Investigation of the nature of the methionine-pi interaction in beta-hairpin peptide model systems

There are frequent contacts between aromatic rings and sulfur atoms in proteins. However, it is unclear to what degree this putative interaction is stabilizing and what the nature of the interaction is. We have investigated the aryl-sulfur interaction by placing a methionine residue diagonal to an aromatic ring on the same face of a beta-hairpin, which places the methionine side chain in close proximity to the aryl side chain. The methionine (Met)-aryl interaction was compared with an equivalent hydrophobic and cation-pi interaction in the context of the beta-hairpin. The interaction between phenylalanine (Phe), tryptophan (Trp), or cyclohexylalanine (Cha) and Met stabilized the beta-hairpin by -0.3 to -0.5 kcal mole(-1), as determined by double-mutant cycles. The peptides were subjected to thermal denaturations that suggest a hydrophobic driving force for the interactions between Met and Trp or Cha. The observed interaction of Met or norleucine (Nle) with Trp or Cha are quite similar, implying a hydrophobic driving force for the Met-pi interaction. However, the thermodynamic data suggest that there may be some differences between the interaction of Met with Trp and Phe and that there may be a small thermodynamic component to the Met...Phe interaction.     

Interaction between FtsZ and inhibitors of cell division.

The interaction between inhibitors of cell division and FtsZ were assessed by using the yeast two-hybrid system. An interaction was observed between FtsZ and SulA, a component of the SOS response, and the interacting regions were mapped to their conserved domains. This interaction was reduced by mutations in sulA and by most mutations in ftsZ that make cell refractory to sulA. No interaction was detected between FtsZ and MinCD, an inhibitory component of the site selection system. However, interactions were observed among various members of the Min system, and MinE was found to reduce the interaction between MinC and MinD. The implications of these findings for cell division are discussed.     

Binding of viral glycoprotein with trypsin and its relation to virulency. I. Initial step of binding

The interaction between surface proteins of some enveloped viruses and trypsin was studied by computer analysis. Prior to the cleavage of the viral protein by trypsin, hydrophobic interaction between them at the vicinity of their active sites may occur. An exposed hydrophobic portion was found there which theoretically could stimulate the interaction. This interaction would be rather non-specific: according to the analysis, trypsin could bind equally well with weakly virulent virus and virulent viruses. Following this interaction, a specific reaction between their active sites would occur. The specificity was found to be related to the virulency of the virus.     

Effects of retinoid ligands on RIP140: molecular interaction with retinoid receptors and biological activity

Receptor interacting protein 140 (RIP140) interacts with retinoic acid receptor (RAR) and retinoid X receptor (RXR) constitutively, but hormone binding enhances this interaction. The ligand-independent interaction is mediated by the amino and central regions of RIP140 which contain a total of nine copies of the LXXLL motif, whereas the agonist-induced interaction is mediated by its carboxyl terminus which contains a novel motif (1063-1076, LTKTNPILYYMLQK). The ligand-independent interaction could be enhanced slightly by agonists, whereas the ligand-dependent interaction was strictly agonist dependent for both RAR and RXR. In the context of heterodimers, ligand occupancy of RXR played a more dominant role for both molecular interaction and biological activity of RIP140. Competition and mutation studies demonstrated an essential role for (1067)Asn and (1073)Met for a ligand-dependent interaction. A model was proposed to address the constitutive and agonist-dependent interaction of RIP140 with RAR/RXR.     

血清白蛋白与酪胺分子的体外相互作用分析

利用毛细管电泳 (capillary electrophoresis, CE)建立牛血清白蛋白(bovine serum albumin, BSA)-酪胺(tyramine, TA)分子作用机制的分析方法,构建TA-BSA相互作用模型,并研究其相互作用机理. 生理条件下,采用HD法(Hummel-Dreyer, HD),前沿分析法(frontal analysis, FA)和空峰法(vacant peak, VP)研究TA与BSA的结合机制,构建TA-BSA理论模型,获取TA和BSA相互作用参数,分析理论模型的适用度. 通过分子模拟,构建TA与BSA的结合模型,考察TA的BSA结合机制. 结果表明,HD法和VP法均适用于分析TA-BSA体系的相互作用,VP法最优. 模型适用度分析得出双对数方程最适合模拟TA-BSA相互作用,TA与BSA结合强度较弱,且只有单一类型的结合位点. 构建的TA与BSA结合模型表明,TA与BSA的相互作用力主要是氢键和范德华力,兼有疏水作用力. 本文结果可为分析生物胺-蛋白质分子作用机制研究提供有意义的参考.     

