Balázs Szalontai

Molecular rearrangements of thylakoids after heavy metal poisoning, as seen by Fourier transform infrared (FTIR) and electron spin resonance (ESR) spectroscopy

The specific effects exerted by different heavy metals on both the function and the structure of the photosynthetic apparatus were addressed. The functional analysis performed via the fluorescence induction kinetics revealed that the applied toxic heavy metals can be classified into two groups: Cd and Ni had no significant effect on the photosynthetic electron transport, while Cu, Pb and Zn strongly inhibited the Photosystem II (PS II) activity, as evidenced by the dramatic decreases in both the variable (Fv) and the maximal (Fm) fluorescence. The structural effects of the heavy metal ions on the thylakoid membranes were considered in three relations: (1) lipids, (2) proteins — studied by Fourier transform infrared (FTIR) spectroscopy, and (3) lipid—protein interactions — investigated by electron spin resonance (ESR) spectroscopy using spin-labeled probe molecules. The studied heavy metal ions had only a non-specific rigidifying effect on the thylakoid lipids. As regards proteins, Cd and Ni had no effect on the course of their heat denaturation. The heat denaturation of the proteins was accompanied by a decrease in the α-helix content (1656 cm-1), a parallel increase in the disordered segments (1651 cm-1), a decrease in the intramolecular β-sheet (1636 cm-1) content and the concomitant appearance of an intermolecular β-structure (1621 cm-1). In contrast with Cd and Ni, Cu and Zn blocked the appearance of the intermolecular β-structure. Pb represented an intermediate case. It seems that these heavy metals alter the native membrane structure in such a way that heat-induced aggregation becomes more limited. The ESR data revealed that certain heavy metals also affect the lipid—protein interactions. While Cd and Ni had hardly any effect on the solvation fraction of thylakoid lipids, Cu, Pb and Zn increased the fraction of lipids solvating the proteins. On the basis of the FTIR and ESR data, it seems that Cu, Pb, and Zn increase the surfaces available for lipid—protein interactions by dissociating membrane protein complexes, and that these ‘lipidated’ proteins have a smaller chance to aggregate upon heat denaturation. The data presented here indicate that the damaging effects of poisonous heavy metals are element-specific, Cu, Pb and Zn interact directly with the thylakoid membranes of the photosynthetic apparatus, while Cd and Ni interfere rather with other metabolic processes of plants.

Low-temperature-induced accumulation of xanthophylls and its structural consequences in the photosynthetic membranes of the cyanobacterium Cylindrospermopsis raciborskii: An FTIR spectroscopic study

The effects of the growth temperature on the lipids and carotenoids of a filamentous cyanobacterium, Cylindrospermopsis raciborskii, were studied., The relative amounts of polyunsaturated glycerolipids and myxoxanthophylls in the thylakoid membranes increased markedly when this cyanobacterium was grown at 25°C instead of 35°C. Fourier transform infrared spectroscopy was used to analyze the low-temperature-induced structural alterations in the thylakoid membranes. Despite the higher amount of unsaturated lipids there, conventional analysis of the νsymCH2 band (characteristic of the lipid disorder) revealed more tightly arranged fatty-acyl chains for the thylakoids in the cells grown at 25°C as compared with those grown at 35°C. This apparent controversy was resolved by a two-component analysis of the νsymCH2 band, which demonstrated very rigid, myxoxanthophyll-related lipids in the thylakoid membranes. When this rigid component was excluded from the analysis of the thermotropic responses of the νsymCH2 bands, the expected higher fatty-acyl disorder was observed for the thylakoids prepared from cells grown at 25°C as compared with those grown at 35°C. Both the carotenoid composition and this rigid component in the thylakoid membranes were only growth temperature-dependent; the intensity of the illuminating light during cultivation had no apparent effect on these parameters. We propose that, besides their well-known protective functions, the polar carotenoids in particular may have structural effects on the thylakoid membranes. These effects should be exerted locally—by forming protective patches, in-membrane barriers of low dynamics—to prevent the access of reactive radicals generated in either enzymatic or photosynthetic processes to sensitive spots of the membranes.

Changes in the raman spectrum of frog sciatic nerve during action potential propagation

Abstract Raman spectra of frog sciatic nerves were recorded in different states of functioning. During excitation reversible changes were observed in the C40-carotenoid peaks enhanced by the resonance Raman effect. This change can be explained by transient carbon-carbon bond equalization of the polyene chain. Possible biological consequences are also discussed.

