Structure and dynamics of the antifungal molecules Syringotoxin-B and Syringopeptin-25A from molecular dynamics simulation.

The phytopathogen Pseudomonas syringae pv. syringae produces toxic cyclic lipodepsipeptides (CLPs): nona-peptides and syringopeptins. All CLPs inhibit the growth of many fungal species, including human pathogens, although different fungi display different degrees of sensitivity. The best studied CLPs are Syringomycin-E (SR-E), Syringotoxin-B (ST-B) and Syringopeptin-25A (SP-25A). Their biological activity is affected by membrane composition and their structural differences. We previously (Matyus et al. in Eur Biophys J 35:459-467, 2006) reported the molecular features and structural preferences of SR-E in water and octane environments. Here we investigate in atomic detail the molecular features of the two other main CLP components, ST-B and SP-25A, in water and octane by 200 ns molecular dynamics simulations (MD), using distance restraints derived from NMR NOE data (Ballio et al. in Eur J Biochem 234:747-758, 1995). We have obtained three-dimensional models of ST-B and SP-25A CLPs in different environments. These models can now be used as a basis to investigate the interactions of ST-B and SP-25A with lipid membranes an important further step towards a better understanding of the antifungal and antibacterial activity of these peptides.

Structural investigation of syringomycin-E using molecular dynamics simulation and NMR.

Syringomycin-E (SR-E) is a cyclic lipodepsinonapeptide produced by certain strains of the bacterium Pseudomonas syringae pv. syringae. It shows inhibitory effects against many fungal species, including human pathogens. Its primary biological target is the plasma membrane, where it forms channels comprised of at least six SR-E molecules. The high-resolution structure of SR-E and the structure of the channels are currently not known. In this paper, we investigate in atomic detail the molecular features of SR-E in water by NMR and in water and octane by molecular dynamics simulation (MD). We built a model of the peptide and examined its structure in water and octane in 200 ns MD simulations both with and without distance restraints derived from NMR NOE data. The resulting trajectories show good agreement with the measured NOEs and circular dichroism data from the literature and provide atomistic models of SR-E that are an important step toward a better understanding of the antifungal and antibacterial activity of this peptide.

High pressure reveals that the stability of interdimeric contacts in the R- and T-state of HbA is influenced by allosteric effectors: Insights from computational simulations.

The molecular details of the mechanism of action of allosteric effectors on hemoglobin oxygen affinity are not clearly understood. The global allostery model proposed by Yonetani et al. suggests that the binding of allosteric effectors can take place both in the R and T states and that they influence oxygen affinity through inducing global tertiary changes in the subunits. Recently published high pressure studies yielded dissociation constants at atmospheric pressure that showed a stabilizing effect of heterotropic allosteric effectors on the dimer interface in the R state, and a more pronounced destabilizing effect in a T state model. In the present work, we report on computational modeling used to interpret the high pressure experimental data. We show structural changes in the hemoglobin interdimeric interfaces, indicative of a global tertiary structural change induced by the binding of allosteric effectors. We also show that the number of water molecules bound at the interface is significantly influenced by binding effectors in the T state in accordance with the experimental data. Our results suggest that the binding of effectors at definite sites leads to tertiary changes that propagate to the interfaces and results in overall structural re-organizations.

Heat perturbation of bovine eye lens alpha-crystallin probed by covalently attached ratiometric fluorescent dye 4'-diethylamino-3-hydroxyflavone.

Bovine eye lens alpha-crystallin was covalently labeled with 6-bromomethyl-4'-diethylamino-3-hydroxyflavone and studied under native-like conditions and at the elevated temperature (60 degrees C) that is known to facilitate alpha-crystallin chaperone-like activity. This novel SH-reactive two-band ratiometric fluorescent probe is characterized by two highly emissive N*- and T*-bands; the latter appears due to excited state intramolecular proton transfer reaction. The positions of these bands and the ratio of their intensities for the alpha-crystallin-dye conjugate are the sensitive indicators of polarity of the dye environment and its participation in intermolecular hydrogen bonding. Although we found that the dye labels both the SH and the NH2 groups in alpha-crystallin, a recently developed procedure allowed us to distinguish between the heat-induced spectral changes of the dye molecules attached to SH and NH2 groups. We observed that at elevated temperature the environment of the SH-attached dye becomes more polar and flexible. The number of H-bond acceptor groups in the vicinity of the dye decreases. Since alpha-crystallin contains a single Cys residue within the C-terminal domain of its (alpha)A subunit (the (alpha)B subunit contains none), we can attribute the observed effects to temperature-induced changes in the C-terminal domain of this protein.

