecule into a cleft formed by the separation of the helices at the C-terminus of a second molecule. To evaluate the contribution of charged residues to complex stability, we employed single and double-mutant Tm fragments in which specific charged residues were changed to alanine in head-to-tail binding assays, and the effects of the mutations were analyzed by thermodynamic double-mutant cycles and protein-protein docking. The results show that residues K5, K7, and D280 are essential to the stability of the complex. Though D2, K6, D275, and H276 are exposed to the solvent and do not participate in intermolecular contacts in the NMR structure, they may contribute to head-to-tail complex stability by modulating the stability of the helices at the Tm termini.     

pH- and salt-dependent self-assembly of human Rad51 protein analyzed as fluorescence resonance energy transfer between labeled proteins

Human HsRad51 protein assembles on a DNA molecule through cooperative binding and forms a long filament for homologous recombination. We have characterized the self-assembly of HsRad51 by measuring the fluorescence resonance energy transfer from the fluorescein-labeled protein to the rhodamine-labeled protein. Self-assembly quickly reached equilibrium and can be described by the head-to-tail polymerization of monomers, like that of its procaryotic homologue, RecA. It depended strongly on pH and was inhibited by high salt concentrations, indicating that ionic interactions between negatively and positively charged aminoacid residues are important. By contrast, neither ATP nor ADP significantly affected the reaction.     

Characterization of the residues involved in the human alpha-thrombin-haemadin complex: an exosite II-binding inhibitor

Haemadin is a 57-amino acid thrombin inhibitor from the land-living leech Haemadipsa sylvestris, whose structure has recently been determined in complex with human alpha-thrombin. Here we communicate the effect of ionic strength on the kinetics of the inhibition of human alpha-thrombin by haemadin, by using thrombin mutants modified in exosite II. Data analysis has allowed both the ionic and nonionic binding contributions to be ascertained, with the nonionic component being virtually the same for all of the thrombins that have been examined, while the ionic binding energy contributions varied from molecule to molecule. In the case of the native human alpha-thrombin-haemadin complex, ionic interactions contribute -17 kJ/mol to the Gibbs free energy of binding, this being the equivalent of up to six salt bridges. These salt bridges make up 20% of the total binding energy at zero ionic strength, and this has been attributed to the C-terminal tail alone. In addition, the contributions of the N-terminal and C-terminal regions of haemadin to its tight binding have been ascertained by using derivatives of both haemadin and thrombin. Limited proteolysis using formic acid produced haemadin cleaved between residues 40 and 41, removing the majority of the C-terminal tail. This truncated haemadin displayed a 20000-fold reduced affinity for thrombin, and was no longer a tight binding inhibitor. A form of thrombin in which the active site serine has been blocked by diisopropyl fluorophosphate binds to haemadin, but with a 72000-fold reduced affinity, indicating that the N-terminus is more important than the C-terminus for strong binding.     

Entropic and enthalpic contributions to annexin V-membrane binding: a comprehensive quantitative model

Annexin V binds to membranes with very high affinity, but the factors responsible remain to be quantitatively elucidated. Analysis by isothermal microcalorimetry and calcium titration under conditions of low membrane occupancy showed that there was a strongly positive entropy change upon binding. For vesicles containing 25% phosphatidylserine at 0.15 m ionic strength, the free energy of binding was -53 kcal/mol protein, whereas the enthalpy of binding was -38 kcal/mol. Addition of 4 m urea decreased the free energy of binding by about 30% without denaturing the protein, suggesting that hydrophobic forces make a significant contribution to binding affinity. This was confirmed by mutagenesis studies that showed that binding affinity was modulated by the hydrophobicity of surface residues that are likely to enter the interfacial region upon protein-membrane binding. The change in free energy was quantitatively consistent with predictions from the Wimley-White scale of interfacial hydrophobicity. In contrast, binding affinity was not increased by making the protein surface more positively charged, nor decreased by making it more negatively charged, ruling out general ionic interactions as major contributors to binding affinity. The affinity of annexin V was the same regardless of the head group present on the anionic phospholipids tested (phosphatidylserine, phosphatidylglycerol, phosphatidylmethanol, and cardiolipin), ruling out specific interactions between the protein and non-phosphate moieties of the head group as a significant contributor to binding affinity. Analysis by fluorescence resonance energy transfer showed that multimers did not form on phosphatidylserine membranes at low occupancy, indicating that annexin-annexin interactions did not contribute to binding affinity. In summary, binding of annexin V to membranes is driven by both enthalpic and entropic forces. Dehydration of hydrophobic regions of the protein surface as they enter the interfacial region makes an important contribution to overall binding affinity, supplementing the role of protein-calcium-phosphate chelates.     

