Biogenic polyamines spermine and spermidine activate RNA polymerase and inhibit RNA helicase of hepatitis C virus.

Influence of the biogenic polyamines spermine, spermidine, and putrescine as well as their derivatives on the replication enzymes of hepatitis C virus (HCV) was investigated. It was found that spermine and spermidine activate HCV RNA-dependent RNA polymerase (NS5B protein). This effect was not caused by the stabilization of the enzyme or by competition with template-primer complex, but rather it was due to achievement of true maximum velocity V(max). Natural polyamines and their derivatives effectively inhibited the helicase reaction catalyzed by another enzyme of HCV replication - helicase/NTPase (NS3 protein). However, these compounds affected neither the NTPase reaction nor its activation by polynucleotides. Activation of the HCV RNA polymerase and inhibition of the viral helicase were shown at physiological concentrations of the polyamines. These data suggest that biogenic polyamines may cause differently directed effects on the replication of the HCV genome in an infected cell.

Analysis of the Domains of Hepatitis C Virus Core and NS5A Proteins that Activate the Nrf2/ARE Cascade.

The hepatitis C virus (HCV) triggers a chronic disease that is often accompanied by a spectrum of liver pathologies and metabolic alterations. The oxidative stress that occurs in the infected cells is considered as one of the mechanisms of HCV pathogenesis. It is induced by the viral core and NS5A proteins. It is already known that both of these proteins activate the antioxidant defense system controlled by the Nrf2 transcription factor. Here, we show that this activation is mediated by domain 1 of the NS5A protein and two fragments of the core protein. In both cases, this activation is achieved through two mechanisms. One of them is mediated by reactive oxygen species (ROS) and protein kinase C, whereas the other is triggered through ROS-independent activation of casein kinase 2 and phosphoinositide 3-kinase. In the case of the HCV core, the ROS-dependent mechanism was assigned to the 37-191 a.a. fragment, while the ROS-independent mechanism was assigned to the 1-36 a.a. fragment. Such assignment of the mechanisms to different domains is the first evidence of their independence. In addition, our data revealed that intracellular localization of HCV proteins has no impact on the regulation of the antioxidant defense system.

Recent studies of T7 RNA polymerase mechanism.

Bacteriophage T7 RNA polymerase (T7 RNAP) is known to be one of the simplest enzymes catalyzing RNA synthesis. In contrast to most RNA polymerases known, this enzyme consists of one subunit and is able to carry out transcription in the absence of additional protein factors. Owing to its molecular properties, the enzyme is widely used for synthesis of specific transcripts, as well as being a suitable model for studying the mechanisms of transcription. In this minireview the recent data on the structure and mechanism of T7 RNAP, including enzyme-promoter interactions, principal stages of transcription, and the results of functional studies are discussed.

The mechanisms of the cyclic AMP-dependent regulation of the enzymes of the 2',5'-oligoadenylate system.

The cAMP-dependent induction of 2,5-oligoadenylate (2-5A) synthetase and cAMP-dependent inhibition of 2-5A phosphodiesterase are shown. Variations in activities of cAMP-dependent protein kinase and the enzymes of 2-5A metabolism in the cells deepening into the resting state were found to be compatible with the above finding. A scheme of coordinated action of cAMP and 2-5A is proposed.

On the functional role of the Tyr-639 residue of bacteriophage T7 RNA polymerase.

Substitution of Asp for a Tyr residue normally present at position 639 of the bacteriophage T7 RNA polymerase leads to a drastic drop in the enzymatic activity. This mutation does not affect the enzyme-promoter interaction but decreases the ability of the RNA polymerase to discriminate between GTP and ATP molecules, resulting in a decrease in the rate of the incorporation of the nucleotide into the RNA chain.

Tyr-571 is involved in the T7 RNA polymerase binding to its promoter.

The in vitro studies of three T7 RNA polymerase point mutants suggest that substitutions of Ala and Thr for Pro-563 and of Ser for Tyr-571 have little effect on the enzyme catalytic competence, but result in its inability to utilize the promoter. Both P563A and P563T mutants retain the promoter-binding ability, whereas the promoter affinity of the Y571S mutant drops drastically.

Regulation of 2',5'-oligo(A) synthetase activity in theophylline-treated NIH 3T3 cells.

Sequential treatment of NIH 3T3 cells with theophylline and actinomycin D results in an enhancement of 2',5'-oligo(A) synthetase activity 2-3-fold exceeding that induced by treatment with theophylline only. This 'superinduction' phenomenon suggests the existence of a negative control of the enzyme that involves a labile, transcription-dependent factor.

Substrate properties of C'-methyl UTP derivatives in T7 RNA polymerase reactions. Evidence for N-type NTP conformation.

The number of synthetic UTP analogues containing methyl groups in different positions of the ribose moiety were tested as substrates for T7 RNA polymerase (T7 RNAP). Two of these compounds (containing substituents in the 5' position) were shown to be weak substrates of T7 RNAP. 3'Me-UTP was neither substrate nor inhibitor of T7 RNAP while 2'Me-UTP was shown to terminate RNA chain synthesis. Conformational analysis of the analogues and parent nucleotide using the force-field method indicates that the allowed conformation of UTP during its incorporation into the growing RNA chain by T7 RNAP is limited to the chi angle range of 192-256 degrees of N-type conformation.