Pressure activation of the chaperone function of small heat shock proteins.

Small heat shock proteins play an important role in the stress response of cells and in several other cellular functions. They possess chaperone-like activity; i.e. they can bind and protect damaged proteins from aggregation and maintain them in a folding-competent state. Two members of this family were investigated in this work: bovine alpha-crystallin and heat shock protein (HSP)16.5 from the thermophilic archaebacteria Methanococcus jannaschii. We reported earlier the enhancement of chaperone potency of alpha-crystallin by high pressure. We now report the completion of the work with results on HSP16.5. The chaperone potency of both proteins can be enhanced significantly by applying high pressure. Evidence by light scattering, Fourier transform infrared (FT-IR) and tryptophan fluorescence experiments show that while the secondary and tertiary structure of these proteins are not influenced by high pressure, their quatemary structure becomes affected: H bonds between subunits are weakened or broken, tryptophan environments become more polar, oligomers dissociate to some extent. We conclude that the oligomeric structure of both proteins is loosened, resulting in stronger dynamics and in more accessible hydrophobic surfaces. These properties lead to increased chaperone potency.

Hg(2+) reacts with different components of the NADPH : protochlorophyllide oxidoreductase macrodomains.

The molecular background of Hg (2+)-induced inhibition of protochlorophyllide (Pchlide) photoreduction was investigated in homogenates of dark-grown wheat leaves. Our earlier work showed that 15 min incubation with 10 (-2) M Hg (2+) completely inhibits the activity of NADPH : Pchlide oxidoreductase ( ). Detailed analysis of spectra recorded at 10 K indicated the appearance of emission bands at 638 and 650 nm, which are characteristic for NADP (+)-Pchlide complexes. Fluorescence emission spectra recorded with different excitation wavelengths, fluorescence lifetime measurements and the analysis of acetone extractions revealed that Hg (2+) can also react directly with Pchlide, resulting in protopheophorbide formation. At 10 (-3) M Hg (2+), the phototransformation was complete but the blue shift of the chlorophyllide emission band speeded up remarkably. This indicates oxidation of the NADPH molecules that have a structural role in keeping together the etioplast inner membrane components. We suggest a complex model for the Hg (2+) effect: depending on concentration it can react with any components of the NADPH : Pchlide oxidoreductase macrodomains.

High-pressure FTIR study of the stability of horseradish peroxidase. Effect of heme substitution, ligand binding, Ca++ removal, and reduction of the disulfide bonds.

The pressure stability of horseradish peroxidase isoenzyme C and the identification of possible stabilizing factors are presented. The effect of heme substitution, removal of Ca(2+), binding of a small substrate molecule (benzohydroxamic acid), and reduction of the disulfide bonds on the pressure stability were investigated by FTIR spectroscopy. HRP was found to be extremely stable under high pressure with an unfolding midpoint of 12.0 +/- 0.1 kbar. While substitution of the heme for metal-free mesoporphyrin did not change the unfolding pressure, Ca(2+) removal and substrate binding reduced the midpoint of the unfolding by 2.0 and 1.2 kbar, respectively. The apoprotein showed a transition as high as 10.4 kbar. However, the amount of folded structure present at the atmospheric pressure was considerably lower than that in all the other forms of HRP. Reduction of the disulfide bonds led to the least pressure stable form, with an unfolding midpoint at 9.5 kbar. This, however, is still well above the average pressure stability of proteins. The high-pressure stability and the analysis of the pressure-induced spectral changes indicate that the protein has a rigid core, which is responsible for the high stability, while there are regions with less stability and more conformational mobility.

Influence of static and dynamic disorder on the visible and infrared absorption spectra of carbonmonoxy horseradish peroxidase.

