Accuracy of wheat-germ RNA polymerase II. General enzymatic properties and effect of template conformational transition from right-handed B-DNA to left-handed Z-DNA.

We investigated the accuracy of the insertion process in RNA chain elongation catalyzed by wheat germ RNA polymerase II. Error frequencies varied from 1 misinserted nucleotide per 250 polymerized correct substrates to less than 1 in 2 x 10(5), depending on template sequence and nature of the divalent metal cofactor. Higher error ratios were observed in the presence of Mn2+ compared to Mg2+, and with alternating poly[d(G-C)].poly[d(G-C)] compared to poly[d(A-T)].poly[d(A-T)]. In this latter case the eukaryotic RNA polymerase was as accurate as Escherichia coli RNA polymerase holo-enzyme. The fidelity of wheat germ RNA polymerase II was also examined in transcription of polynucleotide templates in the poly[d(G-C)] family adopting either the right-handed B or left-handed Z conformations. Error ratios for noncomplementary ATP increased markedly under experimental conditions favoring the B-to-Z conformational transition of the alternating copolymers. In accordance with the results of previous studies, the rate of productive elongation, i.e. the synthesis of poly[r(G-C)], was depressed, suggesting that the decreased accuracy of the enzyme derived from an altered competence of the enzyme to form elongation complexes on the left-handed DNA. As judged by the large difference in apparent Km values of the enzyme for complementary and noncomplementary nucleoside triphosphates, part of the discrimination between substrates seemed to take place at the initial binding step. Furthermore, the results indicate that wheat germ RNA polymerase II was able to elongate a primer with a 3'-terminal mismatch, and thus to incorporate the mismatched nucleotide stably in the nascent RAN. However, the probability of productive RNA chain elongation was much lower with noncognate than with the complementary substrates.

Transcription of synthetic DNA containing sequences with dyad symmetry by wheat-germ RNA polymerase II. Increased rates of product release in single-step addition reactions.

Interaction of purified eukaryotic RNA polymerase II with various synthetic palindromic DNA sequences is associated with the formation of transcriptional complexes of different stabilities, i.e. having different propensities for releasing the nascent transcript. This phenomenon was observed by using wheat-germ RNA polymerase II and a series of double-stranded template polymers containing palindromic repeating motifs of 6-16 bp, with regulatory alternating purine and pyrimidine bases such as d[ATA(CG)nC].d[TAT(GC)nG], with n = 1, 3 or 6 referred to as d(GC), d(GC)3 or d(GC)6, respectively. We also synthesized two double-stranded methylated polymers, containing the repeating units d(ATAm5CGm5C).d(TATGm5CG) and d[ATA(m5CG)6m5C].d[TAT(Gm5C)6G] [designated d(GmC) and d(GmC)6, respectively]. All of these polymers served as templates for the reaction of single-step addition of CTP to a CpG primer catalysed by wheat-germ RNA polymerase II, to an extent that seems well correlated with the number of potential initiation sites within the DNA molecules. Furthermore, in these reactions, the enzyme appears to form relatively stable transcriptional complexes, as trinucleotide product was released only very slowly. In marked contrast to the results with the CpG primer, the single-step addition reaction primed by UpA, i.e. the synthesis of UpApU proceeded at a much higher velocity and was strongly enhanced by increasing the d(G-C) content of the repeating units of the DNA polymers. Thus, taking into account the number of potential sites at which UpApU synthesis could occur, the extent of UpApU synthesis was increased about 12-fold with d(GC)6 compared to that with the d(GC) template. The catalytic nature of the reaction necessarily implies that the stability of the transcription complexes with the plant RNA polymerase II decreased as the d(G-C) content of the repeating motif increased. Furthermore, although the synthesis of CpGpC could be demonstrated with d(GmC)6 as template, the UpA-primed synthesis of UpApU could not be detected with this polymer. The results obtained in transcription of these polymers are discussed in relation to the potential involvement of palindromic DNA in transcription termination and attenuation in the presence of RNA polymerase II.

Abortive intermediates in transcription by wheat-germ RNA polymerase II. Dynamic aspects of enzyme/template interactions in selection of the enzyme synthetic mode.

