[The suppression of a herpes simplex virus reproduction with drug resistance by combination 15lys-bis-nt and phosphate of acycloguanosine with some antiherpetic drugs]

Antiherpetic activity of the double and triple combinations, including original connections 15Lys-bis-Nt and phosphate of acycloguanosine (P-ACG), was studied in vitro. For the first time, it was demonstrated that in case of their combined use with known antiherpetic agents, whose activity does not depend on TK of HSV (PFA, AraA, CDV, Rib, GLN, αa-IFN), synergistic or additive effects of interaction was observed. The antiviral effect of the tested combinations was studied on the model of ACG-resistant viral strain. The tested combinations could be of interest for practical medicine.

[Research of suppression of the herpes simplex virus reproduction with drug resistance using a combination 15-Lys-bis-Nt with some antiherpetic drugs]

The antiviral effect of combinations of netropsin derivative 15-Lys-bis-Nt with the known antiherpetic compounds, whose activity does not depend on viral TK and which are able to inhibit replication of HSV in most cases, including strains resistant to acyclovir and pencyclovir, was studied. The combinations evoking additive, synergistic and significant synergistic effects of interaction of tested compounds were observed. The results obtained in this work indicated the possibility of significant reduction of concentrations of high toxic compounds in case of the combined use.

[Estimation of activity of bis-netropsin derivatives based on a model of an experimental cutaneous herpes simplex virus disease of guinea pigs]

Using the model of an experimental cutaneous infection of guinea pig males caused by herpes simple virus type 1, it is shown that application of dimerico derivatives of netropsin Lys-bis Nt and 15Lys-bis Nt in the form of polietilenglicol-based ointment suppresses viral infection more effectively than acyclovir.

[Antiherpetic activity of netropsin derivatives as tested in experiments in laboratory animals]

Two dimeric netropsin derivatives (Lys-bis-Nt 15Lys-bis-Nt) were comprehensively tested for antiviral and toxic activity in cell cultures and laboratory animals. The two compounds were found to provide effective and selective inhibition of reproduction of herpes simplex I both in cell culture Vero E6 and in brain of infected white mice, thereby increasing the survival rate and mean life expectation of treated animals as compared to control.

[Inhibition of herpes simplex virus helicase UL9 by netropsin derivatives and antiviral activities of bis-netropsins]

Data obtained show that antiviral activities of bis-linked netropsin derivatives are targeted by specific complexes formed by helicase UL9 of herpes simplex virus type 1 with viral DNA replication origins, represented by two OriS sites and one OriL site. According to the results of footprinting studies bis-netropsins get bound selectively to an A+T-cluster which separates interaction sites I and II for helicase UL9 in OriS. Upon binding to DNA bis-netropsins stabilize a structure of the A+T-cluster and inhibit thermal fluctuation-induced opening of AT- base pairs which is needed for local unwinding of DNA by helicase UL9. Kinetics of ATP-dependent DNA unwinding in the presence and absence of Pt-bis-netropsin are studied by measuring the efficiency of Forster resonance energy transfer (FRET) between the fluorescent probes attached covalently to 3?- and 5?-ends of the oligonucleotides in the minimal OriS duplex. Pt-bis-netropsin and related molecules inhibit unwinding of OriS duplex by helicase UL9. Pt-bis-netropsin is also able to reduce the rate of unwinding of the AT- rich hairpin formed by the upper strand in the minimal OriS duplex. The antiviral activities and toxicity of bis-linked netropsin derivatives are studied in cell cultured experiments and experiments with animals infected by herpes virus.

[Antiviral properties of the derivatives of netropsin and distamycin against herpes simplex viruses type 1 and variolovaccine]

The antiherpesvirus activity of newly synthesized DNA-binding compounds for cultured Vero E6 cells was examined. The compounds were found to have selective antiherpesviral activity. Their antiviral activity was shown against the virus strains isolated from clinical specimens. The test compounds were ascertained to have also a high activity against herpes simplex virus type 1 (HSV-1/L2 TC-) that was very resistant to acyclovir. The authors' data demonstrated an obvious dose-dependent antiviral effect, which was representatively seen when Pt-bis-Dst and Lys-bis-Nt were used. The findings have offered the challenge to test some of these compounds in experiments on laboratory animals.

[Complex of the herpes simplex virus initiator protein UL9 with DNA as a platform for the design of a new type of antiviral drugs]

The protein binding to the origin of replication of the herpes simplex virus type 1 (HSV-1) is DNA helicase encoded by the UL9 gene of the herpes virus. The protein specifically binds to two binding sites in the viral DNA replication origins OriS or OriL. In order to determine the role of the UL9 protein in the initiation of replication and find efficient inhibitors of the UL9 activity, we have synthesized a recombinant UL9 protein expressed in E. coli cells. It was found that the recombinant UL9 protein binds to Boxes I and II in the OriS and possesses the DNA helicase and ATPase activities. In a complex with a fluorescent analog of ATP, two molecules of the ATP analog bind to one protein dimer molecule. It was also found that the UL9 protein in the dimer form can bind simultaneously to two DNA fragments, each containing specific binding sites for the protein. The interaction of the recombinant UL9 protein with the 63-mer double and single-stranded oligonucleotides OriS and OriS* has been investigated, which correspond to the origin of replication of herpes simplex virus. From the titrations of OriS and OriS* by ethidium bromide in the presence and absence of the UL9 protein, the equilibrium affinity constants of the protein binding to OriS and OriS* have been determined. A DNase I footprinting study showed that bis-linked netropsin derivatives exhibit preferences for binding to the AT-cluster in the origin of replication OriS and inhibit the fluctuation opening of AT-base pairs in the AT-cluster. The drugs also prevent the formation of an intermediate conformation of OriS* that involves a disordered tail at the 3'-end and stable Box I-Box III hairpin to which the UL9 helicase selectively binds. The stabilization by bis-netropsins of the AT-rich hairpin at its 3' end can inhibit the helicase activity. It was concluded that the antiviral activity of bis-netropsins may be associated with the inhibitory effects of bis-netropsins on these two stages of the reaction catalyzed by helicase UL9.