Accelerated Microdetermination of ε-(γ-Glutamyl)lysine by an Amino Acid Analyzer

The capturing interaction between an insoluble pyridinium-type polymer and bacterial cells was investigated. The strength of the interaction was evaluated by the removal coefficient reported previously based on the initial rate of decrease of viable cell counts caused by the presence of the polymer. Hydrophobic bacteria and hydrophilic bacteria showed distinct differences in the capturing interaction. With hydrophobic bacteria, electrostatic interaction as well as hydrophobic interaction between the polymer and cells appeared to be important. With hydrophilic bacteria, however, other factors such as solvent (water) mediated forces and hydrodynamic forces were suggested.     

Ab initio calculations on hidden modulators of theta class glutathione transferase activity

The glutathione transferases decrease the pKa of glutathione, allowing its deprotonation and the formation of the more reactive thiolate anion. The thiolate is maintained in the active site through a weak conventional hydrogen bond first sphere interaction donated by a Tyr hydroxyl in the Alpha, Mu, Pi, and Sigma glutathione transferase classes that can be modified by other second sphere or indirect thiolate contacts. However, the Theta and Delta class isoforms use a Ser hydroxyl for stabilizing the GSH thiolate, and as such, have a different chemical system compared with that of the Tyr possessed by other classes. We have used high level ab initio methods to investigate this interaction by using a simple methanol methanethiol system as a model. The hydrogen bond strength of this initial first sphere interaction was calculated to be less than that of the Tyr interaction. A putative second sphere interaction exists in the Theta and Delta class structures between Cys or Ser-14 and Ser-11 in the mammalian Theta subclass 1 and 2, respectively. The effect of this interaction on the first sphere interaction has also been investigated and found to significantly increase the energy of the bond.     

Interaction of antimalarial drug quinacrine with nucleic acids of variable sequence studied by spectroscopic methods

The interaction of antimalarial drug quinacrine (QA) with polynucleotides is studied by UV-visible absorption, fluorescence and surface-enhanced Raman spectroscopy (SERS). The polynucleotides employed for such a study were calf thymus DNA, poly(A).poly(T), poly(A).poly(U), poly(C).poly(G) and poly(dG-dC).poly(dG-dC). Absorption and fluorescence spectra of QA complexes indicate that an interaction with the biomolecule is taking place, although different interaction mechanisms are probable depending on the sequence. The SERS spectra also reflect spectral changes which depend on the polymer sequence and that can be correlated to those observed by fluorescence, with the advantage of the detailed structural information provided by this vibrational technique. QA interacts with polynucleotides through its diprotonated form and by ring stacking. The strength of such interaction is extremely sequence dependent, thus suggesting different interaction mechanisms in each case. The SERS technique allows the simultaneous study of those polynucleotide moieties that are directly involved in the interaction thanks to the short-range character of the SERS spectroscopy. The interaction of QA with the above nucleic acids lead to a different change in the chain stability and flexibility which is further related to the different denaturation tendency of the polymer in the presence of the metal surface.     

Kinetics of biodegradation of binary and ternary mixtures of PAHs

The kinetics of biodegradation of mixtures of polycyclic aromatic hydrocarbons (PAHs) by Sphingomonas paucimobilis strain EPA505 were investigated. The investigation focused on three- and four-ring PAHs, specifically 2-methylphenanthrene, fluoranthene, and pyrene. Uptake rates in aerobic batch suspended cultivations were measured for the individual PAHs and their binary and ternary mixtures. It was observed that kinetics were influenced by the mixture composition and the kinetic properties of the components. A material balance equation containing the Monod model was numerically fitted to uptake data to determine extant kinetic parameters for the individual PAHs. Similarly, equations containing kinetic interaction models derived from enzyme kinetics were fitted to the uptake data obtained from experiments with binary and ternary mixtures. The investigation considered the following interaction types: no-interaction (Monod), pure competitive interaction, noncompetitive or mixed-type interaction, uncompetitive inhibition, and nonspecific interaction based on pure competition (SKIP). Model fit was evaluated based on probabilistic and statistical criteria and inferences were reached about underlying interaction mechanisms based on model fit. Mixture kinetics were most adequately simulated by the pure competitive interaction model with mutual substrate exclusivity. This model is fully predictive, relying only on parameters determined in the sole-PAH experiments. It was shown that for low percent inhibition values and with limited data, pure competitive interaction kinetics may not be evident, resembling no-interaction kinetics. This study is a reasonable starting point for understanding and modeling biodegradation of complex PAH mixtures in engineered and natural systems.     