Spectroscopy of horseradish peroxidase with and without the substrate analog, benzohydroxamic acid, was monitored in a glycerol/water solvent as a function of temperature. It was determined from the water infrared (IR) absorption that the solvent has a glass transition at 170-180 K. In the absence of substrate, both the heme optical Q(0,0) absorption band and the IR absorption band of CO bound to heme broaden markedly upon heating from 10-300 K. The Q(0,0) band broadens smoothly in the whole temperature interval, whereas the IR bandwidth is constant in the glassy matrix and increases from 7 to 16 cm(-1) upon heating above the glass transition. Binding of substrate strongly diminishes temperature broadening of both the bands. The results are consistent with the view that the substrate strongly reduces the amplitude of motions of amino acids forming the heme pocket. The main contribution to the Q(0,0) bandwidth arises from the heme vibrations that are not affected by the phase transition. The CO band thermal broadening stems from the anharmonic coupling with motions of the heme environment, which, in the glassy state, are frozen in. Unusually strong temperature broadening of the CO band is interpreted to be caused by thermal population of a very flexible excited conformational substrate. Analysis of literature data on the thermal broadening of the A(0) band of Mb(CO) (Ansari et al., 1987. Biophys. Chem. 26:337-355) shows that such a state presents itself also in myoglobin.

Aromatic substrate specificity of horseradish peroxidase C studied by a combined fluorescence line narrowing/energy minimization approach: the effect of localized side-chain reorganization.

Horseradish peroxidase C binds a wide variety of small H-donor compounds such as benzohydroxamic acid (BHA) and 2-naphthohydroxamic acid (NHA). In this work, we use the Mg(II)-mesoporphyrin prosthetic group derivative as a spectroscopic probe of the active site and of the interaction with the substrates. We report on high-resolution fluorescence line-narrowed spectra which show that the effects of substrate binding on the electronic transitions are similar for both substrates and present data on the normal vibrational modes that are active in the vibronic spectra. Analysis of the vibrational frequencies shows that the Mg(II) ion is 5-coordinate in all cases, thus ruling out a solvent water as sixth ligand. The frequency shifts observed as a result of substrate binding are also indicative of a more rigid prosthetic group upon substrate binding. We present models for MgMP-HRP and its complexes with both substrates and compare the resulting structures on the basis of a modeling approach combining energy minimization to finite difference Poisson--Boltzmann calculations which partitions the various relative protein contributions to substrate binding. We show that the electrostatic potential of the prosthetic group is modified by the binding event. Analysis of the unbound and bound energy-minimized structures shows that the enzyme modulates substrate binding by subtle charge reorganization in the vicinity of the catalytic site and that this rearrangement is not attributable to significant secondary structure conformational changes but to side-chain reorganization.

Effect of trehalose in low concentration on the binding and transport of porphyrins in liposome-human serum albumin system.

The influence of trehalose on the interaction of liposomes with porphyrins and with human serum albumin (HSA) was studied. Small unilamellar liposomes were prepared from 1,2-dimyristoyl-sn-glycero-3-phosphatidylcholine (DMPC) and from DMPC/1,2-dimyristoyl-sn-glycero-3-phosphatidylglycerol (DMPG) 19:1 w/w% and incorporated with mesoporphyrin IX (MP) or magnesium mesoporphyrin (MgMP). The fluorescence intensity and anisotropy of porphyrins were measured within the temperature range of 15-33 degrees C, in the presence and in the absence of 3x10(-2) M trehalose, to study the location of the porphyrins inside the liposomes and their partition between the liposomes and HSA. Based on the presented data and our earlier results (I. Bárdos-Nagy, R. Galántai, A.D. Kaposi, J. Fidy, Int. J. Pharm. 175 (1998) 255-267) we conclude that trehalose - even at this relatively low concentration - interacts with the head groups of the liposomes and that the presence of DMPG enhances the effect. This effect seems to hinder the binding of HSA to the liposome surface and influences the location of MgMP within the liposomes. In the case of MP, the porphyrin partition between the liposomes and HSA was affected by trehalose, while for MgMP, trehalose changed the structural conditions of porphyrin binding to the liposomes. The amount of trehalose used did not have a general trend to modify the association constants of porphyrin derivatives either to liposomes or to HSA.

Carbonmonoxy horseradish peroxidase as a function of pH and substrate: influence of local electric fields on the optical and infrared spectra.