Effect of charged residue substitutions on the thermodynamics of signal peptide-lipid interactions for the Escherichia coli LamB signal sequence.

We have used tryptophan fluorescence spectroscopy to characterize the binding affinities of an Escherichia coli LamB signal peptide family for lipid vesicles. These peptides harbor charged residue substitutions in the hydrophobic core region. Titrations of peptides with vesicles composed of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine and 1-palmitoyl-2-oleoyl-sn-3-phosphoglycerol (65:35 mol%), in conjunction with evaluation of peptide dissociation rates from these vesicles, were used to determine binding parameters quantitatively. We find that under low ionic strength conditions, point mutations introducing negatively charged aspartate residues substantially reduce peptide affinity relative to the wild-type peptide. However, the difference between wild-type and mutant peptide affinities was much lower under approximately physiological ionic strength. In addition, the lipid affinities of model surface-binding and transmembrane peptides were determined. These comparative studies with signal and model peptides permitted semi-quantitative deconvolution of signal peptide binding into electrostatic and hydrophobic components. We find that both interactions contribute significantly to binding, although the theoretically available hydrophobic free energy is largely offset by unfavorable polar-group effects. The implications of these results for understanding the potential roles of the signal sequence in protein translocation are discussed.     

Dual roles of the Cardin-Weintraub motif in multimeric Sonic hedgehog

The fly morphogen Hedgehog (Hh) and its mammalian orthologs, Sonic, Indian, and Desert hedgehog, are secreted signaling molecules that mediate tissue patterning during embryogenesis and function in tissue homeostasis and regeneration in the adult. The function of all Hh family members is regulated at the levels of morphogen multimerization on the surface of producing cells, multimer release, multimer diffusion to target cells, and signal reception. These mechanisms are all known to depend on interactions of positively charged Hh amino acids (the Cardin-Weintraub (CW) motif) with negatively charged heparan sulfate (HS) glycosaminoglycan chains. However, a precise mechanistic understanding of these interactions is still lacking. In this work, we characterized ionic HS interactions of multimeric Sonic hedgehog (called ShhNp) as well as mutant forms lacking one or more CW residues. We found that deletion of all five CW residues as well as site-directed mutagenesis of CW residues Lys(33), Arg(35), and Lys(39) (mouse nomenclature) abolished HS binding. In contrast, CW residues Arg(34) and Lys(38) did not contribute to HS binding. Analysis and validation of Shh crystal lattice contacts provided an explanation for this finding. We demonstrate that CW residues Arg(34) and Lys(38) make contact with an acidic groove on the adjacent molecule in the multimer, suggesting a new function of these residues in ShhNp multimerization rather than HS binding. Therefore, the recombinant monomeric morphogen (called ShhN) differs in CW-dependent HS binding and biological activity from physiologically relevant ShhNp multimers, providing new explanations for functional differences observed between ShhN and ShhNp.     

Electrostatic interactions in the association of proteins: an analysis of the thrombin-hirudin complex.