Synthesis of mixed ribo/deoxyribopolynucleotides by mutant T7 RNA polymerase.

Synthesis of deoxynucleotide-containing RNA-like single-stranded polynucleotides (dcRNAs) using the Y639F, S641A mutant of T7 RNA polymerase (T7 RNAP) was studied. A number of different T7 promoter-containing plasmids were tested as templates for dcRNA synthesis. The dcRNA synthesis efficiency strongly depended on the sequence of the first 8-10 nucleotides immediately downstream of the promoter and increased with the distance of the first incorporated dNMP from the transcription start. The incorporation of dGMP which is obligatory for most T7 promoters in positions +1-+2(3) was practically negligible. Using the constructed plasmid pTZR7G containing seven dG links in the non-coding chain immediately downstream of the promoter, the synthesis of all possible dcRNAs (except dG-containing) was achieved with high yields.

Mutant T7 RNA polymerase is capable of catalyzing DNA primer extension reaction.

The mutant T7 RNA polymerase (T7 RNAP), containing two substitutions (Y639F, S641A) was earlier shown to utilize both rNTP and dNTP in a transcription-like reaction. In this report the ability of the enzyme to catalyze DNA primer extension reaction was demonstrated. The efficiency of the reaction essentially depended on the type of the primer sequence, and was significantly higher if the primer coincided with the T7 promoter non-coding sequence. In this case the primer extension reaction proceeded along with de novo RNA synthesis. The length of the product did not exceed 8 nucleotides, indicating that the primer extension reaction proceeds according to the mechanism of the T7 RNAP-catalyzed abortive transcription.

Mutants of T7 RNA polymerase that are able to synthesize both RNA and DNA.

A mutant T7 RNA polymerase (T7 RNAP) having two amino-acid substitutions (Y639F and S641A) is altered in its specificity towards nucleotide substrates, but is not affected in the specificity of its interaction with promoter and terminator sequences. The mutant enzyme gains the ability to utilize dNTPs and catalyze RNA and DNA synthesis from circular supercoiled plasmid DNA. DNA synthesis can also be initiated from a single stranded template using a DNA primer. Another T7 RNAP mutant having only the single substitution S641A loses RNA polymerase activity but is able to synthesize DNA.

Mapping of T7 RNA polymerase active site with novel reagents--oligonucleotides with reactive dialdehyde groups.

Oligonucleotides of a novel type containing 2'-O-beta-ribofuranosyl-cytidine were synthesized and further oxidized to yield T7 consensus promoters with dialdehyde groups. Both types of oligonucleotides were tested as templates, inhibitors, and affinity reagents for T7 RNA polymerase and its mutants. All oligonucleotides tested retained high affinity towards the enzyme. Wild-type T7 RNA polymerase and most of the mutants did not react irreversibly with oxidized oligonucleotides. Affinity labeling was observed only with the promoter-containing dialdehyde group in position (+2) of the coding chain and one of the mutants tested, namely Y639K. These results allowed us to propose the close proximity of residue 639 and the initiation region of the promoter within initiation complex. We suggest the oligonucleotides so modified may be of general value for the study of protein-nucleic acid interactions.

Regulation of 2-5 A phosphodiesterase activity by cAMP-dependent phosphorylation: mechanism and biological role.

The results of the present study permit the explanation of one of the mechanisms of the interconnection between the regulatory systems of cAMP and 2-5A. cAMP-dependent regulation of 2'-PDE was found to involve phosphorylation of the specific protein inhibitor. Originally, a similar way of regulation of the enzyme activity was discovered for protein phosphatase I. This enzyme has a specific protein inhibitor type 1, which is phosphorylated by cAMP-dependent protein kinase and is activated by phosphorylation (18). It is interesting that the molecular weights of 2'-PDE protein inhibitor and of the inhibitor type 1 of protein phosphatase I are essentially the same. There is also a certain similarity between the above described mechanism and phosphorylation of the regulatory subunit of cAMP-dependent protein kinase type 2. The regulatory subunit can also act as a protein inhibitor of the enzyme and change its properties as a result of phosphorylation (19). The results obtained permit as well a more detailed explanation for cAMP-dependent inhibition of cell proliferation. Evidently, cAMP elevation causes activation of cAMP-dependent phosphorylation which, in turn, leads to the induction of 2-5A synthetase and inhibition of 2'-PDE. As a result of variations in the activities of these enzymes, the level of 2-5A rises. The latter brings about the changes characteristic of the resting state. They involve activation of RNase L and the succeeding acceleration of RNA hydrolysis, inhibition of protein synthesis and cell proliferation. The resting state is characterized by a rapid turnover of macromolecules due to their intensive degradation (20). The above described scheme suggested that the rapid turnover of RNA during inhibition of cell proliferation can be partially accounted for by activation of 2-5A-dependent RNase L. Thus, it can be thought that at least one of the mechanisms of the antiproliferative effect of cAMP-dependent phosphorylation of proteins involves cAMP-dependent elevation of intracellular 2-5A. Evidently, a number of properties of the resting cells are determined by the elevated content of 2-5A. Finally, it should be noted that the interconnection between the systems of cAMP and 2-5A is a multiple process. We have earlier demonstrated (12) that 2-5A activates cAMP phosphodiesterase in NIH 3T3 cell homogenates. These data suggest that the mutual regulation of cAMP and 2-5A levels involves the negative feedback mechanism (Fig. 8).

