The properties of ATP-analogs in initiation of RNA synthesis catalyzed by RNA polymerase from E coli.

Various base and sugar modified derivatives of ATP and UTP were used as substrate analogs for the steady state initiation reaction ATP+UTP=pppApU and the single step addition reaction ApC+ATP=ApCpA. These reactions were carried out by E. coli RNA polymerase on T7 DNA in the presence of rifampicin. The steady state kinetic parameters of the analogs, either as substrates or inhibitors, were determined. On the basis of the obtained results it is concluded that purine NTP s in initiation require anti-conformation about the glycosidic bonds as well as gauche-gauche conformation of the C(4')-C(5') bonds. The latter conformation is also a prerequisite for substrates in elongation, whereas strict anti-conformation of glycosidic bonds is not.     

The effect of low substrate concentrations on the extent of productive RNA chain initiation from T7 promoters A1 and A2 by Escherichia coli RNA polymerase

The extent of productive RNA chain initiation in vitro by Escherichia coli RNA polymerase holoenzyme from the bacteriophage T7 A1 and A2 promoters on purified T7 DNA templates has been investigated at very low concentrations of the ribonucleoside triphosphate substrates. As the concentration of ribonucleoside triphosphates in the reaction is decreased from 10 to 1 micro M, the extent of productive RNA chain initiation at these promoter sites drops precipitously at about 3 micro M. At 1 micro M substrate concentration, productive chain initiation from the A1 promoter does not occur even after extended incubation although the dinucleoside tetraphosphate pppApU is produced at a significant rate under these conditions. The reason for the inability of RNA polymerase to carry out productive RNA chain initiation at 1 micro M substrate concentration is not yet understood. The phenomenon is not due to substrate consumption, enzyme inactivation, or a requirement for a nucleoside triphosphatase activity in the reaction. The possibility is raised that there are additional nucleoside triphosphate binding sites on E. coli RNA polymerase which play some role in the process of productive RNA chain initiation.     

Competition of rifampicin with binding of substrate and RNA to RNA polymerase

The rate of formation of dinucleoside tetraphosphate, pppApU, from ATP and UTP by RNA polymerase on the A1 promoter of the mutant D111 of bacteriophage T7 is distinctly and specifically reduced not only by the third template-directed nucleotide, CTP, but also by CMP. The inhibitory effect of CMP is not changed when the enzyme contains prebound rifampicin. The synthesis of pppApU is also strongly reduced after preincubation of the enzyme with RNA. This inhibitory effect of RNA is, however, distinctly diminished by rifampicin bound to the enzyme prior to the addition of RNA. On the other hand RNA can suppress the specific binding of the antibiotic to the RNA polymerase subassembly alpha 2 beta.     

Kinetics of DNA-dependent RNA synthesis: coupled synthesis of di- and trinucleotides in the presence of a minimum complement of substrate

The qualitative and quantitative characteristics of the synthesis of the short oligonucleotides by Escherichia coli RNA polymerase on A1 promoter of the bacteriophage T7 deletion mutant delta D111 DNA in the presence of the incomplete set of nucleoside triphosphates were studied. It was shown, that in conformity with the structure of A1 promoter the oligonucleotides pppApU, pppApUpC were synthesized in the presence of ATP, UTP, CTP; the oligonucleotides pApU, pApUpC-in the presence of AMP, UTP, CTP and oligonucleotides pApU, pApUpC, pApUpCpG-in the presence of AMP, UTP, CTP, GTP. The curves of di- and trinucleotide syntheses as the functions of the substrate concentrations were obtained. The analytical formulas for the rates of the coupled synthesis were derived from these curves. A kinetic scheme that is in conformity with the experimental data was proposed. This scheme includes the stage of the reversible, random and release of di- and trinucleotides from the enzyme-template complex.     

Kinetics of inhibition by 8-oxy-GTP and 8-bromo-GTP of Escherichia coli RNA-polymerase synthesis of pppApU dinucleotide on the promotor a1 of phage T7deltaD111 DNA in a limited set of substrates

Detailed analysis of the kinetics of inhibition of E. coli RNA-polymerase-catalyzed synthesis of dinucleotide pppApU by 8-oxy-GTP and 8-Br-GTP on promoter A1 of the bacteriophage T7 delta D111 with an incomplete set of substrates was carried out. In accordance with the mathematical models obtained, we calculated quantitative parameters of binding of these nucleotide analogs to the centers whose geometry is suitable for incorporation of ATP and UTP. 8-oxy-GTP and 8-Br-GTP compete with ATP for the binding center (their steady-state dissociation constant ratios are 2.1 and 2.4, respectively, whereas the constant for ATP is 0.3 mM) but, unlike ATP, they are not incorporated into the product. 8-oxy-GTP competes also with UTP (its steady-state dissociation constant ratio is 21.6, the constant for UTP is 0.03 mM). 8-Br-GTP does not interact with the binding center of UTP.     

On the mechanism of rifampicin inhibition of RNA synthesis.

