[Palivizumab: four seasons in Russia].

In 2010, the Russian Federation (RF) registered palivizumab--innovative drug, based on monoclonal antibodies for passive immunization of seasonal respiratory syncytial virus (RSV) infection in children of disease severe progress risk group, which include primarily premature infants, children with bronchopulmonary dysplasia and hemodynamically significant congenital heart disease. Currently, palivizumab is included in the list of recommended medicines and medical care standards of different countries, including Russia. In the review the results of Russian research on the progress of RSV infection, its epidemiology and immunization experience gained over the 2010-2014 period are summarized in relation to the foreign data. During the four epidemic seasons palivizumab immunization covered more than 3,200 children of severe RSV infection risk group with a progressive annual increase in the number of patients who received the drug. Geography of palivizumab immunization is also greatly expanded in our country during this time. If during the first two seasons measures of immunization were taken mainly in Moscow and St. Petersburg, at the present time, thirty one territorial entities of the Russian Federation have the experience in the drug application. Analysis of the results of RSV infection immunization (made in several regions) confirms the high clinical efficacy and palivizumab safety already demonstrated in international studies. In addition, the analysis presents the potential to improve the efficiency of the integrated RSV infection immunization programs, realizing in the establishment of high-risk child group register, adequate counseling for parents, as well as the development of the routing of patients and coordination of interaction between different health institutions during the immunization.

[Prothymosin alpha interacts with C-terminal domain of histone H1 and dissociates p53-histone H1 complex].

A novel mode of the tumor suppressor protein p53 regulation, mediated by recruitment of the linker histone H1 to the promoters of p53 target genes leading to specific repression of p53-dependent transcription, has recently been uncovered. Yet, how this repression could be relieved is not clear. Previously, a histone-binding nuclear protein prothymosin alpha (ProTa) was shown to trigger a p53 response. The histone-binding region of ProTa was found to be essential for this effect, raising a possibility that ProTa stimulates p53-dependent transcription by dissociating the p53-histone H1 repressive complex. Here, we have shown that ProTa interacts with the same C-terminal domain of histone H1 as p53 does and, therefore, ProTa and p53 could compete for binding to histone H1. Furthermore, ProTa, when competent for histone H1 binding, is able to liberate p53 from the histone H1-p53 complex in vitro. In vivo, stimulation of p53-dependent transcription by ProTa correlates with ability of ProTa to interact with histone H1. Ectopic expression of histone H1 or its C-terminal ProTa-binding domain specifically suppresses the stimulating effect of ProTa on transcription of the p53-responsive reporter gene in cultured cells. These results are consistent with the model that ProTa may enhance p53 transcription activity by displacement of histone H1 from p53-H1 repressive complex.

[Effect of chemical chaperones on properties of lysozyme and the reaction center protein from Rhodobacter sphaeroides].

The influence of three chemical chaperones: glycerol, 4-hexylresorcinol, and 5-methylresorcinol on the structure, equilibrium fluctuations, and the functional activity of the hydrophilic enzyme lysozyme and the transmembrane reaction center (RC) protein from Rb. sphaeroides in a broad range of concentrations has been studied. Selected chemical chaperones are strongly different by the structure and action on hydrophilic and membrane proteins. The influence of the chemical chaperones (except methylresorcinol) on the structure, dynamics, and functional properties of lysozyme and RC protein are well described within the frames of extended models of preferential hydration and preferential interaction of protein with a chemical chaperone. A molecule of hexylresorcinol consists of a hydrophobic (alkyl radical) and a hydrophilic (aromatic nuclus) moieties. This fact provides additional regulation of functional activity of lysozyme and RC by hexylresorcinol. The influence of methylresorcinol on proteins differs from that of glycerol and hexylresorcinol. Methylresorcinol interacts with the surface of lysozyme directly, not via water hydrogen bonds. This leads to a decrease in denaturation temperature T(d), and an increase in the amplitude of equilibrium fluctuation, which allows him to be a powerful activator. Methylresorcinol interacts with the membrane RC protein only by the condensation of hydration water, which is negligible in the case of methylresorcinol. Therefore, methylresorcinol does not effect the functional properties of the RC protein. It was concluded that various chaperones at one and the same concentration and chaperones at different concentrations form diverse 3D structures of proteins, which differ by dynamic and functional characteristics.