Inhibition of DNA gyrase by levofloxacin and related fluorine-containing heterocyclic compounds.

Fluoroquinolones are an important class of modern and efficient antibacterial drugs with a broad spectrum of activity. Levofloxacin (the optically active form of ofloxacin) is one of the most promising fluoroquinolone drugs, and its antibacterial activity is substantially higher than the activity of other drugs of the fluoroquinolone family. Earlier, in the Postovsky Institute of Organic Synthesis, UB RAS, an original method of levofloxacin synthesis was developed, and now the pilot batch of the drug is being prepared. Bacterial DNA gyrase is a specific target of fluoroquinolones; hence, the study of the enzyme-drug interaction is of theoretical and practical importance. Moreover, the parameters of DNA gyrase inhibition may serve as a criterion for drug quality. Here, we present the results of studying the interaction of DNA gyrase with a number of fluoroquinolones and their analogs: intermediates and semi-products of the levofloxacin synthesis, and also samples from the pilot batches of this drug. The importance of two structural elements of the levofloxacin molecule for the efficiency of the inhibition is revealed. The data obtained may be useful for the design of new drugs derived from levofloxacin.

Base-modified ribonucleosides as potential anti-hepatitis C virus agents.

Four novel series of base modified ribonucleoside analogues were synthesized and evaluated as potential anti-HCV agents. For two compounds notable anti-HCV activity was observed The triphosphates of bicyclic pyrimidine ribonucleosides were studied as substrates/inhibitors of HCV RNA-dependent RNA polymerase (RdRp, NS5B protein) and RNA helicase/NTPase (NS3 protein).

Hepatitis C virus helicase/NTPase: an efficient expression system and new inhibitors.

A method has been developed for obtaining a full-length protein NS3 of hepatitis C virus with the yield of 6.5 mg/liter of cell culture, and conditions for measuring its NTPase and helicase activities have been optimized. The helicase reaction can proceed in two modes depending on the enzyme and substrate concentration ratio: it can be non-catalytic in the case of enzyme excess and catalytic in the case of tenfold substrate excess. In the latter case, helicase activity is coupled with NTPase and is stimulated by ATP. A number of NTP and inorganic pyrophosphate analogs were studied as substrates and/or inhibitors of NS3 NTPase activity, and it was found that the structure of nucleic base and ribose fragment of NTP molecule has a slight effect on its inhibitory (substrate) properties. Among the nucleotide derivatives, the most efficient inhibitor of NTPase activity is 2 -deoxythymidine 5 -phosphoryl-beta,gamma-hypophosphate, and among pyrophosphate analogs imidodiphosphate exhibited maximal inhibitory activity. These compounds were studied as inhibitors of the helicase reaction, and it was shown that imidodiphosphate efficiently inhibited the ATP-dependent helicase reaction and had almost no effect on the ATP-independent duplex unwinding. However, the inhibitory effect of 2 -deoxythymidine 5 -phosphoryl-beta,gamma-hypophosphate was insignificant in both cases, which is due to the possibility of helicase activation by this ATP analog.

Hepatitis C virus RNA-dependent RNA polymerase: study on the inhibition mechanism by pyrogallol derivatives.

Pyrogallol reversibly and noncompetitively inhibits the activity of the hepatitis C RNA-dependent RNA polymerase. Based on molecular modeling of the inhibitor binding in the active site of the enzyme, the inhibition was suggested to be realized via chelation of two magnesium cations involved in the catalysis at the stage of the phosphoryl residue transfer. The proposed model allowed us to purposefully synthesize new derivatives with higher inhibitory capacity.

Structural-functional analysis of bacteriophage T7 RNA polymerase.

This review summarizes our results of the structural and functional studies of bacteriophage T7 DNA-dependent RNA polymerase (T7 RNAP). Particular features of this enzyme (the single-subunit composition, relatively low molecular weight) make it the most convenient model for investigating the physicochemical aspects of transcription. The review discusses the main properties of T7 RNAP, interaction between the enzyme and promoter, principle stages of T7-transcription, and also the results of structural and functional studies by affinity modification and both random and site-directed mutagenesis techniques.

T7 RNA polymerase: use of limited proteolysis for the study of enzyme's interaction with substrates and inhibitors.

The specific limited trypsinolysis of bacteriophage T7 RNA polymerase (T7RP) was performed in the presence of various components of the polymerase reaction and some GTP-analogs--irreversible inhibitors of the enzyme. The differences in the rate and sites of proteolysis were observed. Basing on the data obtained the role of the N-terminal domain of the T7RP in the interaction with promoter-containing template is proposed.