Altered expression of genes for kir ion channels in dilated cardiomyopathy

Dilated cardiomyopathy (DCM) is a multifactorial disease characterized by left ventricular dilation that is associated with systolic dysfunction and increased action potential duration. The Kir2.x K⁺ channels (encoded by KCNJ genes) regulate the inward rectifier current (IK1) contributing to the final repolarization in cardiac muscle. Here, we describe the transitions in the gene expression profiles of 4 KCNJ genes from healthy or dilated cardiomyopathic human hearts. In the healthy adult ventricles, KCNJ2, KCNJ12, and KCNJ4 (Kir2.1-2.3, respectively) genes were expressed at high levels, while expression of the KCNJ14 (Kir2.4) gene was low. In DCM ventricles, the levels of Kir2.1 and Kir2.3 were upregulated, but those of Kir2.2 channels were downregulated. Additionally, the expression of the DLG1 gene coding for the synapse-associated protein 97 (SAP97) anchoring molecule exhibited a 2-fold decline with increasing age in normal hearts, and it was robustly downregulated in young DCM patients. These adaptations could offer a new aspect for the explanation of the generally observed physiological and molecular alterations found in DCM.

The chromophore structure and chromophore-protein interactions in C-phycocyanin as studied by resonance Raman spectroscopy

Abstract We have studied the changes occurring in the electronic absorption and resonance Raman spectra of C-phycocyanin from Synechococcus 6301 (Anacystis nidulans) during denaturation of the protein induced by lowering the pH of the medium. Absorption studies showed that phycocyanobilin probably does not change its native, extended conformation in the pH range 7.5–3.0, but folds into a helical conformation as the pH is lowered further. Resonance Raman spectra obtained using ultraviolet excitation at 363.8 nm and at low temperature (40 K) revealed that non-covalent chromophore-protein interactions which are necessary in maintaining the extended conformation of the phycocyanobilin chromophore in the native protein involve the ends of the chromophore. They probably involve strong interactions from the protein on the two lactam C=O groups. These groups indeed become protonated only at pH values lower than 2.7, hence allowing folding of the chromophore. At pH 1.5 a complete denaturation of the protein occurs, but even this is partly reversible upon restoration of the physiological pH values.

Resonance Raman spectra of phycocyanin, allophycocyanin and phycobilisomes from blue - green alga Anacystis nidulans

Resonance Raman spectra of native C-phycocyanin, allophycocyanin and whole, intact phycobilisomes from the blue-green alga Anacystis nidulans (Synechococcus 6301) are reported. A tentative assignment for the more prominent resonance Raman bands is suggested. The possibly sensitive regions for inter-chromophore interactions in the case of phycobilisomes are also discussed.

Membrane protein dynamics: limited lipid control

Correlation of lipid disorder with membrane protein dynamics has been studied with infrared spectroscopy, by combining data characterizing lipid phase, protein structure and, via hydrogen-deuterium (H/D) exchange, protein dynamics. The key element was a new measuring scheme, by which the combined effects of time and temperature on the H/D exchange could be separated. Cyanobacterial and plant thylakoid membranes, mammalian mitochondria membranes, and for comparison, lysozyme were investigated. In dissolved lysozyme, as a function of temperature, H/D exchange involved only reversible movements (the secondary structure did not change considerably); heat-denaturing was a separate event at much higher temperature. Around the low-temperature functioning limit of the biomembranes, lipids affected protein dynamics since changes in fatty acyl chain disorders and H/D exchange exhibited certain correlation. H/D exchange remained low in all membranes over physiological temperatures. Around the high-temperature functioning limit of the membranes, the exchange rates became higher. When temperature was further increased, H/D exchange rates went over a maximum and afterwards decreased (due to full H/D exchange and/or protein denaturing). Maximal H/D exchange rate temperatures correlated neither with the disorder nor with the unsaturation of lipids. In membrane proteins, in contrast to lysozyme, the onsets of sizable H/D exchange rates were the onsets of irreversible denaturing as well. Seemingly, at temperatures where protein self-dynamics allows large-scale H/D exchange, lipid-protein coupling is so weak that proteins prefer aggregating to limit the exposure of their hydrophobic surface regions to water. In all membranes studied, dynamics seemed to be governed by lipids around the low-temperature limit, and by proteins around the high-temperature limit of membrane functionality. PACS codes: 87.14.ep, 87.14.cc, 87.16.D