A single domain of the replication termination protein of Bacillus subtilis is involved in arresting both DnaB helicase and RNA polymerase

The current models that have been proposed to explain the mechanism of replication termination are (i) passive arrest of a replication fork by the terminus (Ter) DNA-terminator protein complex that impedes the replication fork and the replicative helicase in a polar fashion and (ii) an active barrier model in which the Ter-terminator protein complex arrests a fork not only by DNA-protein interaction but also by mechanistically significant terminator protein-helicase interaction. Despite the existence of some evidence supporting in vitro interaction between the replication terminator protein (RTP) and DnaB helicase, there has been continuing debate in the literature questioning the validity of the protein-protein interaction model. The objective of the present work was two-fold: (i) to reexamine the question of RTP-DnaB interaction by additional techniques and different mutant forms of RTP, and (ii) to investigate if a common domain of RTP is involved in the arrest of both helicase and RNA polymerase. The results validate and confirm the RTP-DnaB interaction in vitro and suggest a critical role for this interaction in replication fork arrest. The results also show that the Tyr(33) residue of RTP plays a critical role both in the arrest of helicase and RNA polymerase.     

The effect of spatial heterogeneity on the persistence of predator-prey interactions

The effect of spatially discontinuous environments on predator-prey systems is examined by using a computer simulation model. It is shown that increasing prey dispersal and decreasing predator dispersal do not necessarily have a stabilizing influence on the interaction, as had been concluded by previous workers. The stability of predator-prey interaction depends on the interaction of the dispersal process with normal reproduction and feeding of the predator and prey species.     

RhoA Interacts with the Fusion Glycoprotein of Respiratory Syncytial Virus and Facilitates Virus-Induced Syncytium Formation

The fusion glycoprotein (F) of respiratory syncytial virus (RSV), which mediates membrane fusion and virus entry, was shown to bind RhoA, a small GTPase, in yeast two-hybrid interaction studies. The interaction was confirmed in vivo by mammalian two-hybrid assay and in RSV-infected HEp-2 cells by coimmunoprecipitation. Furthermore, the interaction of F with RhoA was confirmed in vitro by enzyme-linked immunosorbent assay and biomolecular interaction analysis. Yeast two-hybrid interaction studies with various deletion mutants of F and with RhoA indicate that the key binding domains of these proteins are contained within, or overlap, amino acids 146 to 155 and 67 to 110, respectively. The biological significance of this interaction was studied in RSV-infected HEp-2 cells that were stably transfected to overexpress RhoA. There was a positive correlation between RhoA expression and RSV syncytium formation, indicating that RhoA can facilitate RSV-induced syncytium formation.     

Continuous association of Escherichia coli single-stranded DNA binding protein with stable complexes of recA protein and single-stranded DNA

The single-stranded DNA binding protein of Escherichia coli (SSB) stimulates recA protein promoted DNA strand exchange reactions by promoting and stabilizing the interaction between recA protein and single-stranded DNA (ssDNA). Utilizing the intrinsic tryptophan fluorescence of SSB, an ATP-dependent interaction has been detected between SSB and recA-ssDNA complexes. This interaction is continuous for periods exceeding 1 h under conditions that are optimal for DNA strand exchange. Our data suggest that this interaction does not involve significant displacement of recA protein in the complex by SSB when ATP is present. The properties of this interaction are consistent with the properties of SSB-stabilized recA-ssDNA complexes determined by other methods. The data are incompatible with models in which SSB is displaced after functioning transiently in the formation of recA-ssDNA complexes. A continuous association of SSB with recA-ssDNA complexes may therefore be an important feature of the mechanism by which SSB stimulates recA protein promoted reactions.     

Interaction of Antimalarial Drug Quinacrine with Nucleic Acids of Variable Sequence Studied by Spectroscopic Methods

Abstract

The interaction of antimalarial drug quinacrine (QA) with polynucleotides is studied by UV- visible absorption, fluorescence and surface-enhanced Raman spectroscopy(SERS). The polynucleotides employed for such a study were calf thymus DNA, poly(A).poly(T), poly(A).poly(U), poly(C).poly(G) and poly(dG-dC).poly(dG-dC). Absorption and fluorescence spectra of QA complexes indicate that an interaction with the biomolecule is taking place, although different interaction mechanisms are probable depending on the sequence. The SERS spectra also reflect spectral changes which depend on the polymer sequence and that can be correlated to those observed by fluorescence, with the advantage of the detailed structural information provided by this vibrational technique. QA interacts with polynucleotides through its diprotonated form and by ring stacking. The strength of such interaction is extremely sequence dependent, thus suggesting different interaction mechanisms in each case. The SERS technique allows the simultaneous study of those polynucleotide moieties that are directly involved in the interaction thanks to the short-range character of the SERS spectroscopy. The interaction of QA with the above nucleic acids lead to a different change in the chain stability and flexibility which is further related to the different denaturation tendency of the polymer in the presence of the metal surface.     