Infrared and optical spectra of carbonmonoxy horseradish peroxidase were monitored as a function of pH and substrate binding. The analyses of experimental results together with semiempirical calculations show that the CO-porphyrin complex is sensitive to environmental changes. The electronic Q(0,0) band of the porphyrin and the CO stretching mode respond to external perturbations with different symmetry dependencies. In this way, the complex is nonisotropic, and the combined spectral analyses constitute a valuable tool for the investigation of structure. In the absence of substrate and at pH 6.0, the low-spin heme optical Q(0,0) absorption band is a single peak that narrows as the temperature decreases. Under these conditions, the CO vibrational stretch frequency is at 1903 cm(-1). Addition of the substrates benzohydroxamic acid or naphthohydroxamic acid produces a split of approximately 320 cm(-1) in the Q(0,0) absorption band that is clearly evident at < 100 K and shifts the CO absorption to 1916 cm(-1). Increasing the pH to 9.3 also causes a split in the Q(0,0) optical band and elicits a shift in nu(CO) to a higher frequency (1936 cm(-1)). The splitting of the Q(0,0) band and the shifts in the IR spectra are both consistent with changes in the local electric field produced by the proximity of the electronegative carbonyl of the substrate near the heme or the protonation and/or deprotonation of the distal histidine, although other effects are also considered. The larger effect on the Q(0,0) band with substrate at low pH and the shift of nu(CO) at high pH can be rationalized by the directionality of the field and the orientation dependence of dipolar interactions.

Trehalose effect on low temperature protein dynamics: fluctuation and relaxation phenomena.

We performed spectral diffusion experiments in trehalose-enriched glycerol/buffer-glass on horseradish peroxidase where the heme was replaced by metal-free mesoporphyrin IX, and compared them with the respective behavior in a pure glycerol/buffer-glass (Schlichter et al., J. Chem. Phys. 2000, 112:3045-3050). Trehalose has a significant influence: spectral diffusion broadening speeds up compared to the trehalose-free glass. This speeding up is attributed to a shortening of the correlation time of the frequency fluctuations most probably by preventing water molecules from leaving the protein interior. Superimposed to the frequency fluctuation dynamics is a relaxation dynamics that manifests itself as an aging process in the spectral diffusion broadening. Although the trehalose environment speeds up the fluctuations, it does not have any influence on the relaxation. Both relaxation and fluctuations are governed by power laws in time. The respective exponents do not seem to change with the protein environment. From the spectral dynamics, the mean square displacement in conformation space can be determined. It is governed by anomalous diffusion. The associated frequency correlation time is incredibly long, demonstrating that proteins at low temperatures are truly nonergodic systems.

Energy selection is not correlated in the Qx and Qy bands of a Mg-porphyrin embedded in a protein.

The Qx-Qy splitting observed in the fluorescence excitation spectra of Mg-mesoporphyrin-IX substituted horseradish peroxidase (MgMP-HRP) and of its complex with naphthohydroxamic acid (NHA) was studied by spectral hole burning techniques. The width of a hole directly burnt in the Qy band and that of a satellite hole indirectly produced in Qy as a result of hole burning in Qx was compared. We also studied the dependence of the satellite hole in the Qy band on the burning frequency used in the Qx band. Both the directly and indirectly burnt holes were very broad in the (higher energy) Qy band. The width of the satellite hole in the Qy band was equal to the entire width of the inhomogeneously broadened band, independently from the position of hole burning in Qx. This is indicative of a clear lack of correlation between the electronic transition energies of the Qx and Qy bands. A photoproduct was produced by laser irradiation of the MgMP-HRP/NHA complex and was identified as a species with lowered Q-splitting. Conversion of the photoproduct could be achieved by thermal activation measured in temperature-cycling experiments, with a characteristic temperature of 25 K. We attribute the phototransformation to a conformational change of MgMP.

In situ detection of ALA-stimulated porphyrin metabolic products in Escherichia coli B by fluorescence line narrowing spectroscopy.