The role of electrostatic interactions in stabilization of the thrombin-hirudin complex has been investigated by means of two macroscopic approaches: the modified Tanford-Kirkwood model and the finite-difference method for numerical solution of the Poisson-Boltzmann equations. The electrostatic potentials around the thrombin and hirudin molecules were asymmetric and complementary, and it is suggested that these fields influence the initial orientation in the process of the complex formation. The change of the electrostatic binding energy due to mutation of acidic residues in hirudin has been calculated and compared with experimentally determined changes in binding energy. In general, the change in electrostatic binding energy for a particular mutation calculated by the modified Tanford-Kirkwood approach agreed well with the experimentally observed change. The finite-difference approach tended to overestimate changes in binding energy when the mutated residues were involved in short-range electrostatic interactions. Decreases in binding energy caused by mutations of amino acids that do not make any direct ionic interactions (e.g., Glu 61 and Glu 62 of hirudin) can be explained in terms of the interaction of these charges with the positive electrostatic potential of thrombin. Differences between the calculated and observed changes in binding energy are discussed in terms of the crystal structure of the thrombin-hirudin complex.     

Antithrombin III phenylalanines 122 and 121 contribute to its high affinity for heparin and its conformational activation

The dissociation equilibrium constant for heparin binding to antithrombin III (ATIII) is a measure of the cofactor's binding to and activation of the proteinase inhibitor, and its salt dependence indicates that ionic and non-ionic interactions contribute approximately 40 and approximately 60% of the binding free energy, respectively. We now report that phenylalanines 121 and 122 (Phe-121 and Phe-122) together contribute 43% of the total binding free energy and 77% of the energy of non-ionic binding interactions. The large contribution of these hydrophobic residues to the binding energy is mediated not by direct interactions with heparin, but indirectly, through contacts between their phenyl rings and the non-polar stems of positively charged heparin binding residues, whose terminal amino and guanidinium groups are thereby organized to form extensive and specific ionic and non-ionic contacts with the pentasaccharide. Investigation of the kinetics of heparin binding demonstrated that Phe-122 is critical for promoting a normal rate of conformational change and stabilizing AT*H, the high affinity-activated binary complex. Kinetic and structural considerations suggest that Phe-122 and Lys-114 act cooperatively through non-ionic interactions to promote P-helix formation and ATIII binding to the pentasaccharide. In summary, although hydrophobic residues Phe-122 and Phe-121 make minimal contact with the pentasaccharide, they play a critical role in heparin binding and activation of antithrombin by coordinating the P-helix-mediated conformational change and organizing an extensive network of ionic and non-ionic interactions between positively charged heparin binding site residues and the cofactor.     

Mapping the electron transfer interface between cytochrome b5 and cytochrome c

To characterize the cytochrome b(5) (Cyt b(5))-cytochrome c (Cyt c) interactions during electron transfer, variants of Cyt b(5) have been employed to assess the contributions of electrostatic interactions (substitution of surface charged residues Glu44, Glu48, Glu56, and Asp60 and heme propionate), hydrophobic interactions, and the thermodynamic driving forces (substitutions for hydrophobic residues in heme pocket residues Phe35, Pro40, Val45, Phe58, and Val61). The electrostatic interactions play an important role in maintaining the stability and specificity of the Cyt b(5)-Cyt c complex that is formed. There is no essential effect on the intraprotein complex electron transfer even if most of the involved negatively charged residues on the surface of Cyt b(5) have been removed. The results support a dynamic docking paradigm for Cyt b(5)-Cyt c interactions. The orientation that is optimal for binding may not be optimal form for electron transfer. Substitution of hydrophobic residues does not have a significant effect on the binding between Cyt b(5) and Cyt c; rather, it regulates the electron transfer rates via changes in the driving force. Combining the electron transfer studies of the Cyt b(5)-Cyt c system and the Cyt b(5)-Zn-Cyt c system, we obtain the reorganization energy (0.6 eV) at an ionic strength of 150 mM.     

