Molecular properties of lysine dendrimers and their interactions with Aß-peptides and neuronal cells.

Prevention of amyloidosis by chemical compounds is a potential therapeutic strategy in Alzheimer's, prion and other neurodegenerative diseases. Regularly branched dendrimers and less regular hyperbranched polymers have been suggested as promising inhibitors of amyloid aggregation. As demonstrated in our previous studies, some widely used dendrimers (PAMAM, PPI) could not only inhibit amyloid aggregation in solution but also dissolve mature fibrils. In this study we have performed computer simulation of polylysine dendrimers of 3rd and 5th generations (D3 and D5) and analysed the effect of these dendrimers and some hyperbranched polymers on a lysine base (HpbK) on aggregation of amyloid peptide in solution. The effects of dendrimers on cell viability and their protective action against Aß-induced cytotoxicity and alteration of K+channels was also analysed using human neuroblastoma SH-SY5Y cells. In addition, using fluorescence microscopy, we analysed uptake of FITC-conjugated D3 by SH-SY5Y cells and its distribution in the brain after intraventricular injections to rats. Our results demonstrated that dendrimers D3 and D5 inhibited amyloid aggregation in solution while HpbK enhanced amyloid aggregation. Cell viability and patch-clamp studies have shown that D3 can protect cells against Aß-induced cytotoxicity and K+channel modulation. In contrast, HpbK had no protective effect against Aß. Fluorescence microscopy studies demonstrated that FITC-D3 accumulates in the vacuolar compartments of the cells and can be detected in various brain structures and populations of cells after injections to the brain. As such, polylysine dendrimers D3 and D5 can be proposed as compounds for developing antiamyloidogenic drugs.

[The application of synthetic peptides to characterize the site-directed antiviral humoral immune response in patients with respiratory syncytial viral infection].

The article deals with the study of characteristics of epitope-specific humoral immune response to respiratory syncytial viral infection depending on nature of disease and patients' age. The couple serums from 226 children and adults with respiratory syncytial viral infection were analyzed. To detect in enzyme immunoassay the epitope-specific IgG the synthetic peptides were applied imitating the structure of functionally depended epitopes of F-protein of respiratory syncytial virus with amino acid sequences 221-232 (F = SP12), 479-491 (F-SP13) and G-protein with amino acid sequences 152-164 (G-H13), 184-198 (G-T15). The respiratory syncytial viral infection neutralizing antibodies were detected using the microneutralization reaction. The rate of seroconversions of epitope-specific IgG consisted 21-25% in children 3-18 years old under primary respiratory syncytial viral infection and increased up to 42-50% in children 3-18 years old and adults under recurrent episodes of diseases. In these groups, the seroconversions of respiratory syncytial virus neutralizing antibodies were observed in 42%, 65% and 58% of cases correspondingly. Independently of age of patients with diagnosed respiratory syncytial viral infection, the absence of conversions of neutralizing antibodies was statistically significant associated with the absence of response from epitope-specific IgG. The presence among B-cell epitopes of immune dominance of surface glycoproteins of respiratory syncytial virus in patients with recurrent (but not primary) respiratory syncytial viral infection is detected The hierarchy of epitope-specific immune response in case of complicated course of disease (response activity to epitopes: SP12 = G-T15 > G-H13) differed from the case of uncomplicated course of disease.

[Peptides derived from the third cytoplasmatic loop of serotonin 1B receptor subtype selectively inhibit serotonin signal transduction via a homologous receptor].