[Statistical fluctuations of the filling level of operator by repressor determine the level of noise of reporter gene expression]

The regulation of the reporter gene activity in a single bacterial cell by means of lambda-phage C1 repressor has been described by the methods of statistical thermodynamics. The equations for the calculation of the mean production rate of the reporter protein and its standard deviation as a function of C1 repressor concentration in the cell have been obtained. The stochastic nature of C1 repressor binding with OR1 and OR2 operator sites becomes apparent when both repressor molecules and operators are present in the bacterial cell in a small number of copies. In this case, the number of repressor molecules that bind to OR1 and OR2 sites fluctuates considerably. The in vitro binding of C1 repressor to OR1 and OR2 sites, their mutant forms, and nonspecific DNA regions has been well studied. Using the binding constants of in vitro binding of C1 repressor to OR1, OR2 and nonspecific DNA regions and also the value of the cooperativity parameter for C1 repressor binding to OR1 and OR2 sites, we calculated the mean rate of synthesis of the reporter protein and its standard deviation as a function of repressor concentration in cell. The theoretical relations fit well the experimental results. The results of calculations confirm the assumption that gene expression noise in a single cell at a repressor concentration exceeding 100 nM is related to the stochastic nature of binding of repressor dimers to OR1 and OR2 sites. Other mechanisms of the generation of gene expression noise (for example, monomer-dimer balance) make a significant contribution at concentrations less than 100 nM.

[The interaction of lamda-Cro repressor and its mutant covalent S-S-dimer lamda-CroV55C with symmetric and asymmetric DNA]

Binding of lamda-Cro protein and mutant CroV55C disulfide bonded dimer to synthetic olygonucleotide duplexes were studied using a competition with distamycin A. The equilibrium binding constants for lamda operator OR3 and duplexes contained symmetry left or right halves of OR3 with one base pair deletion or insertion in center of duplex were calculated. The higher binding constant for Cro was detected with 17 bp symmetry duplex consist two left halves of OR3, for the mutant CroV55C higher binding constant was detected with 16 bp derivate of this duplex with the central GC base pair deletion.

[DNA-binding and antiviral activities of bis-netropsins]

The DNA-binding and antiviral activitus of bis-netropsins in which two monomers are attached covalently via three glycin residue were studied. These compounds have the same C-end groups but contain clusters with different numbers of lysine residues at the N-end of the molecule. In the homologous series of these compounds, bis-neropsins containing 15 and 31 branched lysine residues at the N-end of the molecule appear to be the most effective inhibitors of reproduction of the simplex herpes virus of type I in the Vero cell culture, including the virus versions resistant to aciclovir, ganciclovir, and other medicinal preparations. It was shown that the cytotoxicity of all the compounds studied is much lower than that of netropsin. The antiviral activity of the compounds correlates with their ability to selectively interact with the expanded clusters of the AT-pairs of DNA bases in the form of a monomer or a dimer, stabilized by interaction between the C-end halves of two bis-netropsin molecules bound at the neighboring overlapping binding sites on the DNA. The possible sites of their binding are the expanded clusters of AT-pairs at the origin of replication of OriS and OriL of the herpes virus.

[Statistical fluctuations in processes of gene expression regulation: consideration of the problem from point of view of statistical mechanics]

The regulation of gene expression is a basic problem of biology. In some cases, the gene activity is regulated by specific binding of regulatory proteins to DNA. In terms of statistical mechanics, this binding is described as the process of adsorption of ligands on the one-dimensional lattice and has a probability nature. As a random physical process, the adsorption of regulatory proteins on DNA introduces a noise to the regulation of gene activity. We derived equations, which make it possible to estimate this noise in the case of the binding of the lac repressor to the operator and showed that these estimates correspond to experimental data. Many ligands are able to bind nonspecifically to DNA. Nonspecific binding is characterized by a lesser equilibrium constant but a greater number of binding sites on the DNA, as compared with specific binding. Relations are presented, which enable one to estimate the probability of the binding of a ligand on a specific site and on nonspecific sites on DNA. The competition between specific and nonspecific binding of regulatory proteins plays a great role in the regulation of gene activity. Similar to the one-dimensional "lattice gas" of particles, ligands adsorbed on DNA produce "one-dimensional" pressure on proteins located at the termini of free regions of DNA. This pressure, an analog of osmotic pressure, may be of importance in processes leading to changes in chromatin structure and activation of gene expression.

[Effect of DNA local conformation on the affinity and binding specificity of bis-netropsins to DNA]

The interaction of short nucleotide duplexes with bis-netropsins, in which netropsin fragments are linked in the tail-to-tail orientation via cis-diammineplatinum group (<--Nt-Pt(NH3)-Nt-->) or aliphatic pentamethylene chain (<--Nt-(CH2)5-Nt-->), has been studied. Both the bis-netropsins have been shown to bind to DNA oligomer 5'-CCTATATCC-3' (I) as a hairpin with parallel orientation of netropsin fragments in 1:1 stoichiometry. Monodentate binding has been detected upon binding of bis-netropsins to other duplexes of sequences 5'-CCXCC-3'--where X = TTATT (II), TTAAT (III), TTTTT (IV), and AATTT (V)--along with the binding of bis-netropsins as a hairpin. The formation of dimeric antiparallel motif between the halves of two bound bis-netropsin molecules has been observed in the complexes of <--Nt-(CH2)5-Nt--> with DNA oligomers IV and V. The ratio of binding constant of bis-netropsin as a hairpin (K2) to monodentate binding constant (K1) has been shown to correlate with the width and/or conformational lability of DNA in the binding site. The share of bis-netropsin bound as a hairpin decreases in the order: TATAT > TTATT > TTAAT > TTTTT > AATTT, whereas the contribution of monodentate binding rises. The minimal strong binding site for <--Nt-Pt(NH3)-Nt--> and <--Nt-(CH2)5-Nt--> binding as a hairpin has been found to be DNA duplex 5'-CGTATACG-3'.