High affinity interaction between a synthetic, highly negatively charged pentasaccharide and alpha- or beta-antithrombin is predominantly due to nonionic interactions

Idraparinux is a synthetic O-sulfated, O-methylated pentasaccharide that binds tightly to antithrombin (AT) and thereby specifically and efficiently induces the inactivation of the procoagulant protease, factor Xa. In this study, the affinity and kinetics of the interaction of this high-affinity pentasaccharide with alpha- and beta-AT were compared with those of a synthetic pentasaccharide comprising the natural AT-binding sequence of heparin. Dissociation equilibrium constants, Kd, for the interactions of Idraparinux with alpha- and beta-AT were approximately 0.4 and 0.1 nM, respectively, corresponding to an over 100-fold enhancement in affinity compared with that of the normal pentasaccharide. This large enhancement was due to a approximately 400-fold tighter conformationally activated complex formed in the second binding step, whereas the encounter complex established in the first step was approximately 4-fold weaker. The high-affinity and normal pentasaccharides both made a total of four ionic interactions with AT, although the high-affinity saccharide only established one ionic interaction in the first binding step and was compensated by three in the second step, whereas the normal pentasaccharide established two ionic interactions in each step. In contrast, the affinities of the nonionic interactions (Kd approximately 450 and 90 nM for the binding to alpha- and beta-AT, respectively) were considerably higher than those for the normal pentasaccharide and the highest of all AT-saccharide interactions reported so far. The nonionic contribution to the total free energy of the high-affinity pentasaccharide binding to AT thus amounted to approximately 70%. These findings show that nonionic interactions can play a predominant role in the binding of highly charged saccharide ligands to proteins and can be successfully exploited in the design of such biologically active ligands.     

Predominant contribution of surface approximation to the mechanism of heparin acceleration of the antithrombin-thrombin reaction. Elucidation from salt concentration effects

Heparin has been shown to accelerate the inactivation of alpha-thrombin by antithrombin III (AT) by promoting the initial encounter of proteinase and inhibitor in a ternary thrombin-AT-heparin complex. The aim of the present work was to evaluate the relative contributions of an AT conformational change induced by heparin and of a thrombin-heparin interaction to the promotion by heparin of the thrombin-AT interaction in this ternary complex. This was achieved by comparing the ionic and nonionic contributions to the binary and ternary complex interactions involved in ternary complex assembly at pH 7.4, 25 degrees C, and 0.1-0.35 M NaCl. Equilibrium binding and kinetic studies of the binary complex interactions as a function of salt concentration indicated a similar large ionic component for thrombin-heparin and AT-heparin interactions, but a predominantly nonionic contribution to the thrombin-AT interaction. Stopped-flow kinetic studies of ternary complex formation under conditions where heparin was always saturated with AT demonstrated that the ternary complex was assembled primarily from free thrombin and AT-heparin binary complex at all salt concentrations. Moreover, the ternary complex interaction of thrombin with AT bound to heparin exhibited a substantial ionic component similar to that of the thrombin-heparin binary complex interaction. Comparison of the ionic and nonionic components of thrombin binary and ternary complex interactions indicated that: 1) additive contributions of ionic thrombin-heparin and nonionic thrombin-AT binary complex interactions completely accounted for the binding energy of the thrombin ternary complex interaction, and 2) the heparin-induced AT conformational change made a relatively insignificant contribution to this binding energy. The results thus suggest that heparin promotes the encounter of thrombin and AT primarily by approximating the proteinase and inhibitor on the polysaccharide surface. Evidence was further obtained for alternative modes of thrombin binding to the AT-heparin complex, either with or without the active site of the enzyme complexed with AT. This finding is consistent with the ternary complex encounter of thrombin and AT being mediated by thrombin binding to nonspecific heparin sites, followed by diffusion along the heparin surface to a unique site adjacent to the bound inhibitor.     