[Influence of prothymosin alpha and its mutants on activity of the p53 tumor suppressor].

Overexpression of the nuclear oncoprotein prothymosin a enhanced and, in a reciprocal experiment, down-regulation of endogenous prothymosin alpha by RNA interference approach inhibited transcriptional activity of the p53 tumor suppressor in the reporter gene assay. Ectopic expression of prothymosin alpha enhanced not only p53-dependent transcription, but also intracellular level of p53 in HeLa (but not HCT116) cells. Ability to stimulate p53-dependent transcription was lost by C-terminal mutants of prothymosin alpha with impaired nuclear accumulation, but not by N-terminal deletion mutants and by the double mutant of prothymosin alpha with impaired ability to bind Keap1, suggesting that prothymosinalpha-Keap1 interaction is dispensable for p53 response. Our data suggest that the central "acidic" region of prothymosin alpha together with intact nuclear localization signal is responsible for stimulation of p53-dependent transcription. This conclusion was confirmed by the fact that another protein containing long "acidic" region and nuclear localization signal, parathymosin, was able to stimulate transcription of p53-responsive reporter gene.

Effects of oxygen, heavy water, and glycerol on electron transfer in the acceptor part of Rhodobacter sphaeroides reaction centers.

The kinetics of electron transfer between primary and secondary quinone acceptors of the photosynthetic reaction center (RC) of the purple bacterium Rhodobacter sphaeroides wild type was studied at the wavelengths 400 and 450 nm. It was shown that removing of molecular oxygen from RC preparations slowed down the fast phase of the process from 4-4.5 microsec to tens of microseconds. Similar effects were observed after the incubation of RC in heavy water for 72 h or glycerol addition (90% v/v) to RC preparations. The observed effects are interpreted in terms of the influence of these agents on the hydrogen bond system of the RC. The state of this system can determine the formation of different RC conformations that are characterized by different rates of electron transfer between quinone acceptors.

[A study of protein structure changes during hydration by diffuse X-ray scattering. I. The intensity and the shape of "10-angstrom" maximum].

The angle dependencies of diffuse x-ray scattering intensities were studied in a wide range of angles from 3 to 80 degrees for water-soluble and membrane proteins with a different structural organization: alpha-helical protein myoglobin, alpha-helical protein serum albumen, alpha + beta protein lysozyme, and transmembrane proteins of photosynthetic reaction centers (RC) from purple bacteria Rhodobacter sphaeroides, and Blastochlorii (Rhodopseudomonas) viridis containing cytocrome c, situated out side the membrane, and for H and L+M subunits of membrane protein of reaction center from Rb. sphaeroides for various hydration degrees. The hydration/dehydration process was studied for water-soluble proteins (within hydration range from h = 0.05 to h = 1). The hydration/dehydration process appears to be reversible. All water-soluble proteins show a 10 angstroms peak, and proteins of reaction center do not show this peak. A quantitative comparable study of the behaviour for of the 10 angstroms peak different proteins the degree of lysozyme hydration increases from h = 0.05 to h = 0.45, the protein structure slightly changes (most probably the motifoffolding), the structure of myoglobin in solution is slightly different from the structure in crystal. By taking into account the changes in the shape and intensity of the 10 angstroms peak only, it is impossible to make the conclusion about structural changes in other proteins studied. A correlation between the structural changes observed and dynamic and functional properties of proteins is discussed.

[The temperature dependence of high-resolution 1H NMR spectra of Rhodobacter sphaeroides photosynthetic reaction centres in a temperature range of 25-40 degrees C]. / Kharakter temperaturnoi zavisimosti spektrov protonnogo IAMR vysokogo razresheniia v fotosinteticheskikh reaktsionnykh tsentrakh Rhodobacter sphaeroides v intervale 25-40 C.

High-resolution 1H-NMR spectra registered within a temperature range of 25-40 degrees C revealed a nonmonotonous dome-shaped temperature dependence of the ratio between integral NMR signal intensities determined at ppm intervals 2.5-4.5 and 0.2-2.5 with a maximum at 30 degrees C. This may be due to RC structural changes accompanying the temperature rise and accelerating the recombination reaction between oxidized bacteriochlorophyll and reduced primary quinone at temperatures above 30 degrees C.