[Interaction of synthetic ligands containing N,4-disubstituted mono- and diphthalimides with DNA]

Nevel synthetic DNA binding ligands containing N,4-disubstituted mono- and diphthalimide fragments and carrying positively charged groups at both ends of the molecules were characterized by various physiochemical methods. All the ligands were shown to have fluorescence maximum at about 460 nm for excitation at 340 nm. Interaction of these compounds with DNA and synthetic polydeoxyribonucleotides was studied using spectrophotometry, CD and fluorescence measurements. It was shown, that the ligand containing phthalimide fragment connected by flexible chain to dipyrrolcarboxamide fragment, binds to DNA narrow groove covering 5 base pairs. This type of complex formation was found to be followed by increasing of CD band at 280 nm and increasing in fluorescence intensity. If the ligand backbone contains only phthalimide fragments there is no binding in the DNA narrow groove. In this case the weakly fluorescent outside binding type complex is formed, which is characterized by the binding of one ligand molecule with two base pairs.

[A synthetic zinc chelating peptide competes for DNA binding sites with antibiotics, adsorbed in a minor DNA groove]

Effects of sibiromicyn, distamicyn A and its analogs on binding to DNA and to poly(dA).poly(dT) are reported for a 23-amino acid synthetic zinc-binding peptide, a part of the DNA-binding domain of the transcriptional activator GAL-4. Circular dichroism and fluorometry have shown that the synthetic peptide and two distamicyn A analogs compete for binding sites on DNA and on poly(dA).poly(dT). Antibiotic sibiromycin which forms a covalent bond with a guanine 2-amino group in the minor DNA groove can displace the peptide from a 19 bp self-complementary oligonucleotide serving as a specific target site for Gal-4 protein. The peptide is shown to bind to a glucosylated phage T2 DNA, but its affinity to T2 DNA is weaker than to calf thymus DNA under the same conditions. A method to estimate binding constant and size of the binding site for the synthetic peptide and poly(dA).poly(dT) is proposed based on the binding isotherms of distamycin analogs in the absence and in the presence of the peptide. Using isotherms of binding to poly(dA).poly(dT) for two distamycin analogs with binding constants differing 60-fold, the binding constant of the peptide in the presence of 0.1 M NaCl is estimated as 1.4.10(7)-1.8.10(7) M-1.

[Design of de novo specific DNA-binding peptides, using the motif beta-chain-turn-beta-chain for recognizing a nucleotide sequence in DNA]

De novo design and synthesis by a solid phase technique of linear and cyclic 26-residues peptides are reported. The peptides use beta-strand-turn-beta -strand motif for sequence recognition on DNA. Amino acid sequences in the two peptides are identical, but the structure of the cyclic peptide is constrained by S-S bridge between two cysteine residues. A 28-residue peptide containing at the N-terminus a copper-chelating peptide Gly-Gly-His is also synthesized which can be used as a potential DNA-cleaving reagent. Binding of these peptides to various natural and synthetic DNAs and DNA fragment with a known base pair sequence has been studied by CD spectroscopy, fluorescence methods and DNAse I footprinting technique. By means of CD spectroscopy it is shown that 26-residue linear and cyclic peptides are partially in disordered and beta-conformations in aqueous solution in absence and in presence of 20% trifluoroethanol (TFE), but assume partially an alpha-helix conformation in the presence of 50% TFE. It is shown that linear and cyclic peptides bind to DNA. The binding approaches saturation level when one peptide molecule is bound approximately per three or four DNA base pairs. We found that antibiotic distamycin A, binding in the minor DNA groove, competes effectively with the 26-residue linear and cyclic peptides for binding to poly(dA).poly (dT). According to the CD spectroscopy data the linear and cyclic peptides undergo conformation changes upon binding to DNA, whereas the DNA structure is not markedly altered. Difference CD spectra obtained by subtracting the spectrum of the free DNA from the spectrum of the peptide-DNA mixture differ from the spectrum of the free peptide. The shapes of difference CD spectra are consistent with a conformation transition from a disordered conformation into a beta-like conformation upon binding of peptide to DNA. DNAase I footprinting diagrams show that there is a specific protection by linear and cyclic peptides of the nucleotide sequences on two ends of operators OR1, OR2 and OR3 and pseudooperators within the cro gene of 434 phage.

[Synthesis and interaction of two peptides, modeling the DNA-binding domain of the v-jun transcription activator, with DNA]

Synthesis and DNA-binding activities of the two synthetic 26-residue peptides, containing in two copies a part of the DNA-binding region of the transcription activator v-Jun, are reported. Aminoacid sequences of the two peptides are identical, but in one of them the structure of the DNA-binding region is stabilized by S-S-bond between the two cysteine residues. Using CD spectroscopy, it is shown that the two peptides exist in a random coil conformation in aqueous solution, but assume partially an alpha-helical conformation in the presence of 20% trifluoroethanol. The percentage of alpha-helix is increased in the presence of 40% trifluoroethanol up to approximately 65% and 40% in the absence and presence of S-S-bond between the two cysteine residues, respectively. Evidently, formation of S-S-bond prevents a coil to alpha-helix transition in one of the two DNA-binding regions of the peptide, whereas the formation of alpha-helix in another DNA-binding region is allowed. It is shown that the two peptides bind to DNA. We found that the DNA minor groove-binding antibiotic distamycin A competes with the two peptides for binding to poly(dA).poly(dT). The binding of the two peptides to DNA is accompanied by conformational transitions in the peptide molecules, whereas the structure of DNA does not undergo a marked change. The difference CD spectrum obtained by subtracting the spectrum of DNA from the spectrum of a peptide-DNA mixture differs from the CD spectrum of the free peptide. The shapes of the difference CD spectra are consistent with alpha-beta and coil-beta transitions induced upon binding of the two peptides to DNA. DNase I footprinting diagrams show that peptides mediated cleavage protection of DNA takes place at regions containing 5'-TGA-3' and 5'-TGC-3' nucleotide sequences.

