Levente Herényi

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.

Syntheses and DNA binding of new cationic porphyrin–tetrapeptide conjugates

Recently cationic porphyrin-peptide conjugates were synthesized to enhance the cellular uptake of porphyrins or deliver the peptide moiety to the close vicinity of nucleic acids. DNA binding of such compounds was not systematically studied yet. We synthesized two new porphyrin-tetrapeptide conjugates which can be considered as a typical monomer unit corresponding to the branches of porphyrin-polymeric branched chain polypeptide conjugates. Tetra-peptides were linked to the tri-cationic meso-tri(4-N-methylpyridyl)-mono-(4-carboxyphenyl)porphyrin and bi-cationic meso-5,10-bis(4-N-methylpyridyl)-15,20-di-(4-carboxyphenyl)porphyrin. DNA binding of porphyrin derivatives, and their peptide conjugates was investigated with comprehensive spectroscopic methods. Titration of porphyrin conjugates with DNA showed changes in Soret bands with bathocromic shifts and hypochromicities. Decomposition of absorption spectra suggested the formation of two populations of bound porphyrins. Evidence provided by the decomposition of absorption spectra, fluorescence decay components, fluorescence energy transfer and induced CD signals reveals that peptide conjugates of di- and tricationic porphyrins bind to DNA by two distinct binding modes which can be identified as intercalation and external binding. Tri-cationic structure and elimination of negative charges in the peptide conjugates are preferable for the binding. Our findings provide essential information for the design of DNA-targeted porphyrin-peptide conjugates.

Comparison of the efficiency and the specificity of DNA-bound and free cationic porphyrin in photodynamic virus inactivation

The risk of transmitting infections by blood transfusion has been substantially reduced. However, alternative methods for inactivation of pathogens in blood and its components are needed. Application of photoactivated cationic porphyrins can offer an approach to remove non-enveloped viruses from aqueous media. Here we tested the virus inactivation capability of meso-Tetrakis(4-N-methylpyridyl)porphyrin (TMPyP) and meso-Tri-(4-N-methylpyridyl)monophenylporphyrin (TMPyMPP) in the dark and upon irradiation. T7 bacteriophage, as a surrogate on non-enveloped viruses was selected as a test system. TMPyP and TMPyMPP reduce the viability of T7 phage already in the dark, which can be explained by their selective binding to nucleic acid. Both compounds proved to be efficient photosensitizers of virus inactivation. The binding of porphyrin to phage DNA was not a prerequisite of phage photosensitization, moreover, photoinactivation was more efficiently induced by free than by DNA bound porphyrin. As optical melting studies and agarose gel electrophoresis of T7 nucleoprotein revealed, photoreactions of TMPyP and TMPyMPP affect the structural integrity of DNA and also of viral proteins, despite their selective DNA binding.

Hierarchic Finite Level Energy Landscape Model TO DESCRIBE THE REFOLDING KINETICS OF PHOSPHOGLYCERATE KINASE

One of the most intriguing predictions of energy landscape models is the existence of non-exponential protein folding kinetics caused by hierarchical structures in the landscapes. Here we provide the strongest evidence so far of such hierarchy and determine the time constants and weights of the kinetic components of the suggested hierarchic energy landscape. To our knowledge, the idea of hierarchical folding energy barriers has never been tested over such a broad timescale. Refolding of yeast phosphoglycerate kinase was initiated from the guanidine-unfolded state by stopped-flow or manual mixing and monitored by tryptophan fluorescence from 1 ms to 15 min. The strategy to build a model that describes folding of yeast phosphoglycerate kinase was to start from the simplest paradigm and modify it stepwise to the necessary minimal extent after repeated comparisons with the experiments. We made no a priori assumptions about the folding landscape. The result was a hierarchic finite level landscape model that quantitatively describes the refolding of yeast phosphoglycerate kinase from 1 ms to 15 min. The early steps of the folding process happen in the upper region of the landscape, where the surface has a hierarchic structure. This leads to stretched kinetics in the early phase of the folding. The lower region of the energy landscape is dominated by a trap that reflects the accumulation of molten globule intermediate state. From this intermediate, the protein can reach the global energy minimum corresponding to the native state through a cross-barrier folding step.