The third intracellular loops of hormonal receptors play the main role in the interaction of majority of the serpentine type receptors with heterotrimeric G-proteins. In recent years, it was shown that synthetic peptides corresponding to membrane-proximal regions of these loops could be selectively influenced with hormonal signal transduction via the receptors homologous to them and trigger signalling cascade in absence of the hormone. For the first time, we succeeded in synthesizing the peptides derived from C-terminal region of the third intracellular loop of the IB-subtype serotonin receptor and studied their influence on serotonin-sensitive adenylyl cyclase system in the rat brain. The peptides 300-316 and 306-316 (the numbers correspond to amino acid positions in the rat IB-subtype serotonin receptor) at micromolar concentrations in absence of hormone-stimulated GTP-binding of Gi,-proteins coupled with the IB-subtype serotonin receptors and inhibited forskolin-stimulated adenylyl cyclase activity. Using selective agonists and antagonists of serotonin receptors it was shown that the peptides 300-316 and 306--316 inhibited serotonin signal transduction via homologous to them receptor and weakly influenced other types of serotonin receptors. The peptide 300-316 is more active compared with its shorter analogue 306-316 in the selectivity and efficiency of action on adenylyl cyclase signalling system regulated via the IB-subtype serotonin receptors. These findings indicate that the regions 300-316 of the IB-subtype serotonin receptor are involved in interaction with Grproteins and consist of the main molecular determinants responsible for serotonin signal transduction to adenylyl cyclase.

[Hyperbranched polylysines modified with histidine and arginine: the optimization of their DNA compacting and endosomolytic properties].

The DNA compacting and transfection properties of hyperbranched polylysines whose N-terminal amino groups were modified with histidine and arginine were studied. The histidine-modified hyperbranched polylysines were shown to provide higher efficacy of binding and transfection in comparison with unmodified or hyperbranched arginine-containing polylysines. This fact was explained by the intrinsic endosomolytic activity of the histidine-modified polymers. The dependence between the quantity of the amino acids that modified the terminal lysine residues in the hyperbranched polylysines, the efficacy of their DNA binding, and the transfection activity of the DNA complexes with the corresponding carriers was found. The possibility to increase the transfection activity of the DNA complexes with the hyperbranched polylysines by glycerin or the JTS-1 amphipathic nonapeptide was studied. At the same time, their simultaneous use was found to result in a transfection decrease.

[The receptor of serpentine type and the heterotrimeric G protein as targets of action of the polylysine dendrimers].

The molecular mechanisms of action of the polycationic peptides--polylysine homo- and heterodendrimers on functional activity of biogenic amines- and peptide hormones-sensitive adenylyl; cyclase signaling system (AC system) in the myocardium and the brain of rats were studied. These peptides are expected to be used as highly effective polymer carries for biologically active substances. The polylysine homodendrimers of the third [(NH2)16(Lys)8(Lys)4(Lys)2Lys-Ala-NH2] (I), fourth [(NH2)32(Lys)16(Lys)8(Lys)4(Lys)2Lys-Ala-NH2 (II) and fifth [(NH2)64(Lys)32(Lys)16(Lys)8(Lys)4(Lys)2Lys-Ala-NH2] (III) generations and the polylysine homodendrimers of fifth generation--[(NH2)64(Lys-Glu)32(Lys-Glu)16(Lys-Glu)8(Lys-Glu)4(Lys-Glu)2Lys-Ala-Ala-Lys (ClAc)-Ala-NH2] (IV), [(NH2)64(Lys-Ala)32(Lys-Ala)16(Lys-Ala)8(Lys-Ala)4(Lys-Ala)2Lys-Ala-Lys(ClAc)-Ala-Ala-NH2] (V) and [(NH2)64(Lys-Gly-Gly)32(Lys-Gly-Gly)16(Lys-Gly-Gly)8(Lys-Gly-Gly)4(Lys-Gly-Gly)2 Lys-Gly-Gly-Lys(ClAc)-Ala-Ala-NH2] (VI) showed receptor-independent mechanism of heterotrimeric G-proteins activity, preferably of inhibitory type, interacting with C-terminal regions of their alpha-subunits. The homodendrimers II and III and heterodendrimer V are more effective G-protein activators. The polylysine dendrimers disturbed the functional coupling of the receptors of biogenic amines and peptides hormones with Gi-proteins and, in a lesser extent, Gs-proteins. This is illustrated by the decrease in regulatory effects of the hormones on AX activity and G-protein GTP binding and by the decrease in receptor affinity to agonists in the presence of the polylysine dendrimers, as result of receptor--G-proteins complex dissociation. It was shown also that the molecular mechanisms and the selectivity of the action on the G-proteins of the polylysine dendrimers were similar to those of mastoparan and melittin, natural toxins of insect venom.