In a recent work [Photochem. Photobiol. B: Biol. 50 (1999) 8] the successful photodynamic inactivation of Escherichia coli bacteria by visible light was reported based on delta-aminolevulinic acid (ALA)-induced endogenous porphyrin accumulation. In this work, the identification of these porphyrin derivatives in intact bacteria was performed by low-temperature conventional fluorescence and fluorescence line narrowing (FLN) techniques. Conventional fluorescence emission spectroscopy at cryogenic temperatures revealed the presence of the free-base porphyrins, identified earlier by high-performance liquid chromatography analysis of disintegrated bacterial cells after ALA induction; however, emission maxima characteristic for metal porphyrins were also observed. We demonstrated that the primary reason for this signal is that metal porphyrins are formed from free-base porphyrins by Mg2+ ions present in the culturing medium. Incorporation of Zn ions originating from the glassware could also be supposed. In the FLN experiment, the energy selection effect could be clearly demonstrated for (0,0) emissions of both the free-base and the metal porphyrins. The comparison of the conventional emission spectra and the bands revealed by the FLN experiment show that the dominant monomeric structural population is that of metal porphyrins. The intensity and the shape of the FLN lines indicate an aggregated population of the free-base porphyrins, beside a small monomeric population.

Metal coordination influences substrate binding in horseradish peroxidase.

To clarify the role of metal ion coordination in horseradish peroxidase C (HRPC), the effect of pressure and of an externally applied electric field on spectral holes was compared for both metal-free and Mg-mesoporphyrin-substituted horseradish peroxidase C (MP-HRP and MgMP-HRP), as affected by the binding of 2-naphthohydroxamic acid (NHA). The data are compared to earlier studies performed on the same derivatives. Results obtained for MP-HRP show the presence of a predominant MP tautomer, as well as that of another small population with different pocket field and isothermal compressibility (0.12 vs 0.24 GPa(-1)). Binding NHA induces the formation of two new almost equal populations of MP-HRP tautomer complexes and the protein compressibility in both forms is increased to 0.50 and 0.36 GPa(-1). The protein structure becomes much softer than in the absence of NHA. Binding the same substrate to MgMP-HRP resulted in MgMP adopting a single conformation with no compressibility changes, while without NHA, two forms were possible. Stark effect results show charge rearrangement upon substrate binding in both cases. We propose that it is the presence of the metal that stabilizes the structure during the reorganization of the protein matrix induced by the substrate binding event. With the metal, only one conformation is adopted, without significant structural rearrangement but with charge redistribution. The dissociation constants determined for NHA binding to both derivatives and to native HRPC show that studies using mesoporphyrin and Mg-mesoporphyrin derivatives are relevant to investigating the specificity of the substrate-binding pocket in this enzyme.

Serum albumin-lipid membrane interaction influencing the uptake of porphyrins.

It is frequently observed in pharmaceutical practice that entrapped substances are lost rapidly when liposomes are used as carriers to introduce substances into cells. The reason for the loss is the interaction of serum components with liposomes. To elucidate the mechanism of this phenomenon the partition of mesoporphyrin (MP) was systematically studied in model systems composed of various lipids and human serum albumin (HSA). As surface charge is an important factor in the interaction, neutral (1, 2-dimyristoyl-sn-glycero-3-phosphatidylcoline, DMPC) and negatively charged (1,2-dimyristoyl-sn-glycero-3-phosphatidylcoline/1, 2-dimyristoyl-sn-glycero-3-phosphatidylglycerol, DMPC/DMPG = 19/1 w/w) lipids were compared. The liposome/apomyoglobin system was the negative control. The size distribution of sonicated samples was carefully analyzed by dynamic light scattering. Constants of association of MP to the proteins and to the liposomes were determined: K(p,1) = (2.5 +/- 0.7) x 10(7) M(-1), K(p,2) = (1.0 +/- 0.7) x 10(8) M(-1), K(L,1) = (1.3 +/- 0.3) x 10(5) M(-1), and K(L,2) = (3.2 +/- 0.6) x 10(4) M(-1) for HSA, apomyoglobin, DMPC, and DMPC/DMPG liposomes, respectively. These data were used to evaluate the partition experiments. The transfer of MP from the liposomes to the proteins was followed by fluorescence spectroscopy. In the case of apomyoglobin, the experimental points could be interpreted by ruling out the protein-liposome interaction. In the case of HSA, the efflux of MP from the liposomes was strongly inhibited above a critical HSA concentration range for negatively charged vesicles. This effect was interpreted as the result of HSA coat formation on the liposome surface. This direct interaction is significant for small liposomes. The interpretation is fully supported by differential scanning calorimetry experiments.