Temporary stabilization of electron on quinone acceptor side of reaction centers from the bacterium Rhodobacter sphaeroides wild type and mutant SA(L223) depending on duration of light activation.

The dark reduction of photooxidized bacteriochlorophyll (P+) by photoreduced secondary quinone acceptor (QB-) in isolated reaction centers (RC) from the bacterium Rhodobacter sphaeroides wild type and mutant strain SA(L223) depending on the duration of light activation of RC was studied. The kinetics of the dark reduction of P+ decreased with increasing light duration, which is probably due to conformational changes occurring under prolonged light activation in RC from the wild type bacterium. In RC from bacteria of the mutant strain in which protonatable amino acid Ser L223 near QB is substituted by Ala, the dependence of reduction kinetics of P+ on duration of light was not observed. Such dependence, however, became observable after addition of cryoprotectors, namely glycerol and dimethylsulfoxide, to the RC samples from the mutant strain. It was concluded that substitution of Ser L223 with Ala disturbs the native mechanism of electrostatic stabilization of the electron in the RC quinone acceptor site. At the same time, an additional modification of RC hydrogen bonds by glycerol and dimethylsulfoxide probably includes various possibilities for more effective time delay of the electron on QB.

[Postvaccinal immunity and immunological aspects of Haemophilus influenzae carrier state in children of different age groups after the administration of "Act-HIB" vaccine]. / Postvaktsinal'nyi immunitet i immunologicheskie aspekty bakterionositel'stva Haemophilus influenzae u detei razlichnykh vozrastnykh grupp posle vvedeniia vaktsiny "Akt-khib".

The article deals with H. influenzae (different serotypes) carrier state and immune response before and after the administration of the vaccine "Act-HIB" to children of different age groups. Children aged up to 1 year and over 1 year have been found to differ in the dynamics of carrier state and in the concentration of antibodies of different classes to the antigens of this infective agent, which makes it necessary to carry out their early immunization with a view to ensure their protection from H. influenzae infection.

Recombination reduction of photooxidized cytochrome c in reaction centers of Rhodopseudomonas viridis at low temperature.

The temperature dependence of dark reduction of photooxidized cytochrome c was studied in isolated preparations of Rhodopseudomonas viridis reaction centers. Within the range from room temperature to approximately 260 K this process was found to be mediated by thermal diffusion of exogenous donor molecules, whereas at lower temperatures photooxidized cytochrome is reduced as a result of indirect recombination with photoreduced primary quinone acceptor. Kinetic simulation allowed certain thermodynamic characteristics of this reaction to be calculated. To the first approximation, these characteristics correlate with the estimates obtained from the results of direct redox titration.

Effect of D2O and cryosolvents on the redox properties of bacteriochlorophyll dimer and electron transfer processes in Rhodobacter sphaeroides reaction centers.

Effects of environmental changes on the reaction pattern of excitation energy trapping and transformation into the "stable" radical pair P+Q(A)-, have been analyzed in isolated reaction centers of the anoxygenic purple bacterium Rhodobacter sphaeroides. The following results were obtained: (a) replacement of exchangeable protons by deuterons significantly retarded the electron transfer steps of primary charge separation, leading to the radical pair P+I- and of the subsequent reoxidation of I- by the quinone acceptor Q(A) but has virtually no effect on the midpoint potential of P/P+ that was found to be 430+/-20 mV; (b) addition of 70% (v/v) glycerol causes a shift of Em by about 30 mV towards higher values whereas the kinetics of the electron transfer reactions remain almost unaffected; (c) in the presence of the cryoprotectant DMSO, a combined effect arises, i.e. a retardation of the electron transfer kinetics comparable to that induced by H/D exchange and simultaneously an upshift of the Em value to 475+/-20 mV, resembling the action of glycerol. These results are discussed within the framework of effects on the midpoint potential due to the dielectric constant of the medium and changes of the charge distribution in the vicinity of the redox groups and the influence of relaxation processes on electron transfer reactions.

Effects of extraction of the H-subunit from Rhodobacter sphaeroides reaction centers on relaxation processes associated with charge separation.