[Interaction of a synthetic peptide, containing a part of the DNA-binding domain of the v-jun transcription activator, with DNA]

Synthesis and DNA-binding activity of the synthetic 26-residue peptide, containing in two copies a part of the DNA-binding domain of the transcription activator v-Jun, are reported. Using CD spectroscopy, it has been shown that the peptide exists in a random coil conformation in aqueous solution, but assumes partially an alpha-helical conformation in the presence of 20% trifluoroethanol. The percentage of alpha-helix is increased in the presence of 40% trifluoroethanol up to approximately 80%. It has been shown that the peptide forms two types of complexes with DNA. The first type of complexes saturates when one peptide molecule occupies six base pairs. At further increase of molar peptide to DNA ratio the binding became a cooperative process. The binding approaches saturation when one peptide molecule is bound approximately to four DNA base pairs. The binding constant of the monomer peptide complex with DNA has been estimated to be approximately 1.10(5) M-1 in the presence of 0.2 M NaCl. The peptide binds more strongly to poly(dG).poly(dC) and poly(dA).poly(dT) than to poly[d(GC)].poly[d(GC)]. We found that the DNA minor groove-binding antibiotic distamycin A competes effectively with the peptide for binding to poly(dA).poly(dT).

[Interaction of a synthetic zinc-binding peptide with DNA]

Synthesis, DNA- and zinc ion-binding activities of the synthetic 23-residue peptide, forming a part of the DNA-binding domain of yeast transcription activator GAL-4, are reported. In presence of zinc ions considerable changes in the shapes of the fluorescence and CD spectra of the peptide are observed. It is shown that the peptide forms complexes with zinc ions containing one metal ion per peptide molecule with association constants on the order of (1-2) x 10(6) M-1. Using gel filtration on a TSK-gel column we have shown that in aqueous solution at concentrations of 10(-4)-10(-6) M the peptide exists predominantly in the dimeric form. Dimerization constants were found to be 5 x 10(6) M-1 and 1.7 x 10(7) M-1 in the absence and in the presence of zinc ions, respectively. It is shown that the peptide binds to DNA. The binding approaches saturation when one peptide molecule is bound approximately to five base pairs of DNA. The shapes of the titration curves obtained from binding of the peptide to DNA show that the peptide can bind to DNA both in the monomeric and self-associated forms (dimer or tetramer). Increasing DNA concentration and decreasing the peptide/DNA molar ratio lead to a shift in the equilibria between self-associated peptide species and monomers toward the formation of monomer peptide complexes.

[Ligands with affinity to specific sequences of DNA base pairs. X. Synthesis and binding of netropsin analogs, containing a chelating copper ion peptide, with DNA]

An analogue of netropsin has been synthesized consisting of two N-propylpyrrolcarboxamide units linked covalently to a copper-chelating tripeptide Gly-Gly-L-His by means of two and three glycine residues. Binding to DNA and synthetic polynucleotides of netropsin analogue containing three glycine residues between Gly-Gly-L-His tripeptide and the N-end of netropsin analogue (His-Nt) has been studied. It is shown that this netropsin analogue chelates a copper ion with 1:1 stoichiometry, similar to a free Gly-Gly-L-His peptide. It is found that this netropsin analogue occupies 3 to 4 base pairs upon binding to poly(dA).poly(dT) and poly[d(AT)].poly[d(AT)] polymers, irrespective of whether it binds in Cu(2+)-ligated or unligated forms. Binding constants and binding site sizes have been calculated for netropsin analogue complexes with DNA, poly(dA).poly(dT) and poly[d(AT)].poly[d(AT)] polymers at the [Cu2+]/[His-Nt] ratio equal to 0 and 1.0. In the three-component system including His-Nt and Cu(2+)-His-Nt, cooperative effects are recognized which can be explained by heterodimer generation on interaction of His-Nt and Cu(2+)-His-Nt at adjacent binding sites.

[Specific DNA cleavage by an analog of netropsin containing a copper(II) chelating peptide Gly-Gly-His]

Experimental data are reported on DNA-cleaving activity of the synthetic netropsin analogs consisting of the two N-propylpyrrole carboxamide units linked covalently through two or three glycine residues to a copper-chelating tripeptide glycyl-glycyl-L-histidine. Incubation of DNA restriction fragment and netropsin analog in the presence of ascorbate, hydrogen peroxide and Cu2+ ions resulted in selective cleavage of the DNA at or near the preferred sites for binding of netropsin analog. A similar cleavage pattern is observed after X-ray irradiation of DNA complexes with netropsin analogs tethered with Cu2+ ions. The cleavage patterns are found to be dependent on the length of the connecting chain between the histidine-containing tripeptide and netropsin analog. The netropsin analog containing three glycine residues in the connecting chain, but not the analog with a shorter linker chain, can generate an intense cleavage of one of the two polynucleotide chains at a position corresponding to the presumed binding site for the dimeric ligand species. More than 50% of the total DNA can be cleaved at this position after X-ray irradiation. From analysis of the nucleotide sequences surrounding the preferred cleavage site on several DNA fragments we found that the consensus is 5'-TTTTNCA*AAA-3', where N is an arbitrary nucleotide. The Cu(2+)-mediated cleavage of DNA occurs at the second adenine (indicated by an asterisk) from the 5'-end of the sequence. The greatest cleavage activity is observed when the molar ratio of Cu2+ to the netropsin analog is equal to 0.5. Evidently, the Cu(2+)-ligated and unligated oligopeptide species interacts with each other to form a heterodimer bound to DNA at the cleavage site. To test the validity of this model we have studied the binding of unligated netropsin analog and netropsin analog complexed with Cu2+ ion to a self-complementary oligonucleotide 5'-GCGTTTTGCAAAACGC-3'. It is found that binding of Cu(2+)-ligated netropsin analog to the DNA oligomer preincubated with unligated form of the oligopeptide is a cooperative process for which interactions between the two bound ligands are responsible. The cooperativity parameter is estimated to be on the order of factor 6. Finally, a model is proposed in which a heterodimer stabilized by interligand beta-sheet binds in the minor DNA groove.