Structure-based design of potent linear peptide inhibitors of the YAP-TEAD protein-protein interaction derived from the YAP omega-loop sequence

The YAP-TEAD protein-protein interaction is a potential therapeutic target to treat cancers in which the Hippo signaling pathway is deregulated. However, the extremely large surface of interaction between the two proteins presents a formidable challenge for a small molecule interaction disrupter approach. We have accomplished progress towards showing the feasibility of this approach by the identification of a 15-mer peptide able to potently (nanomolar range) disrupt the YAP-TEAD interaction by targeting only one of the two important sites of interaction. This peptide, incorporating non-natural amino acids selected by structure-based design, is derived from the Ω-loop sequence 85–99 of YAP.     

Network evolution: rewiring and signatures of conservation in signaling

The analysis of network evolution has been hampered by limited availability of protein interaction data for different organisms. In this study, we investigate evolutionary mechanisms in Src Homology 3 (SH3) domain and kinase interaction networks using high-resolution specificity profiles. We constructed and examined networks for 23 fungal species ranging from Saccharomyces cerevisiae to Schizosaccharomyces pombe. We quantify rates of different rewiring mechanisms and show that interaction change through binding site evolution is faster than through gene gain or loss. We found that SH3 interactions evolve swiftly, at rates similar to those found in phosphoregulation evolution. Importantly, we show that interaction changes are sufficiently rapid to exhibit saturation phenomena at the observed timescales. Finally, focusing on the SH3 interaction network, we observe extensive clustering of binding sites on target proteins by SH3 domains and a strong correlation between the number of domains that bind a target protein (target in-degree) and interaction conservation. The relationship between in-degree and interaction conservation is driven by two different effects, namely the number of clusters that correspond to interaction interfaces and the number of domains that bind to each cluster leads to sequence specific conservation, which in turn results in interaction conservation. In summary, we uncover several network evolution mechanisms likely to generalize across peptide recognition modules.     

Inhibition of RecA protein by the Escherichia coli RecX protein: modulation by the RecA C terminus and filament functional state

The RecX protein is a potent inhibitor of RecA activities. We identified several factors that affect RecX-RecA interaction. The interaction is enhanced by the RecA C terminus and by significant concentrations of free Mg(2+) ion. The interaction is also enhanced by an N-terminal His(6) tag on the RecX protein. We conclude that RecX protein interacts most effectively with a RecA functional state designated A(o) and that the RecA C terminus has a role in modulating the interaction. We further identified a C-terminal point mutation in RecA protein (E343K) that significantly alters the interaction between RecA and RecX proteins.     

Action of hemoglobin. The energy of interaction

The energy of interaction is developed for three of the models applied to the action of hemoglobin. Evaluation of an energy of interaction requires a model defining the unperturbed or statistical process from which the real system is derived. The shape of a ligand binding curve by itself does not yield an energy of interaction since a steepened ligand binding curve may result from either a negative or positive energy of interaction.     

Spectroscopic study of the interaction of gossypol with bovine serum albumin

The interaction of gossypol with bovine serum albumin (BSA) at pH 7.6 in 0.02 M borax-borate buffer has been followed by circular dichroism (CD) and difference spectroscopy. From the extrinsic CD band at 390 nm, a binding constant of 2.7 X 10(3) M-1 was calculated. At 54 degrees the induced CD spectrum was abolished, suggesting that the interaction is not favoured at that temperature. The effect of various solvents and salts on the interaction has been followed by difference spectroscopy. The modification of epsilon-amino groups of lysine did not affect the interaction. Binding of gossypol to BSA does not cause a change in its secondary structure or sedimentation coefficient.     

Interaction of allylisothiocyanate with bovine serum albumin

The interaction of allylisothiocyanate with bovine serum albumin was monitored by fluorescence titration. The interaction was weak with an apparent association constant of 2 × 10². The interaction was unaffected in the pH range of 5.0 to 8.3 and by NaCl. However, the addition of dioxane upto 4% increased the value of the association constant. N-Methyl bovine serum albumin and bovine serum albumin with sulphydryl groups blocked had the same affinity for allylisothiocyanate suggesting that amino and sulphydryl groups may not be involved in the interaction. Polyacrylamide gel electrophoresis and estimation of available lysine suggested that there were perhaps two types of groups involved in the interaction of allylisothiocyanate with bovine serum albumin. An erratum to this article is available at .