Location of Mesoporphyrin in Liposomes Determined by Site-Selective Fluorescence Spectroscopy

Binding of photosensitizers to target cells is a crucial step during the photodynamic effect. Sensitizer distribution is a good indication of whether the chemical is a good candidate for perturbing cell membrane integrity. Hence, the photophysical properties of porphyrinoid sensitizers in microheterogeneous systems such as liposomes are of outstanding interest. Here we present a site-selective fluorescence study of liposome systems. Monocomponent, small unilamellar vesicles formed of different phosphatidylcholines with incorporated mesoporphyrin were investigated. The size distribution of liposomes was measured by dynamic light scattering after each step of the experiment. On the basis of fluorescence line narrowing spectra of mesoporphyrin, the inhomogeneous distribution function was determined in order to characterize the photosensitizer location. The dual character of the functions revealed two different locations. Decomposition of the inhomogeneous distribution functions into Gaussians and the analysis of the fit results suggest that one of the locations for mesoporphyrin is between the two lipid layers, and the other one is between the hydrocarbon chains of the lipid molecules.

Role of structure-proteins in the porphyrin-DNA interaction.

We studied the complexation of meso-tetrakis(4-N-methylpyridyl)porphyrin (TMPyP) with HeLa nucleosomes and compared it to our earlier results on T7 phage nucleoprotein complex (NP) and isolated DNA. To identify binding modes and relative concentrations of the bound TMPyP forms, the porphyrin absorption spectra were analyzed at various base pair/porphyrin ratios. Spectral decomposition and circular dichroism measurements proved that the two main binding modes of TMPyP, i.e., external binding and intercalation occur also in the nucleosomes. The DNA superstructure maintained by the proteins decreases its accessibility for TMPyP similarly in both nucleoproteins. A difference is observed between the partitioning of the two binding modes: in the case of nucleosome the ratio of intercalation to groove-binding is changed from 60/40 to 40/60 as determined for T7 NP and for isolated DNA-s. Using UV and CD melting studies, we revealed that TMPyP destabilizes the DNA-protein interaction in the nucleosomes but not in the T7 phage. Lastly, photoinduced reaction of bound TMPyP caused alterations in DNA structures and DNA-protein interactions within both nucleoprotein complexes; the nucleosomes were found to be more sensitive to the photoreaction.

Binding of new cationic porphyrin–tetrapeptide conjugates to nucleoprotein complexes

Ongoing research on DNA binding of cationic porphyrin derivatives and their conjugates is a subject of growing interest because of their possible DNA binding and demonstrated biological properties. In this study nucleoprotein binding of tri-cationic meso-tri(4-N-methylpyridyl)-mono-(4-carboxyphenyl)porphyrin (TMPCP) and tetrapeptides conjugated TMPCP (TMPCP-4P) and bi-cationic meso-5,10-bis(4-N-methylpyridyl)-15,20-di-(4-carboxyphenyl)porphyrin (BMPCP-4P2) was investigated with comprehensive spectroscopic methods. The key observation is that tetrapeptide-conjugates of cationic porphyrins with two or three positive charges bind to encapsidated DNA in T7 phage nucleoprotein complex. The binding modes were analyzed by fluorescent energy transfer, fluorescent life time and CD measurements. Intercalative binding is most feasible when tricationic ligands complex with DNA, especially when it is in close connection with protein capsid. It was found that larger ligand BMPCP-4P2 binds externally to encapsidated T7 DNA, and complex externally as well as by intercalation when the DNA accommodate to relaxed B-conformation. In the case of TMPCP and TMPCP-4P the intercalation is the predominant binding form both in nucleoprotein (NP) and preheated complexes. Further, melting experiments revealed that bound porphyrins do not influence the capsid stability or protein-DNA interactions, but efficiently stabilize the double helical structure of DNA without respect to binding form. A good correlation was found between porphyrin/base pair ration and DNA strand separation temperature.