Nicotinic acetylcholine receptor channel electrostatics determined by diffusion-enhanced luminescence energy transfer

The electrostatic potentials within the pore of the nicotinic acetylcholine receptor (nAChR) were determined using lanthanide-based diffusion-enhanced fluorescence energy transfer experiments. Freely diffusing Tb3+ -chelates of varying charge constituted a set of energy transfer donors to the acceptor, crystal violet, a noncompetitive antagonist of the nAChR. Energy transfer from a neutral Tb3+ -chelate to nAChR-bound crystal violet was reduced 95% relative to the energy transfer to free crystal violet. This result indicated that crystal violet was strongly shielded from solvent when bound to the nAChR. Comparison of energy transfer from positively and negatively charged chelates indicate negative electrostatic potentials of -25 mV in the channel, measured in low ionic strength, and -10 mV measured in physiological ionic strength. Debye-Hückel analyses of potentials determined at various ionic strengths were consistent with 1-2 negative charges within 8 A of the crystal violet binding site. To complement the energy transfer experiments, the influence of pH and ionic strength on the binding of [3H]phencyclidine were determined. The ionic strength dependence of binding affinity was consistent with -3.3 charges within 8 A of the binding site, according to Debye-Hückel analysis. The pH dependence of binding had an apparent pKa of 7.2, a value indicative of a potential near -170 mV if the titratable residues are constituted of aspartates and glutamates. It is concluded that long-range potentials are small and likely contribute little to selectivity or conductance whereas close interactions are more likely to contribute to electrostatic stabilization of ions and binding of noncompetitive antagonists within the channel.     

Pharmacology and Surface Electrostatics of the K Channel Outer Pore Vestibule

In spite of a generally well-conserved outer vestibule and pore structure, there is considerable diversity in the pharmacology of K channels. We have investigated the role of specific outer vestibule charged residues in the pharmacology of K channels using tetraethylammonium (TEA) and a trivalent TEA analog, gallamine. Similar to Shaker K channels, gallamine block of Kv3.1 channels was more sensitive to solution ionic strength than was TEA block, a result consistent with a contribution from an electrostatic potential near the blocking site. In contrast, TEA block of another type of K channel (Kv2.1) was insensitive to solution ionic strength and these channels were resistant to block by gallamine. Neutralizing either of two lysine residues in the outer vestibule of these Kv2.1 channels conferred ionic strength sensitivity to TEA block. Kv2.1 channels with both lysines neutralized were sensitive to block by gallamine, and the ionic strength dependence of this block was greater than that for TEA. These results demonstrate that Kv3.1 (like Shaker) channels contain negatively charged residues in the outer vestibule of the pore that influence quaternary ammonium pharmacology. The presence of specific lysine residues in wild-type Kv2.1 channels produces an outer vestibule with little or no net charge, with important consequences for quaternary ammonium block. Neutralizing these key lysines results in a negatively charged vestibule with pharmacological properties approaching those of other types of K channels.     

The association between a negatively charged ligand and the electronegative binding pocket of its receptor.

Many examples exist of charged amino acids that play a role in attracting or holding a charged ligand toward or inside an oppositely charged binding pocket of the protein. For example, the enzymes superoxide dismutase, triose-phosphate isomerase, and acetylcholinesterase can steer ligands toward their oppositely charged binding pockets or gorges. Interestingly, in our Brownian dynamics simulations of a phosphate-binding protein, we discovered that negatively charged phosphate (HPO(2-)(4)) could make its way into the negatively charged binding pocket. In fact, the phosphate-binding protein exhibits counterintuitive kinetics of association. That is, one would expect that the rate of association would increase on increases to the ionic strength since the interaction between the ligand, with a charge of -2, and the electronegative binding pocket would be repulsive and greater screening should reduce this repulsion and increase the rate of association. However, the opposite is seen-i.e., the rate of association decreases on increases in the ionic strength. We used Brownian dynamics techniques to compute the diffusion limited association rate constants between the negatively charged phosphate ligand and several open forms of PBP (wild-type and several mutants based on an x-ray structure of open-form PBP, mutant T141D). With the appropriate choices of reaction criteria and molecular parameters, the ligand was able to diffuse into the binding pocket. A number of residues influence binding of the ligand within the pocket via hydrogen bonds or salt bridges. Arg135 partially neutralizes the charges on the HPO(2-)(4) ligand in the binding pocket, allowing it to enter. It is also found that the positive electrostatic patches above and below the binding entrance of PBP contribute the major attractive forces that direct the ligand toward the surface of the protein near the binding site.     