At constant enzyme concentration and with the full set of nucleotide substrates dictated by template sequence, the chain-length distribution of polymeric product varies with template concentration in reactions catalysed by wheat-germ RNA polymerase II. Under the same conditions, but in the presence of a single ribonucleoside triphosphate, the rate of condensation of the triphosphate substrate to a dinucleotide primer also exhibits a complex dependence with the template concentration. This effect is observed using poly[d(A-T)] as a template. For both reactions there are two extreme types of behaviour in each of which transcription appears to involve a single enzyme synthetic mode, characterized by either a high (at low template concentration) or a low (at high template concentration) probability of releasing the transcripts. A strong correlation is found between these two pathways, such that conditions favouring the abortive release of trinucleotide products in the single-step addition reaction are associated with the synthesis of short-length RNA species in productive elongation, and reciprocally. A model previously developed by Papanicolaou, Lecomte & Ninio [(1986) J. Mol. Biol. 189, 435-448] to account for the kinetics of polymerization/excision ratios with Escherichia coli DNA polymerase I, and by Job, Soulié, Job & Shire [(1988) J. Theor. Biol. 134, 273-289] for kinetics of RNA-chain elongation by wheat-germ RNA polymerase II provides an explanation for the observed behaviour with the plant transcriptase. The basic requirement of this model is a slow equilibrium between two states of the polymerization complex with distinct probabilities of releasing the product. In the presence of Mn2+, and under conditions allowing the synthesis of poly[r(A-U)], one of these states is involved in the formation of oligonucleotides shorter than 15 bases, whereas the other catalyses the polymerization of chains longer than 40 bases.

Effect of Sarkosyl and heparin on single-step addition reactions catalysed by wheat-germ RNA polymerase II--poly[d(A-T)]transcription complexes.

Incubation of purified wheat-germ RNA polymerase II with poly[d(A-T)] template, Mn2+, U-A dinucleoside monophosphate primer and UTP substrate resulted in catalytic formation of the trinucleoside diphosphate U-A-U, in accordance with the results of previous studies. Both Sarkosyl and heparin inhibited completely and immediately (within less than 1 min) U-A-U synthesis, if either of these compounds was added to the assays during the progress of the reaction. This behaviour is in marked contrast to that reported for single-step addition reactions catalysed by Escherichia coli RNA polymerase on the same template [Sylvester & Cashel (1980) Biochemistry 19, 1069-1074]. However, treatment of the transcription complexes with Sarkosyl or heparin for periods sufficient to abolish U-A-U formation completely did not suppress completely the ability of such complexes to elongate RNA chains. Hence, the effect of Sarkosyl or heparin on the rate of U-A-U synthesis was predominantly due to change in the rate (or in the mechanism) of trinucleotide product release by the transcription complexes. Furthermore, once U-A-U synthesis has begun on the poly[d(A-T)] template, the transcription complexes became resistant to the action of a competitor DNA such as poly[d(G-C)]. The results are consistent with a model where at least a sizeable fraction of the enzyme molecules remains associated with the DNA template upon formation of a single phosphodiester bond.

Studies on the inhibition by alpha-amanitin of single-step addition reactions and productive RNA synthesis catalysed by wheat-germ RNA polymerase II.

The rate of formation of a single phosphodiester bond with UTP substrate, U-A primer, poly[d(A-T)] template and wheat-germ RNA polymerase II is greatly depressed in the presence of alpha-amanitin. Half-maximal inhibition occurs at 0.04 microgram/ml, in close agreement with published values for inhibition of productive RNA synthesis with class II RNA polymerases from higher-plant species. However, a sizeable proportion of U-A-U synthesis is resistant to inhibition by excess alpha-amanitin. In the additional presence of ATP, i.e. under experimental conditions permitting RNA chain elongation, the synthesis of poly[r(A-U)] is arrested after the formation of the first phosphodiester bond. The results support the contention that the main enzymic process disrupted by alpha-amanitin is the translocation step of the transcription complex along the DNA template.

A slow kinetic transient in RNA synthesis catalysed by wheat-germ RNA polymerase II.

Progress curves of U-A-primed RNA synthesis catalysed by wheat-germ RNA polymerase II on a poly[d(A-T)] template exhibit a slow burst of activity. In contrast, the progress curves of single-step addition of UMP to U-A primer in the abortive elongation reaction do not exhibit the slow burst of activity. The correlation between the kinetic transient in the productive pathway of RNA synthesis and the rate of abortive elongation is suggestive of the occurrence of a slow conformational change of the transcription complex during the transition from abortive to productive elongation. The exceptional duration of the transient burst (in the region of 4 min) may suggest a transition of a hysteretic type.