[Interaction of trivaline with single-stranded polyribonucleotides]

Binding of tripeptide H-Val3-(NH)2-Dns (TVP) to polyribonucleotides was studied by fluorescence methods, circular and flow linear dichroism, equilibrium dialysis and electron microscopy. It was found that TVP binds to poly(U) in monomer, dimer and tetramer forms with binding constants of about 10(3), 40, 18.10(4) M, respectively. The cooperativity parameter for peptide dimer binding is 2000. The peptide forms tetramer complexes with poly(A), poly(C), poly(G) also. The formation of a complex between the peptide tetramer and nucleic acid is accompanied by a significant increase in the fluorescence intensity. The cooperative binding of TVP dimers to poly(U), poly(A), poly(C) is accompanied by a dramatic decrease in the flexibility of polynucleotide chains. However, it has a small effect (if any) on the flexibility of the poly(G) chain. The observed similarity of thermodynamic, optical and hydrodynamic++ properties of TVP complexes with single-stranded and double-stranded nucleic acids may reflect a similarity in the geometries of peptide complexes with nucleic acids. Electron microscopy studies show that peptide binding to poly(U) and dsDNA leads to compactization of the nucleic acids caused by interaction between the peptide tetramers bound to a nucleic acid. At the first stage of the compactization process the well-organized rod-like particles are formed, each consisting of one or more single-stranded polynucleotide fibers. Increasing the peptide concentration stimulates a side-by-side association and folding of the rods with the formation of macromolecular "leech-like" structures with the thickness of 20-50 nm.

[Interaction of a cysteine-containing peptide with DNA]

Cystine peptide dimer (Lys-Gly-Val-Cys-Val-N2H2Dns)2 with S-S bridge was synthesized and its interactions with DNA and synthetic polynucleotides have been studied by optical spectroscopy methods. By recording fluorescent titration curves we have shown that the affinity of the peptide to different synthetic polynucleotides decreases in the order: poly(dG).poly(dC) greater than poly(dA).poly(dT) greater than poly(dGC).poly(dGC). The stability of complexes to increasing concentrations of NaCl diminishes in the same order. The association constant is about 20-fold greater for peptide binding to poly(dG).poly(dC) than to poly(dA).poly(dT). By using circular dichroism and fluorescence measurements we have shown that the peptide competes for the binding sites on DNA with two minor-groove binding antibiotics--distamycin A and sybiromycin. These results have suggested that the peptide also binds in the DNA minor groove. Investigation of the interactions between such peptides and DNA may be useful for constructing ligands with combined specificity to DNA.

[Synthesis of nonlinear DNA-binding peptide with binding specificity determinants close to those of 434 Cro-repressor]

Design, synthesis and DNA binding activity of a nonlinear 102 residue peptide are reported. The peptide contains four sequence-specific DNA binding domains of 434 Cro protein. These four domains were linked covalently to a symmetrical carboxyterminal crosslinker that contains four arms each ending with an aliphatic aminogroup. From CD studies we have found that in aqueous buffer in the presence of 20% trifluoroethanol the peptide residues assume alpha helical, beta-sheet and random coiled conformations with an alpha helical content of about 16% at room temperature. The alpha helicity is increased up to 40% in the presence of 40% trifluoroethanol. Upon complex formation between the peptide and DNA a change in the peptide conformation takes place which is consistent with an alpha-beta transition in the DNA binding, helix-turn-helix motif of 434 Cro repressor. Evidently residues present in helices alpha(2) and alpha(3) form a beta hairpin which is inserted in the minor DNA groove. The latter inference is supported by our observations that the peptide can displace minor groove binding antibiotic distamycin A from a complex with poly(dA).poly(dT). As revealed from DNase protection studies the peptide exhibits preferences for binding to operator and pseudooperator sites recognized by 434 Cro repressor. It binds strongly to operator sites OR1, OR2 and OR3 and exhibits a greater affinity for pseudooperator site Op1. From analysis of nucleotide sequences in the strong affinity binding sites for the peptide on DNA a conclusion is drawn that it binds to pseudosymmetrical nucleotide sequences 5'-ACAA(W)nCTGT-3', where W is an arbitrary nucleotide. n is equal to six or seven. In the strongest affinity binding site for the peptide on DNA (Op1) motif 5'-ACAA-3' is replaced by sequence 5'-ACCA-3'. A difference in binding specificity shown by the peptide and 434 Cro protein could be attributed to a flexibility of the connecting chains between DNA-binding domains in the peptide molecule as well as to a replacement of Thr - Ala in the alpha 2 helix. Removal of two residues from the N-terminal end of helix alpha 2 in each of the four DNA binding domains of 434 Cro present in the peptide leads to a loss of binding specificity, although the modified peptide binds to DNA unspecifically.

