Replication of RNA viruses: analysis by liquid polymer phase partition of the binding of Q RNA polymerase to nucleic acid

The number of RNA sites bound by the Qβ RNA polymerase and the affinity of the enzyme for different RNA sites was measured by equilibrium partition of enzyme and enzyme-nucleic acid complexes between two liquid polymer phases. At 0 °C and in the absence of other components required for RNA synthesis the enzyme bound to many regions of Qβ RNA, f2 RNA, 16S rRNA, double-stranded RNA, and circular DNA. Under conditions of enzyme excess, the maximum numbers of enzyme molecules bound per molecule of Qβ RNA, f2 RNA, and 16S rRNA were 32, 26, and 12, respectively. The enzyme bound to most, if not all, of the Qβ RNA sites with the same affinity. Nevertheless, the association constant for enzyme binding to Qβ RNA was more than 10-fold greater than for binding to f2 RNA over a wide range of salt concentrations.     

Interactions of Q beta replicase with Q beta RNA

The interactions of Qβ replicase with Qβ RNA were investigated by treating replicase-Qβ RNA complexes under various conditions with ribonuclease T₁, and by characterizing enzyme-bound RNA fragments recovered by a filter binding technique. Evidence for replicase binding at two internal regions of Qβ RNA was obtained. One region (at about 1250 to 1350 nucleotides from the 5′ end) overlaps with the initiation site for coat protein synthesis; this interaction is thought to be inessential for template activity but rather to be involved in the regulation of protein synthesis. Binding to this site (called the S-site) requires moderate concentrations of salt but no magnesium ions. The other region (at about 2550 to 2870 nucleotides from the 5′ end) is probably essential for template activity; binding to this site (called the M-site) is dependent on the presence of magnesium ions. The nucleotide sequences of the RNA fragments from the two sites were determined and found to have no common features. Under the conditions tested, replicase binding at the 3′ end of Qβ RNA could not be demonstrated, except when initiation of RNA synthesis was allowed to occur in the presence of GTP and host factor. If instead of intact Qβ RNA, a complete RNAase T₁ digest of Qβ RNA was allowed to bind to replicase, oligonucleotides from the S-site and the M-site, and oligonucleotides from a region close to the 3′ end, were found to have the highest affinity to the enzyme.The RNA fragments recovered in highest yield, M-2 and S-3 from the M and S-site, respectively, were isolated on a preparative scale and their enzyme binding properties were studied. In competition assays with random RNA fragments of the same size, selective binding was observed both for the M and the S-site fragment. Partial competition for replicase binding was found if M-2 and S-3 were presented simultaneously to the enzyme. Either fragment, if preincubated with replicase, caused a specific inhibition of initiation of Qβ RNA-directed RNA synthesis, without inhibiting the poly(rC)-directed reaction.The results are discussed in terms of a model of replicase-Qβ RNA recognition. Template specificity is attributed to binding of internal RNA regions to replicase, resulting in a specific spatial orientation of the RNA by which the inherently weak, but essential, interaction at the 3′ end is allowed to occur and to lead to the initiation of RNA synthesis.     

Function of bacteriophage Qbeta replicase containing an altered subunit IV

In order to elucidate the function of elongation factor Ts in Qβ replicase, enzyme was obtained from a Qβ-infected Escherichia coli mutant HAK88, which carries an altered EFTs² with a thermolabile catalytic activity. HAK88 Qβ replicase was found to be quite unstable at 42 °C. Further studies indicated that the mutant enzyme exhibits temperature sensitivity with regard to GTP binding ability but not with Qβ RNA and poly(C) binding. These results suggest that the function of EFTs in Qβ replicase is closely related to the binding of GTP to the enzyme.A defect in Qβ replicase also appears when it is reconstituted from the Qβ replicase subunit complex I–II and the HAK88 EFTu-EFTs complex. Several lines of evidence obtained by using the reconstituted enzyme suggest strongly that the EFTs function is involved specifically in initiation of RNA synthesis, but not in the elongation reaction.     

Site-directed mutagenesis: Generation of an extracistronic mutation in bacteriophage Qβ RNA

The preparation in vitro and chemical characterization of bacteriophage Qβ RNA with an extracistronic mutation, a G → A transition in the 16th position from the 3′-terminus, is described. The 5′-terminal region of the Qβ minus strand was synthesized in vitro up to position 14 (inclusive) by using ATP and GTP as the only substrates. The mutagenic nucleotide analog N⁴-hydroxyCMP was then incorporated into position 15 instead of CMP. The minus strand was completed with the four standard ribonucleoside triphosphates, purified and used as a template for the synthesis of plus strands. Of the plus strand product, 33% had a G → A transition in the 16th position from the 3′-end (which corresponds to position 15 of the minus strand), as shown by nucleotide sequence analysis of the terminal T₁ oligonucleotide. The modified RNA was efficiently replicated by Qβ replicase and a preparation containing 55% of the mutant RNA was obtained.The general approach to directed mutagenesis outlined above should allow the introduction of mutations into the 5′ and 3′-terminal regions of Qβ RNA as well as into the intercistronic sequences.     

Replication of RNA viruses: structure of a 6 s RNA synthesized by the Q RNA polymerase

The in vitro synthesis of RNA catalyzed by the Qβ RNA polymerase has been studied using a single-stranded 6 s RNA template. Whereas Qβ RNA replication results in the synthesis predominantly of single-stranded Qβ RNA, the predominant reaction product of 6 s RNA replication was found to be double stranded. When treated with formaldehyde to dissociate complementary base pairs, 6 s RNA exhibited a decrease in molecular weight as indicated by its slower sedimentation rate and faster electrophoretic mobility. 6 s RNA also exhibited a hyperchromic thermal transition indicative of double-stranded RNA and differing markedly from that of single-stranded RNA. The T_m of this transition increased linearly with the logarithm of ionic strength. Renaturation of 6 s RNA below the T_m occurred slowly and was also dependent upon ionic strength.     