Studies of the molecular mechanisms of action of relaxin on the adenylyl cyclase signaling system using synthetic peptides derived from the LGR7 relaxin receptor.

The peptide hormone relaxin produces dose-dependent stimulation of adenylyl cyclase activity in rat tissues (striatum, cardiac and skeletal muscle) and the muscle tissues of invertebrates, i.e., the bivalve mollusk Anodonta cygnea and the earthworm Lumbricus terrestris, adenylyl cyclase stimulation being more marked in the rat striatum and cardiac muscle. Our studies of the type of relaxin receptor involved in mediating these actions of relaxin involved the first synthesis of peptides 619-629, 619-629-Lys(Palm), and 615-629, which are derivatives of the primary structure of the C-terminal part of the third cytoplasmic loop of the type 1 relaxin receptor (LGR7). Peptides 619-629-Lys(Palm) and 615-629 showed competitive inhibition of adenylyl cyclase stimulation by relaxin in rat striatum and cardiac muscle but had no effect on the action of relaxin in rat skeletal muscle or invertebrate muscle, which is evidence for the tissue and species specificity of their actions. On the one hand, this indicates involvement of the LGR7 receptor in mediating the adenylyl cyclase-stimulating action of relaxin in rat striatum and cardiac muscle and, on the other, demonstrates the existence of other adenylyl cyclase signal mechanisms for the actions of relaxin in rat skeletal muscle and invertebrate muscle, not involving LGR7 receptors. The adenylyl cyclase-stimulating effect of relaxin in the striatum and cardiac muscles was found to be decreased in the presence of C-terminal peptide 385-394 of the alpha(s) subunit of the mammalian G protein and to be blocked by treatment of membranes with cholera toxin. These data provide evidence that in the striatum and cardiac muscle, relaxin stimulates adenylyl cyclase via the LGR7 receptor, this being functionally linked with G(s) protein. It is also demonstrated that linkage of relaxin-activated LGR7 receptor with the G(s) protein is mediated by interaction of the C-terminal half of the third cytoplasmic loop of the receptor with the C-terminal segment of the alpha(s) subunit of the G protein.

[Lysine dendrimers as vectors for delivering genetic constructs to eukaryotic cells].

Asymmetrical lysine dendrimers are promising as vectors for delivering gene expression constructs into mammalian cells. The condensing, protective, and transfection properties were studied for pentaspherical lysine dendrimer D5 and its analog D5C10, modified with capric acid residues at the outer sphere; in addition, the transfection activity was assayed for complexes DNA-dendrimer-endosomolytic peptide JTS-1. Fatty acid residues incorporated in lysine dendrimers proved to improve their ability to bind DNA, to protect DNA from nuclease degradation, and to ensure its transfer into the nucleus. Peptide JTS-1 introduced in DNA-dendrimer complexes significantly increased their transfection activity. The potentiating effect of JTS-1 was especially high with the DNA-D5C10 complex. An excess of JTS-1 changed the structure of the complexes and reduced their transfection activity. It was assumed that dendrimers D5 and D5C10 are promising vectors for delivering DNA to eukaryotic cells and provide a basis for constructing more refined nonvirus module carriers.

[Comparative study of molecular mechanisms of natural and synthetic polycationic peptides action on the activity of the adenylyl cyclase signaling system].