Trp42 rotamers report reduced flexibility when the inhibitor acetyl-pepstatin is bound to HIV-1 protease.

The Q7K/L331/L631 HIV-1 protease mutant was expressed in Escherichia coli and the effect of binding a substrate-analog inhibitor, acetyl-pepstatin, was investigated by fluorescence spectroscopy and molecular dynamics. The dimeric enzyme has four intrinsic tryptophans, located at positions 6 and 42 in each monomer. Fluorescence spectra and acrylamide quenching experiments show two differently accessible Trp populations in the apoenzyme with k(q1) = 6.85 x 10(9) M(-1) s(-1) and k(q2) = 1.88 x 10(9) M(-1) s(-1), that merge into one in the complex with k(q) = 1.78 x 10(9) M(-1) s(-1). 500 ps trajectory analysis of Trp X1/X2 rotameric interconversions suggest a model to account for the observed Trp fluorescence. In the simulations, Trp6/Trp6B rotameric interconversions do not occur on this timescale for both HIV forms. In the apoenzyme simulations, however, both Trp42s and Trp42Bs are flipping between X1/X2 states; in the complexed form, no such interconverions occur. A detailed investigation of the local Trp environments sampled during the molecular dynamics simulation suggests that one of the apoenzyme Trp42B rotameric interconversions would allow indole-quencher contact, such as with nearby Tyr59. This could account for the short lifetime component. The model thus interprets the experimental data on the basis of the conformational fluctuations of Trp42s alone. It suggests that the rotameric interconversions of these Trps, located relatively far from the active site and at the very start of the flap region, becomes restrained when the apoenzyme binds the inhibitor. The model is thus consistent with associating components of the fluorescence decay in HIV-1 protease to ground state conformational heterogeneity.

Tryptophan phosphorescence signals characteristic changes in protein dynamics at physiological temperatures.

The Arrhenius plot of the de-excitation rate of tryptophan triplet state deviates from linearity in the physiological temperature range for several proteins with buried tryptophans, similarly to the behaviour of enzyme activity. A model is presented featuring two de-excitation pathways whose effectiveness is regulated by protein dynamics.

Horseradish peroxidase monitored by infrared spectroscopy: effect of temperature, substrate and calcium.

Horseradish peroxidase was examined as a function of Ca and substrate binding using infrared spectroscopy in the temperature range of 10-300 K. The Ca complex could be identified by the carboxylate stretches. The amide peak positions indicate that the protein remains stable from room temperature to 10 K. Shifts in these peaks are consistent with increased hydrogen bonding as temperature decreases, but the protein conformation is maintained at cryogenic temperatures. The substrate, benzohydroxamic acid, produced no detectable change in the infrared spectrum, consistent with X-ray crystallography results. With removal of Ca, the protein maintained its overall helicity.

delta-Aminolaevulinic acid-induced porphyrin synthesis and photodynamic inactivation of Escherichia coli B.

The possibility and conditions for the induction of porphyrin synthesis by exogenous delta-aminolaevulinic acid (ALA) and its applicability for the inactivation of Gram-negative bacteria Escherichia coli B. by photodynamic therapy (PDT) have been studied. The bacteria are supplemented with ALA in the log phase of growth, and are grown in a synthetic medium at 37 degrees C in the dark. The efficiency of porphyrin synthesis is detected by fluorescence spectroscopy performed on the isolated bacterial cells and the medium, respectively, and compared with results of high-performance liquid chromatography (HPLC) analysis. ALA stimulates the synthesis of protoporphyrin in the bacteria by a factor of five to six, and an increased amount of the more hydrophilic derivatives with a significant contribution of mesoporphyrin by a factor of two to three is observed in the culturing medium. The optimal conditions of ALA treatment with respect to PDT are 10-15 min of incubation of a bacterial culture of 2 x 10(7) cells ml-1 with (5-9) x 10(-3) mol l-1 ALA. The ALA-treated cells are irradiated by white light of 80 mW cm-2 under growth conditions and a decrease to 0.6% of the number of colony-forming units (CFUs ml-1) is observed after 90 min of irradiation.