Comparison of protein-protein interactions in serine protease-inhibitor and antibody-antigen complexes: implications for the protein docking problem.
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The protein-protein interaction energy of 12 nonhomologous serine protease-inhibitor and 15 antibody-antigen complexes is calculated using a molecular mechanics formalism and dissected in terms of the main-chain vs. side-chain contribution, nonrotameric side-chain contributions, and amino acid residue type involvement in the interface interaction. There are major differences in the interactions of the two types of protein-protein complex. Protease-inhibitor complexes interact predominantly through a main-chain-main-chain mechanism while antibody-antigen complexes interact predominantly through a side-chain-side-chain or a side-chain-main-chain mechanism. However, there is no simple correlation between the main-chain-main-chain interaction energy and the percentage of main-chain surface area buried on binding. The interaction energy is equally effected by the presence of nonrotameric side-chain conformations, which constitute approximately 20% of the interaction energy. The ability to reproduce the interface interaction energy of the crystal structure if original side-chain conformations are removed from the calculation is much greater in the protease-inhibitor complexes than the antibody-antigen complexes. The success of a rotameric model for protein-protein docking appears dependent on the extent of the main-chain-main-chain contribution to binding. Analysis of (1) residue type and (2) residue pair interactions at the interface show that antibody-antigen interactions are very restricted with over 70% of the antibody energy attributable to just six residue types (Tyr > Asp > Asn > Ser > Glu > Trp) in agreement with previous studies on residue propensity. However, it is found here that 50% of the antigen energy is attributable to just four residue types (Arg = Lys > Asn > Asp). On average just 12 residue pair interactions (6%) contribute over 40% of the favorable interaction energy in the antibody-antigen complexes, with charge-charge and charge/polar-tyrosine interactions being prominent. In contrast protease inhibitors use a diverse set of residue types and residue pair interactions. (+info)
Biosynthesis of indole-3-acetic acid in Azospirillum brasilense. Insights from quantum chemistry.
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Quantum chemical methods AM1 and PM3 and chromatographic methods were used to qualitatively characterize pathways of bacterial production of indole-3-acetic acid (IAA). The standard free energy changes (delta G(o)'sum) for the synthesis of tryptophan (Trp) from chorismic acid via anthranilic acid and indole were calculated, as were those for several possible pathways for the synthesis of IAA from Trp, namely via indole-3-acetamide (IAM), indole-3-pyruvic acid (IPyA), and indole-3-acetonitrile (IAN). The delta G(o)'sum for Trp synthesis from chorismic acid was -402 (-434) kJ.mol-1 (values in parentheses were calculated by PM3). The delta G(o)'sum for IAA synthesis from Trp were -565 (-548) kJ.mol-1 for the IAN pathway, -481 (-506) kJ.mol-1 for the IAM pathway, and -289 (-306) kJ.mol-1 for the IPyA pathway. By HPLC analysis, the possibility was assessed that indole, anthranilic acid, and Trp might be utilized as precursors for IAA synthesis by Azospirillum brasilense strain Sp 245. The results indicate that there is a high motive force for Trp synthesis from chorismic acid and for IAA synthesis from Trp, and make it unlikely that anthranilic acid and indole act as the precursors to IAA in a Trp-independent pathway. (+info)
Characterization of thermostable RecA protein and analysis of its interaction with single-stranded DNA.
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Thermostable RecA protein (ttRecA) from Thermus thermophilus HB8 showed strand exchange activity at 65 degrees C but not at 37 degrees C, although nucleoprotein complex was observed at both temperatures. ttRecA showed single-stranded DNA (ssDNA)-dependent ATPase activity, and its activity was maximal at 65 degrees C. The kinetic parameters, K(m) and kcat, for adenosine triphosphate (ATP) hydrolysis with poly(dT) were 1.4 mM and 0.60 s-1 at 65 degrees C, and 0.34 mM and 0.28 s-1 at 37 degrees C, respectively. Substrate cooperativity was observed at both temperatures, and the Hill coefficient was about 2. At 65 degrees C, all tested ssDNAs were able to stimulate the ATPase activity. The order of ATPase stimulation was: poly(dC) > poly(dT) > M13 ssDNA > poly(dA). Double-stranded DNAs (dsDNA), poly(dT).poly(dA) and M13 dsDNA, were unable to activate the enzyme at 65 degrees C. At 37 degrees C, however, not only dsDNAs but also poly(dA) and M13 ssDNA showed poor stimulating ability. At 25 degrees C, poly(dA) and M13 ssDNA gave circular dichroism (CD) peaks at around 192 nm, which reflect a particular structure of DNA. The conformation was changed by an upshift of temperature or binding to Escherichia coli RecA protein (ecRecA), but not to ttRecA. The dissociation constant between ecRecA and poly(dA) was estimated to be 44 microM at 25 degrees C by the change in the CD. These observations suggest that the capability to modify the conformation of ssDNA may be different between ttRecA and ecRecA. The specific structure of ssDNA was altered by heat or binding of ecRecA. After this alteration, ttRecA and ecRecA can express their activities at each physiological temperature. (+info)
The interaction of coenzyme Q with phosphatidylethanolamine membranes.