The molecular mechanisms of action of natural and synthetic polycationic peptides, forming amphiphilic helices, on the heterotrimeric G-proteins and enzyme adenylyl cyclase (AC), components of hormone-sensitive AC system, were studied. It is shown that synthetic peptides C-epsilonAhx-WKK(C10)-KKK(C10)-KKKK(C10)-YKK(C10)-KK (peptide I) and (GRGDSGRKKRRQRRRPPQ)2-K-epsilonAhx-C(Acm)(peptide II) in dose-dependent manner stimulate the basal AC activity, inhibit forskolin-stimulated AC activity and decrease both stimulating and inhibiting AC effects of the hormones in the tissues (brain striatum, heart muscle) of rat and in smooth muscles of the mollusc Anodonta cygnea. AC effects of these peptides are decreased after membrane treatment by cholera and pertussis toxins and are inhibited in the presence of the peptides, corresponding to C-terminal regions 385-394 alphas- and 346-355 alphai2-subunits of G-proteins. These data give evidence that the peptides I and II act on the signaling pathways which are realized through Gs- and Gi-proteins. At the same time, natural polycationic peptide mastoparan acts on AC system through Gi-proteins and blocks hormonal signals mediated via Gi-proteins only. Consequently, the action of mastoparan on G-proteins is selective and differs from the action of the synthetic peptides. It is also shown that peptide II, with branched structure, directly interacts not only with G-proteins (less effective in comparison with peptide I with hydrophobic radicals and mastoparan), but also with enzyme AC, the catalytic component of AC system. On the basis of data obtained the following conclusions were made: 1) the formation of amphiphilic helices is not enough for selective activation of G-protein by polycationic peptides, and 2) the primary structure of the peptides, the distribution of positive charged amino acids and hydrophobic radicals in them are very important for selective interaction between polycationic peptides and G-proteins.

[Study of molecular mechanisms of the relaxin action on adenylyl cyclase signaling system using synthetic peptides derived from the relaxin receptor LGR7].

The peptide hormone relaxin in dose-dependent manner stimulates adenylyl cyclase activity in the rat tissues (brain striatum, heart and skeletal muscles) and the muscle tissues of invertebrates--bivalve mollusk Anodonta cygnea and earthworm Lumbricus terrestris. Adenylyl cyclase stimulating effect of the hormone is most expressed in striatum and heart muscles of rats. For identification of the type ofrelaxin receptors, participating in the realization of this effect of the hormone, the peptides 619-629, 619-629-Lys(Palm) and 615-629 derived from the primary structure of C-terminal region of the third intracellular loop of the relaxin receptor of type 1 (LGR7), were synthesized by us for the first time. It is shown that peptide: 619-629-Lys(Palm) and 615-629 in competitive manner inhibit the stimulation of the adenylyl cyclase by relaxin in brain striatum and heart muscle of rats. At the same time, these peptides do not change stimulating effect of the hormone in the skeletal muscles of rat and in the muscles of invertebrates. Thus, the peptide action on adenylyl cyclase effect of relaxin is tissue- and species-specific. These data, on the one hand, demonstrate participation of receptor LGR7 in realization of adenylyl cyclase stimulating effect of relaxin in striatum and heart muscle of rats and, on the other, give evidence for existence of another adenylyl cyclase signaling mechanisms of relaxin action in the skeletal muscles and the muscle of invertebrates, which do not involve LGR7 receptor. The adenylyl cyclase stimulating effect of relaxin in striatum and heart muscle was decreased in the presence of C-terminal peptides 385-394 of alpha(s)-subunit of mammalian G protein and was blocked by treatment of the membranes with cholera toxin. On the basis of data obtained the following conclusions were made: (i) in striatum and heart muscle the relaxin stimulates adenylyl cyclase through LGR7 receptors functionally coupled with Gs protein, and (ii) the coupling between hormoneactivated relaxin receptor LGR7 and Gs protein is realized via the interaction of C-terminal part of receptor third intracellular loop and C-terminal segment of Gs protein alpha-subunit.

[Starlike branched and hyperbranched biodegradable polymer systems as DNA carriers].

The information on the synthesis of new biologically compatible and biologically degradable DNA carriers based on starlike polymer conjugates of proteins (lysine dendrimers and their derivatives) and hyperbranched polyamino acids is reviewed. Their capacity to bind and compact DNA and to provide for transfection is discussed based on results obtained with model systems. The English version of the paper: Russian Journal of Bioorganic Chemistry, 2006, vol. 32, no. 3; see also http://www.maik.ru.

Decrease in functional activity of G-proteins hormone-sensitive adenylate cyclase signaling system, during experimental type II diabetes mellitus.