Differences in short peptide-substrate cleavage by two cell-envelope-located serine proteinases of Lactococcus lactis subsp. cremoris are related to secondary binding specificity

Various chromophoric peptides have been tested as substrates for two genetically related types (PI and PIII) of cell-envelope proteinases of Lactococcus lactis subsp. cremoris. The positively charged peptide methoxy-succinyl-arginyl-prolyl-tyrosyl-p-nitroanilide appeared to be cleaved with the highest catalytic efficiency by both enzymes, although in the case of PIII only at high ionic strength. A cation binding site in the PI-type proteinase that is not present in the related PIII-type appears to be mainly responsible for the difference between these enzymes with respect to the rate of conversion of this chromophoric substrate at relatively low ionic strength. This cation binding site most probably resides in the aspartic acid residue 166,which in PIII is substituted by asparagine. Substitution of the threonine residue 138 by lysine in PIII may also play a role. The binding step in the reactionpathway catalysed by PI at low ionic strength is governed mainly by an ionic interaction involving the cation binding site. In addition, hydrophobic interactions contribute to the binding process. Masking of the cation binding site only increases the Michaelis constant K _m; the catalytic constant k _catis not affected. In the absence of the cation binding site (viz. in PIII) the free energy derived from the hydrophobic interactions only is too small to promote binding of the substrate effectively. High activities are measured only if a high ionic strength is introduced. Removal of electrostatic repulsion between the substrate and positively charged residues of the enzyme, among which is lysine 138, may contribute to this activation. Inhibition by n-butanol suggests the presence of an essential hydrophobic (binding) site which is primarily involved in the orientation of the substrate molecule for the catalytic reaction to be initiated.     

Kinetics of the inhibition of thrombin by hirudin

The dissociation constant for hirudin was determined by varying the concentration of hirudin in the presence of a fixed concentration of thrombin and tripeptidyl p-nitroanilide substrate. The estimate of the dissociation constant determined in this manner displayed a dependence on the concentration of substrate which suggested the existence of two binding sites at which the substrate was able to compete with hirudin. A high-affinity site could be correlated with the binding of the substrate at the active site, and the other site had an affinity for the substrate that was 2 orders of magnitude lower. Extrapolation to zero substrate concentration yielded a value of 20 fM for the dissociation constant of hirudin at an ionic strength of 0.125. The dissociation constant for hirudin was markedly dependent on the ionic strength of the assay; it increased 20-fold when the ionic strength was increased from 0.1 to 0.4. This increase in dissociation constant was accompanied by a decrease in the rate with which hirudin associated with thrombin. This rate could be measured with a conventional recording spectrophotometer at higher ionic strength and was found to be independent of the binding of substrate at the active site.     