Effects of extraction of the H-subunit from Rhodobacter sphaeroides photosynthetic reaction centers (RC) on the characteristics of the photoinduced conformational transition associated with electron transfer between photoactive bacteriochlorophyll and primary quinone acceptor were studied. Extraction of the H-subunit (i.e., the subunit that is not directly bound to electron transfer cofactors) was found to have a significant effect on the dynamic properties of the protein--pigment complex of the RC, the effect being mediated by modification of parameters of the relaxation processes associated with charge separation.

The dipyridamole effect on the photoactive bacteriochlorophyll interaction with quinone acceptors in reaction centers of purple bacteria.

The effect of Dipyridamole (10(-6)-10(-3) M) on the photomobilized electron transport in the system of quinone acceptors Q(A)-Q(B) of isolated photosynthetic reaction centers of Rhodobacter sphaeroides and on its temporary stabilization on Q(B) was studied. Depending on the type of the detergent present in the reaction center (lauryl dimethylamine oxide, Triton X-100, sodium dodecyl sulfate, and sodium cholate), dipyridamole could increase the time of the electron transfer to Q(B). The dipyridamole effect on the efficiency of the electron stabilization on Q(B) for reaction centers with different detergents was revealed in slowing down the process of dark reduction of photoactive bacteriochlorophyll from Q(B) at initial concentrations of added dipyridamole (10(-6)-10(-5) M) with following acceleration of the process at the dipyridamole concentrations of 10(-4)-10(-3) M. The pH lowering from 6.8-7.0 to 5.9-6.0 increased the dipyridamole effect. The possibility of the dipyridamole effect on the structural-dynamic state of the reaction center complex, including its hydrogen bond system, which influences the studied parameters of functional activity, is suggested.

Dipyridamole and its derivatives modify the kinetics of the electron transport in reaction centers from Rhodobacter sphaeroides.

A well known vasodilator dipyridamole (DIP), 2,6-bis(diethanolamino)-4,8-dipiperidinopyrimido[5,4-d]pyrim idine, and its derivatives have recently been shown as potential co-activators (modulators) in the phenomenon of multidrug resistance (MDR) in cancer therapy. They inhibit the specific function of a transmembrane P-glycoprotein responsible for the ex-flux of anti-cancer drugs from tumor cells. To clarify molecular mechanisms of the anti-MDR activity of DIP and its two derivatives, RA25 and RA47, we have studied their effects on electron transport in reaction centers (RC) from purple photosynthetic bacteria Rb. sphaeroides, using RC as a model system. Increasing concentrations of DIP and RA47 progressively accelerate the back electron transfer from the primary quinone acceptor QA to the bacteriochlorophyll dimer Bchl2 (Bchl2+ -QA- recombination). In the absence of o-phenantroline, when both quinone acceptors QA and QB are involved in the electron transport, RA47 is more effective than DIP. DIP stabilizes the electron on the secondary quinone acceptor QB, the effect manifested as the retardation of Bchl2+ -QB- recombination. Effects of RA25 are negligible in all cases. The drugs are proposed to change the electron transport affecting the RC structural dynamics and the stabilization of the electron on quinone acceptors through modification of H-bonds in the system.

Effect of dipyridamole on the recombination kinetics between photooxidized bacteriochlorophyll and photoreduced primary quinone in reaction centres of purple bacteria.

The action of dipyridamole (DIP) on dark recombination between the photooxidized special pair bacteriochlorophyll BChl2+ and reduced primary quinone acceptor Q(A)- in the reaction centres (RCs) of the bacteria Rhodobacter sphaeroides was studied in the presence of different detergents (LDAO, Triton X-100, sodium cholate, sodium dodecyl sulfate). DIP accelerated this reaction approximately 4-5-fold. In RCs with the extracted H-subunit, the effect of DIP was observed at lower concentrations. The possibility of modification of the RC structure-dynamic state by DIP (including changes in RC hydrogen bonds) is proposed. The modification obviously disturbs the processes of the long-life electrostatic stabilization of Q(A)-.

Methods of isolation of reaction center preparations from photosynthetic purple bacteria.