The development of experimental type II diabetes mellitus in rats was accompanied by dysfunction of inhibitory and stimulatory heterotrimeric G-proteins, components of hormone-sensitive adenylate cyclase signal system. The function of inhibitory G-proteins decreased most significantly under these conditions, which is seen from weakened regulatory effects of somatostatin (in the myocardium) and bromocriptine (in the brain striatum) realized via inhibitory G-proteins in diabetic rats compared to controls. These hormones produce less pronounced inhibitory effect on forskolin-induced activation of adenylate cyclase. In the myocardium of diabetic rats, the stimulatory effects of isoproterenol and relaxin on adenylate cyclase realized via stimulatory G-proteins were decreased to a lesser extent. In the striatum of diabetic rats the stimulatory effect of serotonin and relaxin did not differ from the control. Therefore, dysfunction of stimulatory G-proteins during type II diabetes mellitus is characterized by tissue specificity. Synthetic peptides corresponding to functionally important regions in a-subunits of G-proteins and relaxin receptor LGR7 less effectively inhibited hormone signal transduction via the adenylate cyclase system in rats with type II diabetes. These changes reflect abnormal coupling between receptors and G-proteins in tissues of diabetic rats.

[Optimization of transfection properties of DNA-lysine dendrimer complexes].

We studied the possibility of optimizing the DNA transfection properties of carriers based on lysine dendrimers of the third and the fifth generation, including those containing a chloroacetyl or a lipophilic palmitoyl moiety at C-end. The use of lysosome-destroying antibiotic chloroquine and an amphipathic polycationic nonadecapeptide JTS-1 was found to enhance the DNA transfecting properties of the lysine dendrimers. The triple complex including DNA, a lysine dendrimer of the third generation modified with lipophylic moieties of palmitic acid at its C-end, and JTS-1 was shown to be comparable in its transfecting activity to a complex containing Escort, a commercial cationic liposome carrier.

[Cationic oligopeptides modified with lipophilic fragments: use for DNA delivery to cells].

Cationic oligopeptides, including the amphipathic alpha-helical peptides, are applied to the targeted delivery of DNA to eukaryotic cells due to their DNA-compacting properties and the ability to destabilize the cell lipid bilayer in some cases. We synthesized the peptides differing in the number and location of residues of decanoic acid covalently attached to Lys residues in order to combine the DNA-binding and the membrane activities in a single molecule. We chose peptide structures that assisted in the formation of alpha-helices. The DNA-binding ability of the peptides and the membrane activity of their complexes with DNA were shown to depend on the structure. The study of erythrocyte hemolysis by complexes with DNA of the pCMV LacZ plasmid and the peculiarities of transfection of these complexes revealed a correlation between the hemolytic activity and the expression level of the lacZ gene in the cells.

[Inhibitory action of polycationic peptides on hormonal regulation of adenylyl cyclase of the ciliate Dileptus anser].

To analyse molecular mechanisms of regulatory action of different hormones on the activity of the adenylyl cyclase signaling system (ACS) of the ciliate Dileptus anser, we studied the influence on this process of six synthetic polycationic peptides and peptides, corresponding to C-terminal regions of mammalian G-protein 385-394 alphas- and 346-355 alphai2-subunits. As we reported earlier, these peptides block hormonal signal transduction in tissues of the higher eukaryotes. Now it has been found that both polycationic peptides, containing hydrophobic C to-radicals, and branched peptides decrease regulatory effects of peptide hormones (insulin, relaxin) and biogenic amines (serotonin, adrenaline) on adenylyl cyclase (AC) activity and GTP-binding. In regard to the following peptides Cys-epsilonAhx-Trp-Lys-Lys(C10)-Lys2-Lys(C10)-Lys3-Lys(C10)-Tyr-Lys-Lys(C10)-Lys-Lys-amide and [(Gly-Arg-Gly-Asp-Ser-Gly-Arg-Lys-Lys-Arg-Arg-Gln-Arg-Arg-Arg-Pro- Pro-Gly)2-Lys-EAhx-Cys]2 (epsilonAhx - E-aminocaproyl, C10 - caprinoyl group) their dose-dependent inhibitory action is shown. In cell culture of D. anser with a lower basal AC activity, both hydrophobic and branched peptides stimulated AC and GTP-binding without hormones. The data give evidence that these peptides can activate ACS of ciliates in a receptor-independent manner. No influence of peptides 385-394 alphas and 346-355 alphai2 on hormonal signal transduction in D. anser was observed, due, presumably, to some structural differences of G-proteins of the lower and higher eukaryotes. A conclusion was made about an important role of polycationic regions for functional coupling of hormone-activated receptor and G-proteins in the ciliate D. anser.