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Coenzyme Q (CoQ) is a component of the mitochondrial respiratory chain which carries out additional membrane functions, such as acting as an antioxidant. The location of CoQ in the membrane and the interaction with the phospholipid bilayer is still a subject of debate. The interaction of CoQ in the oxidized (ubiquinone-10) and reduced (ubiquinol-10) state with membrane model systems of 1,2-dielaidoyl-sn-glycero-3-phosphoethanolamine (Ela2Gro-P-Etn) has been studied by means of differential scanning calorimetry (DSC), 31P-nuclear magnetic resonance (31P-NMR) and small angle X-ray diffraction (SAXD). Ubiquinone-10 did not visibly affect the lamellar gel to lamellar liquid-crystalline phase transition of Ela2Gro-P-Etn, but it clearly perturbed the multicomponent lamellar liquid-crystalline to lamellar gel phase transition of the phospholipid. The perturbation of both transitions was more effective in the presence of ubiquinol-10. A location of CoQ forming head to head aggregates in the center of the Ela2Gro-P-Etn bilayer with the polar rings protruding toward the phospholipid acyl chains is suggested. The formation of such aggregates are compatible with the strong hexagonal HII phase promotion ability found for CoQ. This ability was evidenced by the shifting of the lamellar to hexagonal HII phase transition to lower temperatures and by the appearance of the characteristic hexagonal HII 31P-NMR resonance and SAXD pattern at temperatures at which the pure Ela2Gro-P-Etn is still organized in extended bilayer structures. The influence of CoQ on the thermotropic properties and phase behavior of Ela2Gro-P-Etn is discussed in relation to the role of CoQ in the membrane. (+info)
Studies on the formation and stability of a complex between Streptomyces proteinaceous metalloprotease inhibitor and thermolysin.
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The effects of certain physicochemical parameters on the formation and stability of a complex between Streptomyces proteinaceous metalloprotease inhibitor (SMPI) and thermolysin were investigated. SMPI had its lowest Ki value at a pH of around 6.5 (similar to the pH dependence of the kcat/K(m) of thermolysin catalysis), reflecting the splitting mechanism of the SMPI inhibition of thermolysin. This Ki increased with an increase in pressure, and in (Ki-1) was almost linear with respect to pressure. The volume of the reaction (delta Vcomp), which is the volume change accompanying enzyme-inhibitor complex formation, was calculated as +8.1 +/- 0.3 mL.mol-1, which has a sign opposite to delta Vcomp for neutral peptide inhibitors and acyl-peptide substrates. The temperature dependence of Ki-1 gave the reaction enthalpy (delta Hcomp) and reaction entropy (delta Scomp) of the complex formation as 34.6 +/- 1.4 kJ.mol-1 and 298 +/- 5 J.mol-1.K-1, respectively. These positive reaction volumes and reaction entropies were related to the electrostatic interactions and ionic strength dependence of Ki which corresponded to the key ionic interaction during complex formation. Complex formation with SMPI stabilized thermolysin against pressure perturbation as observed by the changes in the Trp fluorescence of thermolysin with increasing pressure. Thermal stability, however, was affected very little by complex formation with SMPI. Phosphoramidon, Cbz-Phe-Gly-NH2 and Cbz-Phe also positively affected the pressure-tolerance of thermolysin, in the following order: Cbz-Gly-Phe-NH2 < Cbz-Phe << phosphoramidon. The third compound exhibited stabilizing effects comparable with those of SMPI, which suggests that the interaction between SMPI and thermolysin was localized to the reactive site. (+info)
The effect of template RNA structure on elongation by HIV-1 reverse transcriptase.