Lipids, Proteins, and Their Interplay in the Dynamics of Temperature-Stressed Membranes of a Cyanobacterium, Synechocystis PCC 6803

Proper responses to low- and high-temperature stresses are essential for the survival of many organisms. It has been established that at low-temperature stress the sufficient microviscosity of the lipids is decisive in this respect. In many organisms, adapting the level of lipid unsaturation to the low growth temperature regulates this feature. At high-temperature stresses, however, there are no unequivocal results concerning the role of the lipids. In these temperature ranges, the lipids are all disordered and fluid and their physical parameters change slowly with increasing temperatures, while biological organisms give characteristic stress responses in rather narrow temperature ranges. Therefore, one may speculate that other membrane parameters/components, which change sharply in the range of the high-temperature stress, may give a signal to initiate the general response of the cells. For such a role, proteins are the trivial candidates. To reveal the role of the lipids and the proteins in these processes, we used a genetically engineered system, based on a cyanobacterium, Synechocystis PCC 6803. In the wild-type cells of this bacterium, by altering the growth temperature, the polyunsaturated lipid content of the cell membranes can be varied considerably (as required by the homeoviscous adaptation principle). In the case of desA(-)/desD(-) mutant cells, which can contain only monounsaturated fatty acyl chains in their lipids, homeoviscous adaptation of the lipids is not possible. Since desA(-)/desD(-) mutation affects only the lipids, additional perturbations (e.g., altered protein content) should minimally disturb the comparison of the lipid behaviors in wild-type and mutant cells. Infrared spectra of thylakoid and cytoplasmic membranes isolated from wild-type and mutant cells were recorded in 3 degrees C steps between 8 and 92 degrees C. By analyzing the rates of protein structural changes, hydrogen-deuterium exchange, in-membrane lipid disorder, and water-membrane interfacial order/hydration as functions of the temperature, we conclude that (i) the gel-to-liquid crystalline phase transition of the lipids correlates with the growth temperature in the wild-type cells but not in the desA(-)/desD(-) mutants, (ii) over the physiological temperature range, both protein and lipid dynamics are regulating/regulated, providing remarkably constant dynamics for both the thylakoid and cytoplasmic membrane, (iii) in the high-temperature stress region, protein structure and dynamics are changing sharply without any correlation with growth temperature and/or mutation, i.e., membrane protein stability does not seem to depend on the lipid composition of the membrane (this finding points to the possible primacy of proteins as initiators/targets of heat-shock alarms), and (iv) there are substantial differences between the dynamics of the proteins of the thylakoid and cytoplasmic membranes, reflecting their different protein complexes and lipid-to-protein ratios.

Streptococcal antigen I/II binds to extracellular proteins through intermolecular β‐sheets

One of the functions associated with the oral streptococcal surface protein I/II is to bind to human extracellular matrix molecules or blood components, which could act as opportunistic ligands in pathological circumstances. In order to understand the relative specificity of the binding repertoire of this bacterial adhesin, we examined by infrared measurements the mode of binding of the protein I/II from Streptococcus mutans OMZ175 (I/IIf) to fibronectin and fibrinogen. This approach revealed the β‐structure forming capacity of I/IIf upon interaction with both proteins. The forming of intermolecular β‐structures may provide a non‐selective way of interaction between I/IIf and its possible targets.

Surface-enhanced resonance Raman spectroscopy of phycocyanin and allophycocyanin

High quality surface-enhanced resonance Raman (SERR) spectra were recorded from native and denatured phycocyanin and allophycocyanin on ascorbic acid treated silver hydrosols. The visible-excited SERR and resonance Raman (RR) spectra of the phycobiliproteins were very similar, indicating a predominantly electromagnetic surface enhancement mechanism. Investigation of pH-induced denaturation ofx allophycocyanin has shown that even small differences in protein/chromophore conformational are sensitively reflected by the SERR spectra. Concerning the adsorption of the protein to the metal surface, the experiments have shown that: (i) there is limited possibility for changing protein conformation during the adsorption process, (ii) there are no changes after the protein has been adsorbed onto the silver surface and (iii) for each protein an optimal activation of the silver sol has to be found for recording proper SERR spectra. The results obtained on phycobiliproteins are also discussed in connection with the interpretation of phytochrome Raman spectra.