[The age-related specificity of site-oriented immunity in respiratory-syncytial virus infection]. / Vozrastnye osobennosti saitnapravlennogo immuniteta pri respiratorno-sintsitial'noi virusnoi infektsii.

ELISA test systems were designed on the basis of synthetic peptides (SP) simulating the primary structure of functionally significant epitopes of the respiratory and cyncyntial virus (RCV) F-protein for the purpose of investigating the structure and age-related peculiarities of humoral immunity in respect to separate epitopes of RCV F-protein. One of them (221-232) simulates a part of RCV "virus-neutralizing domain" and another one (479-491) is highly important for the fusion mechanisms. New SP-based ELISA were used to examine pair sera in 159 patients with documented RCV infection including children, aged up to 3 years and 3 to 15, and adults. The activity of anti-RCV antibodies to SP was found to be significantly lower in children aged up to 3 years versus the older children and especially versus the adults. The virus neutralizing and, to a greater extent, fusion-inhibiting activities of antibodies were increasing with age, which collated with the results of detecting the antibodies to SP by immune-enzyme assay. The results testify to synchronism of formation of antibodies to different epitopes of the RCV F-protein. The shaping-up of antibodies with the above SP could denote the protective properties of humoral immunity, which justifies the use of the SP-based ELISA in its analysis, especially, in babies as well as in different-type immunodeficiency and immunopathology conditions.

[Dissociation action of cationic peptides with hydrophobic radicals on functional coupling between serpentine type receptors and GTP-binding proteins]. / Razobshchaiushchee vliianie kationnykh peptidov, soderzhashchikh gidrofobnye radikaly, na funktsional'noe sopriazhenie retseptorov serpantinnogo tipa s GTF-sviazyvaiushchimi belkami.

The coupling of hormone-activated receptor and heterotrimeric G protein is an important step of the signal transduction through adenylyl cyclase signal system (ACS). The numerous literature data and own results show that G protein-interacting regions, that are localized in cytoplasmic loops of receptors, have considerable positive charge, can form amphiphilic alpha-helices and are tightly associated with the membrane. We studied the influence of model cationic peptides on both basal and stimulated by hormones and nonhormonal agents adenylyl cyclase (AC) activity and on GTP binding activity of heterotrimeric G proteins in skeletal muscles of rats and smooth muscles of mollusc Anodonta cygnea. Peptides with hydrophobic radicals of caprinoyl acid (C10): Lys(C10)-His-Glu-Lys-Lys-(C10)-His-Glu-Lys-Lys(C10)-His-Glu-Lys-Lys(C10)- His-Glu-Lys-Ala-amide (peptide I), Cys-Lys(C10)-X-Tyr-Lys-Ala-Lys7-Trp-Lys-amide (II), Cys-X-Trp-Lys-Lys(C10)-Lys2-Lys(C10)-Lys3-Lys(C10)-Tyr-Lys-Lys(C10)-Lys-Lys- amide (III), where X--epsilon-aminocaproyl acid residue, were synthesized by solid-phase methodology. IC50 values for inhibiting the influence of peptides on serotonin-(molluscs) and isoproterenol-stimulated (rats) AC activity were: for peptide I--56 and 70 mkM, for peptide II--32 and 47 mkM, for peptide III--22 and 28 mkM, respectively. At the same time the peptides weakly decreased AC activity stimulated by nonhormonal agents (NaF, Gpp[NH]p, forskolin). Peptides I--III stimulated basal activity of the enzyme in both investigated tissues. The maximum stimulating effects (28--52%) of the peptides were observed at their concentration 10 mkM. Peptides (10--100 mkM) increased Gpp[NH]p binding in plasma membranes of mollusc and rat muscles and strongly decreased the influence of the hormones on the binding. Based on the obtained data we supposed that cationic peptides with hydrophobic radicals mimic G protein-binding regions of the receptors and can be involved in the regulation of functional coupling between the receptors and G proteins.