Electrostatic interactions modulate the conformation of collagen I

The pH- and electrolyte-dependent charging of collagen I fibrils was analyzed by streaming potential/streaming current experiments using the Microslit Electrokinetic Setup. Differential scanning calorimetry and circular dichroism spectroscopy were applied in similar electrolyte solutions to characterize the influence of electrostatic interactions on the conformational stability of the protein. The acid base behavior of collagen I was found to be strongly influenced by the ionic strength in KCl as well as in CaCl(2) solutions. An increase of the ionic strength with KCl from 10(-4) M to 10(-2) M shifts the isoelectric point (IEP) of the protein from pH 7.5 to 5.3. However, a similar increase of the ionic strength in CaCl(2) solutions shifts the IEP from 7.5 to above pH 9. Enhanced thermal stability with increasing ionic strength was observed by differential scanning calorimetry in both electrolyte systems. In line with this, circular dichroism spectroscopy results show an increase of the helicity with increasing ionic strength. Better screening of charged residues and the formation of salt bridges are assumed to cause the stabilization of collagen I with increasing ionic strength in both electrolyte systems. Preferential adsorption of hydroxide ions onto intrinsically uncharged sites in KCl solutions and calcium binding to negatively charged carboxylic acid moieties in CaCl(2) solutions are concluded to shift the IEP and influence the conformational stability of the protein.     

Electron transfer in hemoproteins. VIII. Influence of ionic strength on the rate of reduction of ferricytochrome c by oxymyoglobin derivatives, chemically modified at histidine residues

The influence of chemical modification of His residues in Mb on the rate of redox reaction in system MbO2--Cyt c has been studied at different ionic strengths and pH medium. The products of alkylation of all available His by bromacetate and iodacetamide, CM-Mb and CA-Mb, respectively, and myoglobin, modified by spin label 2,2', 6,6'-tetramethyl-4-bromoacetoxypiperidine-1-oxyl (SL) at His residue A10--Sl (His-A10)--Mb have been studied. It has been shown, that the character of the ionic strength dependence of reaction SL(His-A10)--MbO2 with Cyt c at pH 6.0 ann 7.0 is basically analogues to that, observed for intact protein. It means that only His-GH1 of two His residues, His-A10 and His-GH1, situated in the region of "active contact" of Mg with Cyt c molecule, participates in the interactions, essential for electron transfer. The interaction of the charge of this His with the negatively charged group of Cyt c is necessary, probably for the proper arrangement of other interactions in the active complex, because the deprotonation of His-GHl in the studied pH interval decreases the rate of the process by more than one order of magnitude. The rate of oxidation of MC-MbO2 and CA-MbO2 by ferricytochrome c, in contrast to intact protein, shows a weak dependence on the ionic strength and does not depend on the pH medium, throughout the range of ionic strengths from 0.005 to 1.0. The cause of the radical change in the ionic strength dependence is, probably, nearly entire disturbance of electrostatic interactions in the active complex due to chemical modification of His residues in the site of "active contact", and first of all, the His-CHl residue. The fact, that during alkylation of all available His in Mb the electron transfer persists in the system, points to that in the process of electron transfer to cytochrome c, uncharged group, most probably "inner" His-B5, participates. Based on the data on spatial structure and the obtained results, the positions of the charged groups in the site of "active contact" of Mb with Cyt c molecule are presented.     

Binding interactions between the core central domain of 16S rRNA and the ribosomal protein S15 determined by molecular dynamics simulations

The goal of the current study is to utilize molecular dynamic (MD) simulations to investigate the dynamic behavior of 16S rRNA in the presence and absence of S15 and to identify the binding interactions between these two molecules. The simulations show that: (i) 16S rRNA remains in a highly folded structure when it is bound to S15; (ii) in the absence of S15, 16S rRNA significantly alters its conformation and transiently forms conformations that are similar to the bound structure that make it available for binding with S15; (iii) the unbound rRNA spends the majority of its time in extended conformations. The formation of the extended conformations is a result of the molecule reaching a lower electrostatic energy and the formation of the highly folded, crystal-like conformation is a result of achieving a lower solvation energy. In addition, our MD simulations show that 16S rRNA and S15 bind across the major groove of helix 22 (H22) via electrostatic interactions. The negatively charged phosphate groups of G658, U740, G741 and G742 bind to the positively charged S15 residues Lys7, Arg34 and Arg37. The current study provides a dynamic view of the binding of 16S rRNA with S15.