The mechanism of rifampicin inhibition of Escherichia coli RNA polymerase was studied with a newly developed steady state assay for RNA chain initiation and by analysis of the products formed with several 5'-terminal nucleotides. The major effect of rifampicin was found to be a total block of the translocation step that would ordinarily follow formation of the first phosphodiester bond. These effects were incorporated into a steric model for rifampicin inhibition. Additional minor effects of the enzyme bound inhibitor were to increase slightly the lifetime of RNA polymerase on the lambdaPR' promoter and to increase by two the apparent Michaelis constants of the initiating triphosphates. The products formed by RNA polymerase in the presence of rifampicin belong nearly exclusively to the class pppPupN. No evidence for the accumulation of such molecules was obtained in vivo.     

Mechanism of ribonucleic acid chain initiation. 1. A non-steady-state study of ribonucleic acid synthesis without enzyme turnover

A non-steady-state kinetic method has been developed to observe the initiation of long RNA chains by Escherichia coli RNA polymerase without the enzyme turnover. This method was used to determine the order of binding of the first two nucleotides to the enzyme in RNA synthesis with the first two nucleotides to the enzyme in RNA synthesis with poly(dA-dT) as the template. It was shown that initiator [ATP, uridyly(3'-5')adenosine, or adenyly(3'-5')uridylyl-(3'-5')adenosine] binds first to the enzyme-template complex, followed by UTP binding. The concentration dependence of UTP incorporation into the initiation complex suggests that more than one UTP molecule may bind to the enzyme-DNA complex during the initiation process. Comparison of the kinetic parameters derived from these studies with those obtained under steady-state conditions indicates that the steps involving binding of initiator or UTP during initiation cannot be rate limiting in the poly(dA-dT)-directed RNA synthesis. The non-steady-state technique also provides a method for active-site titration of RNA polymerase. The results show that only 36 +/- 9% of the enzyme molecules are active in a RNA polymerase preparation of high purity and specific activity. In addition, the minimal length of poly(dA-dT) involved in RNA synthesis by one RNA polymerase molecule was estimated to be approximately 500 base pairs.     

Kinetics of inhibition by 8-oxy-ATP of the dinucleotide pppApU synthesis catalyzed by Escherichia coli RNA-polymerase on the promoter A1 of phage T7 delta D111 DNA during coupled synthesis of di- and trinucleotides and a limited set of substrates

A kinetic analysis of inhibition of synthesis of dinucleotide pppApU catalyzed by Escherichia coli RNA-polymerase on A1 promoter of the DNA from T7 delta DIII phage mutant by 8-oxy-ATP under the conditions of the coupled synthesis of pppApU and pppApUpC and in the presence of an incomplete set of substrates, namely ATP, UTP, CTP, has been performed. It was found that 8-oxy-ATP is an unproductive analog of both ATP and CTP. A comparative analysis of the dissociation constants shows that 8-oxy-ATP binds at ATP center 3.3. times and at CTP center 540 times weaker than natural substrates. At the UTP center 8-oxy-ATP does not bind at all.     

The role of ATP in the transport of rapidly-labeled RNA from isolated nuclei of rat liver in vitro.

To understand the mechanism of the action of ATP on the in vitro transport of the rapidly-labeled RNA from isolated nuclei, the fate of ATP during the incubation as well as the effect of ATP, its analogues and other ribonucleoside triphosphates on the transport was examined and the following results were obtained. (1) More than 97% of added ATP remained acid soluble. No polyadenylation of the rapidly-labeled RNA in the released fraction by added ATP occurred although new polyadenylate segments smaller than 10 S were synthesized. (2) The addition of an ATP-generating system to the reaction mixture restored the initial rate of the release of the rapidly-labeled RNA from isolated nuclei. (3) Among the ribonucleoside triphosphates tested, ATP was most effective in stimulating the release. GTP was about 2/3 as effective as ATP. UTP showed some effect, but CTP showed no effect. EDTA was also non-effective. (4) When no ATP-generating system was added to the reaction mixture, AMP failed to mimic the effect of ATP. However, the combination of AMP and pyrophosphate could take the place of ATP. (5) Both AMP-CPP and AMP-PCP, the ATP analogues, showed the equal degree of their effect on the release, regardless of the position of the methylene bond. From these results, the principal role of ATP in the in vitro transport systems seemed to be its interaction with isolated nuclei to dissociate a structure which retains the rapidly-labeled RNA in the nucleus.     

Mechanistic studies on deoxyribonucleic acid dependent ribonucleic acid polymerase from Escherichia coli using phosphorothioate analogues. 1. Initiation and pyrophosphate exchange reactions.

The diastereomers of adenosine 5'-O-(1-thiotriphosphate) (ATP alpha S) and adenosine 5'-O-(2-thiotriphosphate) (ATP beta S) can replace adenosine triphosphate (ATP) in the initiation reaction catalyzed by deoxyribonucleic acid (DNA) dependent ribonucleic acid (RNA) polymerase from Escherichia coli. In both cases, the Sp diastereomer is a better initiator than the Rp isomer. The diasteromers of 3'-uridyl 5'-adenosyl ,O-phosphorothioate [Up(S)A] can replace UpA in the primed initiation reaction catalyzed by RNA polymerase; however, the Rp diastereomer is a better initiator than the Sp isomer. By using ATP or CpA as initiator and UTP alpha S, isomer A, as substrate, we determined the stereochemical courses of both the initiation and primed initiation reactions, respectively, with T7 DNA template and found them to proceed with inversion of configuration. Determination of the stereochemical course of the pyrophosphate exchange reaction catalyzed by RNA polymerase provides evidence that this reaction is the reverse of the phosphodiester bond-forming reaction.