[Synthetic DNA-bindings ligands containing reaction centers specific for AT- and GC-pairs in DNA]

In the present communication design, synthesis and DNA binding activities of three bis-netropsins and two netropsin analogs containing two N-propylpyrrolecarboxamide fragments linked covalently to peptides Gly-Gly-(analog I) and Val-Val-Val-Gly-Gly-(analog II) are reported. Each bis-netropsin consists of two netropsin-like fragments attached to peptides -Gly-Cys-Gly-NH2 (compound IIIa), H-Gly-Cys-Gly-Gly-Gly-(compound IV) or Gly-Cys-Sar-NH2 (compound IIIb) which are linked symmetrically via S-S bonds. Physico-chemical studies show that each bis-netropsin carries 6 AT-specific reaction centers and covers approximately 10 base pairs upon binding to poly(dA).poly(dT). This indicates that two netropsin-like fragments of the bis-netropsin molecule are implicated in specific interaction with DNA base pairs. The peptide fragments of bis-netropsins IIIa and IV form small beta-sheets containing two-GC-specific reaction centers. The DNase I cleavage patterns of bis-netropsin-DNA complexes visualized by high resolution gel electrophoresis show that the preferred binding sites for bis-netropsins IIIa and IV are identical and contain two runs of three or more AT pairs separated by two GC pairs. Specificity determinants of netropsin analog II binding in the beta-associated dimeric form are identical to those of bis-netropsin IIIa thereby indicating that there is a similarity in the structure of complexes formed by these ligands with DNA. In the monomeric form analog II exhibits binding specificity identical to that of analog I. Replacement of C-terminal glycine residues by sarcosines in the peptide fragments of bis-netropsin IIIa leads to a decrease in the affinity of ligand for DNA.

[Stereochemistry and kinetics of interaction with DNA of the antineoplastic antibiotic olivomycin]

The kinetics of interaction of antitumor glycoside antibiotic olivomycin with DNA has been investigated. The existence of two relaxation times in the experimental kinetics curves indicates that two types of antibiotic--DNA complex are formed. We have measured the rate constants of association and dissociation processes and determined their temperature dependences. It is suggested, that one of the complex form results from nonspecific interaction between glycoside residues of the antibiotic molecule and sugar-phosphate backbone of DNA whereas the other type of complex exhibits a pronounced specificity for GC-rich regions on DNA. The binding specificity probably results from formation of a H-bond between the antibiotic chromophore ring and guanine 2-amino group. A stereochemical model for olivomycin-DNA complex is proposed. According to this model the antibiotic chromophore and glycoside residues are located in the narrow groove of DNA.

[Cooperative effects during the binding of large ligands with DNA. Non-contact interaction between adsorbed ligands]

Equations are derived to describe the cooperative binding of large ligands to DNA. A mathematical approach is developed which enables one to give a simple probabilistic interpretation of binding equations and to solve them in the general case when long-range interactions are allowed between bound ligands. These interactions can be mediated by conformation changes induced in the DNA in the course of binding process and transformed over some distances beyond the DNA region immediately covered by a bound ligand molecule (allosteric effect of DNA). Interactions between ligand molecules can be formally described in terms of model potential characterizing pairwise interactions between bound ligands. A procedure is developed which allows one to determined the form of such potential from experimentally measured binding isotherms. It is based on a comparison of experimental binding isotherms with the appropriate curves calculated for the case of non-interacting ligands.

[Interactions between distamycin A analogs bound to DNA]

The experimental binding isotherms of the distamycin A analog to 8 natural and synthetic DNAs were analyzed. The shapes of binding isotherms suggest that the bound ligand molecule induces transitions of DNA (B-form) into two perturbated conformation states. These transitions are responsible for the existence of positive and negative cooperative effects on binding of distamycin analogs to DNA. At low levels of binding positive cooperative effects play a dominating role whereas at high levels of binding negative cooperative effects are observed. These cooperative effects can be described by the aid of a potential of pairwise interactions between nearest neighbour bound antibiotic molecules. A detailed analysis of experimental binding isotherms shows that characteristic distances over which these interactions are extended depend on the AT content of DNA. The energetical and structural parameters characterising the allosteric transitions of DNA to the perturbated states are obtained.

[Spatial structure of DNA complex with the oligopeptide dansyl hydrazide trivaline]

The structure of complexes between double-stranded DNA and oligopeptide dansyl hydrazide trivaline was studied by linear dichroism, electron microscopy and hydrodynamical methods. The results show that the binding of the oligopeptide to DNA is a cooperative process that leads to the formation of particles significantly differing in the structure from free DNA. The linear dichroism studies were carried out in a wide range of flow-speed gradients. From the theoretical analysis of these data a conclusion can be drawn that the DNA-oligopeptide complexes possesses a higher rigidity as compared with that of free DNA. The hydrodynamical behaviour of these particles is consistent with the rigid rod-like structure of the particles with a long axis nearly parallel to the DNA helix axis in the complexes. The sedimentation patterns of the complexes suggest the existence of the fast and slow sedimenting species. The sedimentation coefficient measured for a fast sedimenting species is about 3 times higher than that of free DNA. The linear dichroism spectra obtained for the floworiented DNA-oligopeptide complexes correlate with the existence of a superhelical organization of DNA in the complex. This offers a possibility for the determining of the angle of the DNA local axis inclination with respect to the superhelix axis. On electron micrographs the DNA-oligopeptide complexes look like rod-shaped structures with the thickness of about 180 A and 80 A on the rotatory-shadowed preparations and on the uranylacetate stained preparations, respectively. The rod-shaped structures are formed by two interwound DNA molecules. The superhelix has a pitch of about 150 A with an angle of twist inclination of about 40 degrees. These values are in good agreement with the optical anisotropic data. It is suggested that the complex structure is stabilized by periodically spaced hydrophobic contacts between the dimeric oligopeptide species bound to the DNA molecules.

[Determination of the number of GC-pairs "recognized" by actinomycin D during binding with DNA]

Experimental studies are reported on the binding of actinomycin D to various synthetic and naturally occurring DNAs. The experimental data obtained agree with a model in which the antibiotic molecule carries only one GC-specific reaction center and covers 5 base pairs upon binding to DNA. Positive cooperative effects are observed for the binding of actinomycin to poly(dG-dC)-poly (dG-dC) duplex.