Various modern methods of isolation of functionally active membrane complexes of the reaction centers (RC) from photosynthetic purple bacteria are reviewed. Special attention is given to the methods of RC isolation from bacteria which are widely used in experimental practice. The analysis includes the main steps of RC isolation, evaluation of purity of the resultant preparation, and characterization of its functional activity. Besides description of conventional methods of RC isolation based on ion-exchange chromatography and hydroxyapatite chromatography, some other methods such as affinity chromatography and high-performance chromatography at high and fine pressure are also considered.

Slowing of proton transport processes in the structure of bacterial reaction centers and bacteriorhodopsin in the presence of dipyridamole.

Dipyridamole, 2,6-bis(diethanolamino)-4,8-dipiperidinopyrimido(5, 4-d)pyrimidine, is employed in clinical practice as a vasodilator. It can also inhibit a specific membrane protein (glycoprotein P) which pumps anticancer drugs out of tumor cells. Dipyridamole (10-4 M) markedly slows down the kinetics of the electrogenic phase of the photoelectric response in Rhodobacter sphaeroides chromatophores. This phase is due to proton transfer from the external medium to the secondary quinone acceptor in the reaction center. In purple membranes of bacterium Halobacterium salinarium containing bacteriorhodopsin dipyridamole (in its charged state) significantly slowed the kinetics of proton transfer from the primary donor, Asp-96 (in membranes from bacteria of wild type), or from the external medium (in D96N mutant) to the Schiff base. It is suggested that dipyridamole can influence the structural-dynamic state of membrane proteins including modification of the structure of their hydrogen bonds involved in proton-transport processes.

The cytochrome subunit structure in the photosynthetic reaction center of Chromatium minutissimum.

Gel-electrophoretic assay revealed that the photosynthetic reaction center (RC) of Chromatium minutissimum, in contrast to the well-known RC Rhodopseudomonas viridis, consists of five rather than four subunits with molecular masses of 37, 34, 25, 19, and 17 kDa. The 37- and 19-kDa subunits are stained with tetramethylbenzidine for the cytochrome c hemes. Absorption spectra show that the concentration of reduced cytochromes in the C. minutissimum RC poised at redox potential of -150 mV (fully reduced pool of hemes) is about three times more than in the C. minutissimum RC poised at redox potential of +260 mV (only high-potential hemes are reduced). The results of redox titration of absorption changes at the cytochrome c alpha-band are most appropriately approximated by a six-component theoretical curve with the midpoint potentials of Em1 = 390 mV, Em2 = 320 mV, Em3 = 210 mV, Em4 = 100 mV, Em5 = 20 mV, and Em6 = -50 mV. Possible functions of the cytochromes with the midpoint potentials 210 and 100 mV, which have not been found in purple bacteria before, are discussed.

Effect of deuteration and cryosolvents on the energy transduction in primary processes of photosynthesis.

Effects of cryosolvents and D2O/H2O substitution on the reaction centres (RCs) isolated from photosynthetic bacteria were studied with respect to the role of intra-protein hydrogen bonds in the primary photosynthetic electron transfer. As a result of such treatment of RCs, the charge separation rate between the photoactive bacteriochlorophyll (P2 dimer) and bacteriopheophytin and the rate of electron transfer to the primary quinone slowed down. The energy migration rate from bacteriopheophytin (BPheM), inactive in electron transport, to P2 decreased as well. Although cryosolvents can shift the redox potential of the photoactive pigment, there is no direct correlation between the P2 potential and the effects of these modifying agents on the photosynthetic process in RCs occurring with participation of P2. The removal of H subunit from the pigment-protein complex results in the pronounced weakening of the dimethyl sulfoxide modifying effects on the RC hydrogen bonds. The role of structural and dynamic state in the functioning of the photosynthetic bacterial RCs is analyzed. Relaxation processes in purple bacteria RCs accompanying the primary picosecond steps of energy transformation proceed with the participation of small proton-containing molecular groups in the immediate surroundings of electron transfer carriers. In this paper, we present results concerning mechanisms of primary photosynthetic steps, which were initiated by A. A. Krasnovsky and have been studied for several years at the Department of Biophysics. This paper is dedicated to the memory of our teacher Prof. A. A. Krasnovsky.