Oligo- and polypeptide conjugates of cationic porphyrins: binding, cellular uptake, and cellular localization

Recently, we have characterized the DNA and nucleoprotein (NP) binding of bis(4-N-methylpyridyl)-15,20-di(4-carboxyphenyl)porphyrin (BMPCP) and meso-tri(4-N-methylpyridyl)-mono(4-carboxyphenyl)porphyrin (TMPCP) and their tetrapeptide conjugates (BMPCP-4P2 and TMPCP-4P, respectively). In this work, we investigated the interaction of TMPCP conjugated to the tetrapeptide branches of branched chain polymeric polypeptide with poly-l-lysine backbone (AK) with DNA or NP using spectroscopic methods. Analysis of absorption spectra revealed the external binding but no intercalation of TMPCP-AK to DNA. There was no evidence for the interaction between TMPCP-AK and encapsidated DNA. Furthermore, we examined the cellular uptake of BMPCP and TMPCP and their tetra- or polypeptide conjugates by flow cytometry and analyzed how charge, size, and structure of the compounds affect their incorporation. In comparison, liposomal association constants of these derivatives were determined. BMPCP-4P2 accumulated the most, and porphyrins with two positive charges (BMPCP and BMPCP-4P2) showed better accumulation than the tri-cationic TMPCP or TMPCP-4P. Cellular uptake of polycationic TMPCP-AK was significantly lower than that of the free or tetrapeptide conjugated derivatives. The subcellular localization of all the five compounds was investigated in co-localization studies by confocal microscopy with special attention to their nuclear localization. Neither free nor conjugated BMPCP or TMPCP was co-localized with nuclear marker. Instead, these derivatives showed co-localization with lysosomal and mitochondrial fluorescent probes. TMPCP-AK conjugate had different localization patterns appearing mainly in mitochondria and cytoplasmic vesicles. Our results may contribute to the further design of DNA-targeting porphyrin-based constructs.

Millisecond time-scale protein dynamics exists prior to the activation of the bulk solvent matrix

Conformational dynamics of proteins is of fundamental importance in their physiological functions. The exact mechanisms and determinants of protein motions, including the regulatory interplay between protein and solvent motions, are not yet fully understood. In the present work, the thermal activation of phosphorescence quenching was measured in oxygen-saturated aqueous protein solutions to explore protein dynamics in the millisecond range. The sample was brought to cryogenic temperatures in a fast cooling process to avoid the bulk crystallization of ice. The phosphorescence quenching effect was followed by the phosphorescence lifetime of either Zn-protoporphyrin substituting the heme in the β-subunits of human hemoglobin (Zn-HbA) or tryptophan residues of Zn-HbA and human myoglobin (Mb), measured in thermal equilibrium at temperatures varied from 8 to 273 K. The quenching effect was attributed primarily to the activation of collisions with O(2) molecules made possible by the activated millisecond time-scale dynamics of the matrix around the chromophores. We find that, in the studied temperature range, the activation of protein global dynamics facilitating oxygen diffusion takes place at clearly separated lower temperatures and independently from bulk solvent dynamics and that the energy and entropy differences between the studied frozen and thermally activated states are specific for the protein.

Aging dynamics in globular proteins: summary and analysis of experimental results and simulation by a modified trap model

Recent results of spectral diffusion experiments by spectral hole-burning techniques carried out at cryogenic temperatures on various monomeric heme proteins unequivocally show interesting new features of conformational dynamics of globular proteins that were not emphasized in the literature until now. These new aspects of the protein dynamics are anomalous diffusion and the aging effect. Here, using the similarities between proteins and glassy systems, we present a model which can interpret the line broadening and—through this effect—the aging phenomenon as well. Leaving untouched the widely accepted energy landscape (EL) concept for the general description of protein dynamics, we concentrate on the bottom of the funnel-like EL, because this part corresponds to the native state(s) at low temperature. We suggest that the overall shape of the EL at the lowest energy range is rather smooth, but on a finer scale it consists of traps. The dynamics is defined by sequential jumps among these traps and the process is described by a Master equation, where the hopping rate only depends on the parameters of the starting state. This model was adapted to interpret the common results of spectral diffusion experiments. We tested our model in the simplest case by computer simulation, and it shows excellent agreement with the experimental data. To our knowledge this is the first work where a theoretical interpretation of the aging dynamics of proteins is directly and quantitatively related to the experimental observations. We also show that the model, after the generalization that the traps are hierarchically organized, is in accordance with the concept of other well-known EL models.