[Mechanism of AT base pairs recognition by molecules of dye "Hoechst 33258"]

Experimental studies are reported on the binding of the dye "Hoechst 33 258" to DNA and synthetic polynucleotides. A stereochemical model of binding of the dye to DNA is proposed. According to the model, the molecules of the dye are located in the minor groove of DNA, each covering 4 base pairs. The benzimidazole backbone of the dye tends to form a helix isogeometric to that of DNA in the B form. The specifisity of "Hoechst 33 258" binding to At pairs involves hydrogen bonding of two NH-groups of benzimidazole rings and CH3N+H group of the piperazine ring to O2 oxygenes of thymines and N3 nitrogens of adenines facing the minor groove of the DNA double helix.

[Binding of actinomycin D analogs to DNA]

Equilibrium and kinetic studies are reported on the binding to DNA of actinomycin D analogues containing various substituents at position 7 of the antibiotic chromophore. The binding constants are calculated from the experimental binding isotherms of actinomycin D and its analogues to calf thymus DNA. The rate constants of the association and dissociation processes are measured by stop -- flow method. From these experiments a conclusion is drawn that small substituents (such as nitro or aminogroups) at position 7 of the actinomycin chromophore exhibit a little (if any) influence both on the affinity of antibiotic for DNA and kinetics of association and dissociation processes, while bulky substituents decrease the antibiotic binding affinity and make kinetics behavior slower.

[Specific reaction between oligovaline and nucleic acids]

The DNA binding activity of trivaline dansyl hydrazide was investigated by circular dichroism, UV spectrophotometry and fluorescence methods. It is shown that these peptides in the absence of DNA can adopt statistical coil and antiparallel beta-conformation and can exist in aqueous solution as monomers, dimers and higher orders aggregates depending upon the concentration and the presence of N- and C-blocking groups. The aggregation and disaggregation processes are very slow especially for N- and C-protected peptides. Our observations show that oligopeptides in the monomeric and dimeric forms bind to double-stranded DNA and RNA whereas tetramers and higher order aggregates exhibit no DNA binding activity. The binding of monomers is a cooperative process favoring the formation of deformed antiparallel beta-structure between adjacently bound monomers. The binding constant of dimeric oligovaline species to GC-rich DNA sequences is about 5 fold higher than that found from the binding of oligovaline to poly(dA) . poly(dT). The binding of dimers takes place in the minor DNA groove as revealed from our observations that oligovaline binds to T6 phage DNA containing massive glucose and diglucose residues in the major groove. The backbone C=0 groups of oligovaline probably serve as specific reaction centres for the interaction with guanine 2-amino groups in the minor DNA groove.

[Binding of actinomycin D analogues containing some substituents at position 7 of the antibiotic chromophore to DNA]

Spectrophotometric methods are used to study the binding to DNA of Actinomycin D (AMD) and its analogues: 7-nitro-AMD; 7-amino-AMD; 7-(Z-Val-Glo-NH)-AMD; 7-(AcO- . +H2-Val-Glo-NH)-AMD; 7-(AcO- . +H2-Val-Glo-Val-Glo-NH)-AMD. The binding constants are calculated from the binding isotherm of AMD and those of the AMD analogues to calf thymus DNA obtained by spectrophotometric titration. Introduction of smaller substituents such as the nitro or amino groups into position 7 of chromophore influences insignificantly the antibiotic binding to DNA, whereas bulky substituents cause a decrease in the affinity of the AMD analogues for DNA, although the spectral characteristics are not affected.

[Reaction of fluorescent labeled analogs of the antibiotic distamycin A with synthetic polydeoxyribonucleotides]

Interaction of DNA with the analogs of the antibiotic distamycin A having different numbers of pyrrolcarboxamide units and labeled with dansyl was studied. The intensity of fluorescence of these analogs increases markedly when they bind to DNA. It is shown that the introduction of dansyl into the analog molecules does not change their binding characteristics. The binding isotherms of the analogs to synthetic polydeoxyribonucleotides were obtained. Analysis of the experimental data leads to the following conclusions: 1. The free energy of binding of the analogs to poly(dA1 . poly(dT) depends linearly on the number of pyrrolcarboxamide units in the molecule of the analog whereas attachment of each pyrrolcarboxamide unit produces change of 2 kcal/mole in the free energy. 2. Attachment of a pyrrolcarboxamide unit to GC pair results in the free energy change of 0.95 kcal/mole. 3. Adenine and thymine are close but not equivalent by the energy of binding to the analogs of distamycin A. 4. The binding of analogs to poly(dA . poly(dT) is a cooperative process, presumably dependent on the conformational changes induced by the binding of analogs to DNA.

[Precise relationships for calculating the binding of regulatory proteins and other lattice ligands in double-stranded polynucleotides]

The binding of long multisite ligands to double-stranded nucleic acids is considered. The ligand is taken as a lattice of AT- and GC-specific reaction centres the sequence of which is complementary to the base pair sequence in the specific ligand interaction site on DNA. Exact equations are derived for the two cases: that when a ligand binds in a fixed orientation relative to the DNA and that when it can be attached to DNA in the two alternative orientations related by two-fold rotation. Included in the formulation are two alternative orientations related by two-fold rotation. Included in the formulation are the ligand size effects as well as cooperative effects for which the interactions between the nearest neighbour adsorbed molecules are responsible. In particular, if cooperative interactions are allowed only between the adjacent ligand molecules related by two-fold rotation symmetry, the ligands would tend to associate into symmetrical "dimers" upon binding to DNA. This model enables one to explain the recognition of specific base sequences which are related by two-fold rotation symmetry and are complementary to the sequence of ligand reaction centres. Numerical calculations are carried out for several specific cases and for various values of parameters involved in the theoretical model.