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Reverse transcription of the RNA genome of retroviruses has to proceed through some highly structured regions of the template. The RNA genome of the human immunodeficiency virus type 1 (HIV-1) contains two hairpin structures within the repeat (R) region at the 5' end of the viral RNA (Fig. 1Fig. 1Template RNA structure of the HIV-1 R region and the position of reverse transcription pause sites. The HIV-1 R region (nucleotides +1/97) encodes two stable RNA structures, the TAR and polyA hairpins [5]. The latter hairpin contains the AAUAAA hexamer motif (marked by a box) that is involved in polyadenylation. The lower panel shows the predicted structures of the wild-type and two mutant forms of the polyA hairpin that were used in this study. Nucleotide substitutions are boxed, deletions are indicated by black triangle. The thermodynamic stability (free energy or DeltaG, in kcal/mol) was calculated according to the Zucker algorithm [71]. The TAR hairpin has a DeltaG of -24.8 kcal/mol. Minus-strand DNA synthesis on these templates was initiated by a DNA primer annealed to the downstream PBS. The position of reverse transcription pause sites observed in this study are summarized. All numbers refer to nucleotide positions on the wild-type HIV-1 transcript. Filled arrows represent stops observed on the wild-type template, and open arrows mark the pause sites that are specific for the structured A-mutant template. The sizes of the arrows correspond to the relative frequency of pausing. Little pausing was observed on the B-mutant template with the destabilized polyA hairpin.). These structures, the TAR and polyA hairpins, fulfil important functions in the viral life cycle. We analyzed the in vitro elongation properties of the HIV-1 reverse transcriptase (RT) enzyme on the wild-type RNA template and mutants thereof with either a stabilized or a destabilized polyA hairpin. Stable RNA structure was found to interfere with efficient elongation of the RT enzyme, as judged by the appearance of pause cDNA products. A direct relation was measured between the stability of template RNA structure and the extent of RT pausing. However, the position of structure-induced pause sites is rather diverse, with significant stops at a position approximately 6 nt ahead of the basepaired stem of the TAR and polyA hairpins. This suggests that the RT enzyme is stalled when its most forward domain contacts the RNA duplex. Addition of the viral nucleocapsid protein (NC) to the in vitro assay was found to overcome such structure-induced RT stops. These results indicate that the RT polymerase has problems penetrating regions of the template with stable RNA structure. This effect was more pronounced at high Mg2+ concentrations, which is known to stabilize RNA secondary structure. Such a structure-induced defect was not apparent in reverse transcription assays performed in virus-infected cells, which is either caused by the NC protein or other components of the virion particle. Thus, retroviruses can use relatively stable RNA structures to control different steps in the viral life cycle without interfering with the process of reverse transcription. (+info)
Folding stability of the kinetoplastid membrane protein-11 (KMP-11) from Leishmania infantum.
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Kinetoplastid membrane protein-11 (KMP-11) is a major component of the cell surface of kinetoplastids, and acts as a potent B- and T-cell immunogen during Leishmania infection. Here we report that the Leishmania infantum KMP-11 secondary structure adopts mainly an alpha-helical conformation at pH 7.5 and that its urea- and thermally-induced unfolding constitute a fully reversible two-step process. This allows estimation of a half-denaturation temperature of approximately 65 degrees C, a delta GDH2O at 20 degrees C of approximately 14.63 kJ.mol-1, and an increment of the reaction heat of approximately 183.92 kJ.mol-1 and an entropy of approximately 543.4 J.mol-1.deg-1, respectively, for the native-denatured equilibrium of the KMP-11 in solution. We also report that the KPM-11 protein is induced to adopt a molten globule state at a pH range between pH 4 and pH 6. As a whole, the stability and the specific features of the denaturing effect induced by changes in pH are similar in KMP-11 to various other lipoproteins. (+info)
DNA-protein cooperative binding through variable-range elastic coupling.
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Cooperativity plays an important role in the action of proteins bound to DNA. A simple mechanism for cooperativity, in the form of a tension-mediated interaction between proteins bound to DNA at two different locations, is proposed. These proteins are not in direct physical contact. DNA segments intercalating bound proteins are modeled as a worm-like chain, which is free to deform in two dimensions. The tension-controlled protein-protein interaction is the consequence of two effects produced by the protein binding. The first is the introduction of a bend in the host DNA and the second is the modification of the bending modulus of the DNA in the immediate vicinity of the bound protein. The interaction between two bound proteins may be either attractive or repulsive, depending on their relative orientation on the DNA. Applied tension controls both the strength and the range of protein-protein interactions in this model. Properties of the cooperative interaction are discussed, along with experimental implications. (+info)