[Structure of DNA complexes with regular polypeptides]

The conformation of some regular polypeptides: (Lys-Ala)50, (Lys-Ala2)37, (Lys-Ala2)26, (Lys-Ala3)18, (Lys3-Pro)29, (Orn3-Gly)28 was studied by means of CD. The complexes of these polypeptides with DNA were obtained by the methods of jump-dilution of a two-components mixture from 2 M NaCl to 0.05 M NaCl. The extent of DNA covering by the polypeptides was compared using binding isoterms of ethidium on DNA and DNA-polypeptide complex. The length, L, which polypeptides cover on DNA was estimated by means of energy transfer between the dyes absorbed on the complexes. The CD spectra of the complexes revealed a high sensitivity to changes of the environmental conditions. Small variations in the temperature and ionic strength produces marked changes in the CD spectra of the complexes. It was suggested that observed CD changes are due to both the structural relaxation of the complexes and the existence of liquid-crystal domains in solution.

[Addition of the fluorescent label to the 3'-OH end of DNA and the 3'-OH end of nascent RNA]

3'(2')-O-acyl derivatives of the uridine triphosphate were synthesized. Acyl residues contained fluorescent dye; fluoresceine or rodamine C. Optical properties and stability of UTP analogues were studied. Their ability to serve as the substrates for calf thymus terminal deoxyribonucleotidyl transferase and E. coli RNA polymerase was also examined. It was shown that both enzymes were able to use tested analogues as substrates. Incorporation of the analogues into nascent RNA and DNA chains inhibited the synthetic reaction because of primer inactivation. The rate of the incorporation of the analogues showed an exponential time dependence

[Oxytetracycline binding to E. coli ribosomes]

Binding of oxytetracycline to E. coli ribosomes was studied by equilibrium dialysis. The results are consistent with the existence of two classes of binding sites for the antibiotic on ribosomes having different reactivities. There is one strong binding site as well as about 500 weak ones. The association constant for strong complexes is about 10(3) times greater than the value for weak ones. Oxytetracycline and tetracycline bind to ribosomes as magnesium chelates. Increase of the concentration of Mg2+ leads to the formation of two types of magnesium chelates of the antibiotic: chelate 1 which is formed at a relatively low concentration of Mg2+ and has a stiochiometry 1:1, and chelate 2 which probably corresponds to the attachment of second ion to the antibiotic molecule. The strong binding of oxytetracycline to ribosomes prevents the template dependent association of aminoacyl-tRNA with ribosomes. However, no changes in the extent of the antibiotic binding were found upon addition of aminoacyl-tRNA, poly(U) and chloramphenicol to oxytetracycline-ribosome complexes. It has been suggested that inhibiting effect of oxytetracycline on the protein synthesis involves an allosteric mechanism.

[A code governing specific binding of regulatory proteins to DNA and structure of stereospecific sites of regulatory proteins]

A model is proposed for the structure of stereospecific sites in regulatory proteins. On its basis a possible code is suggested that governs the binding of regulatory proteins at specific control sites on DNA. Stereospecific sites of regulatory proteins are assumed to contain pairs of antiparallel polypeptide chain segments which form a right-hand twisted antiparallel beta-sheet, with single-stranded regions at the ends of the beta-structure. The model predicts that binding reaction between a regulatory protein and double-helical DNA is a cooperative phenomenon and is accompanied by significant structural alteration at the stereospecific site of the protein. Half of hydrogen bonds normally existing in beta-structure are broken upon complex formation with DNA and a new set of hydrogen bonds is formed between polypeptide amide groups and DNA base pairs. In a stereospecific site, one chain (t-chain) is attached through hydrogen bonds to the carbonyl oxygens of pyramides and N3 adenines lying in one DNA strand, while the second polypeptide chain (g chain) is hydrogen bonded to the 2-amino groups of guanine residues lying in the opposite DNA strand. The amide groups serve as specific reaction sites being hydrogen bond acceptors in g-chain and hydrogen bond donors in t-chain. The single-stranded portions of t- and g-chains lying in neighbouring subunits of regulatory protein interact with each other forming deformed beta-sheets. The recognition of regulatory sequences by proteins is based on the structural complementarity between stereospecific sites of regulatory proteins and base pairs sequences at the control sites. An essential feature of these sequences is the asymmetrical distribution of guanine residues between the two DNA strands. The code predicts that there are six fundamental amino acid residues (serine, threonine, asparagine, histidine, glutamine and cysteine) whose sequence in stereospecific site determines the base pair sequence to which a given regulatory protein would bind preferentially. The code states a correspondence between four amino acid residues at the stereospecific site of regulatory protein with the two residues being in t- and g-segments, respectively, and AT(GC) base pair at the control site. It is thus possible to determine which amino acid residues in the repressor and which base pairs in the operator DNA are involved in specific interactions with each other, as exemplified by lac repressor binding to lac operator.

[Structure of the complexes of distamycin type antibiotics and actinomycin D with DNA: new data on the localization of these antibiotics within the DNA narrow groove]

It is shown that antibiotics actinomycin D (AM), netropsin (Nt), distamycin A (DM) and the propyl analogue of distamycin A (pDM) being complexed with DNA are located within the narrow groove of DNA. A comparative investigation of the 3H-dimethyl sulphate methylation extent of free calf thymus DNA and its complexes with AM, Nt, DM and pDM reveals that upon DNA saturation these antibiotics decrease the methylation level of the narrow groove (AM by 30%, pDM by 50%, DM by 65% and Nt by 70%). In the triple complex of DNA+AM+DM the methylation level of the narrow groove drops by 80%. The large groove is not shielded by these antibiotics at all. However, the methylation level of the large groove decreases by 50% for T6 phage DNA due to the presence of glucosyl residues linked to 5-hydroxymethylcytosine within the large groove. The binding of AM to DNA saturated with Nt or with the analogue of distamycin A (DM2) containing the 2 N-methylpyrrole residues has been investigated by spectrophotometry. The apparent number of binding sites for AM in these 2 complexes is about half as much as observed for free DNA while the saturation level of the binding decreased only by about 20%. This proves simultaneous presence of AM and Nt (DM2) within the narrow groove of DNA.