Functional circularity of legitimate Qbeta replicase templates

Qβ replicase (RNA-directed RNA polymerase of bacteriophage Qβ) exponentially amplifies certain RNAs in vitro. Previous studies have shown that Qβ replicase can initiate and elongate on a variety of RNAs; however, only a minute fraction of them are recognized as ‘legitimate’ templates. Guanosine 5′-triphosphate (GTP)-dependent initiation on a legitimate template generates a stable replicative complex capable of elongation in the presence of aurintricarboxylic acid, a powerful inhibitor of RNA-protein interactions. On the contrary, initiation on an illegitimate template is GTP independent and does not result in the aurintricarboxylic-acid-resistant replicative complex. This article demonstrates that the 3′ and 5′ termini of a legitimate template cooperate during and after the initiation step. Breach of the cooperation by dividing the template into fragments or by introducing point mutations at the 5′ terminus reduces the rate and the yield of initiation, increases the GTP requirement, decreases the overall rate of template copying, and destabilizes the postinitiation replicative complex. These results revive the old idea of a functional circularity of legitimate Qβ replicase templates and complement the increasing body of evidence that functional circularity may be a common property of RNA templates directing the synthesis of either RNA or protein molecules.     

Sub-nuclear fractionation. II. Intranuclear compartmentation of transcription in vivo and in vitro

DNA-dependent RNA polymerase activities were measured in subnuclear fractions obtained from rat liver by the procedure described in the preceding paper [14]. Most of the total nuclear enzyme was recovered in a form bound to chromatin with only small amounts as free enzyme in the nucleoplasm. The multiple eukaryotic RNA polymerases were resolved according to the endogenous template to which they were bound and which they continue to transcribe in vitro. The A and B forms of the enzyme were distinguished from each other by their differential sensitivities to α-amanitin, exogenous native and denatured DNA, thermal denaturation at 45 °, Mg²⁺ and Mn² ions, high ionic strength and by the binding of ${}^{14}\text{C-methyl}\text{-γ-}\text{amanitin}$. RNA polymerase B (α-amanitin-sensitive) was exclusively recovered in the nucleoplasmic and euchromatin fractions. RNA polymerase A was recovered in the dispersed nucleolar as well as in heterochromatin. By assaying in the presence of α-amanitin subnuclear fractions that had been pre-incubated at 45 °C a third enzyme (form C) was located exclusively in heterochromatin fractions. Only the euchromatin associated RNA polymerase B was capable of initiating the synthesis of new RNA chains in vitro on endogenous template at low ionic strength. Raising the ionic strength abolished initiation but accelerated chain elongation by this form of enzyme.When nuclear RNA was labelled in vivo, newly made RNA turned over rapidly in the nucleoplasm but accumulated in the euchromatin + membrane fraction. RNA in the nucleolar fraction accumulated gradually after a lag period, whereas a significant amount of rapidly-labelled nuclear RNA was recovered in the heterochromatin fractions. The distribution of RNA labelled in vivo compared with that of RNA polymerase activities suggested that RNA synthesized in vivo is rapidly translocated from its site of synthesis to some other sites within the nucleus.     

Control of template positioning during de novo initiation of RNA synthesis by the bovine viral diarrhea virus NS5B polymerase

The RNA-dependent RNA polymerase of the hepatitis C virus and the bovine viral diarrhea virus(BVDV)is able to initiate RNA synthesis denovo in the absence of a primer. Previous crystallographic data have pointed to the existence of a GTP-specific binding site (G-site) that is located in the vicinity of the active site of the BVDV enzyme. Here we have studied the functional role of the G-site and present evidence to show that specific GTP binding affects the positioning of the template during de novo initiation. Following the formation of the first phosphodiester bond, the polymerase translocates relative to the newly synthesized dinucleotide, which brings the 5'-end of the primer into the G-site, releasing the previously bound GTP. At this stage, the 3'-end of the template can remain opposite to the 5'-end of the primer or be repositioned to its original location before RNA synthesis proceeds. We show that the template can freely move between the two locations, and both complexes can isomerize to equilibrium. These data suggest that the bound GTP can stabilize the interaction between the 3'-end of the template and the priming nucleotide, preventing the template to overshoot and extend beyond the active site during de novo initiation. The hepatitis C virus enzyme utilizes a dinucleotide primer exclusively from the blunt end; the existence of a functionally equivalent G-site is therefore uncertain. For the BVDV polymerase we showed that de novo initiation is severely compromised by the T320A mutant that likely affects hydrogen bonding between the G-site and the guanine base. Dinucleotide-primed reactions are not influenced by this mutation, which supports the notion that the G-site is located in close proximity but not at the active site of the enzyme.     

Recombinant viral RdRps can initiate RNA synthesis from circular templates

The crystal structure of the recombinant hepatitis C virus (HCV) RNA-dependent RNA polymerase (RdRp) revealed extensive interactions between the fingers and the thumb subdomains, resulting in a closed conformation with an established template channel that should specifically accept single-stranded templates. We made circularized RNA templates and found that they were efficiently used by the HCV RdRp to synthesize product RNAs that are significantly longer than the template, suggesting that RdRp could exist in an open conformation prior to template binding. RNA synthesis using circular RNA templates had properties similar to those previously documented for linear RNA, including a need for higher GTP concentration for initiation, usage of GTP analogs, sensitivity to salt, and involvement of active-site residues for product formation. Some products were resistant to challenge with the template competitor heparin, indicating that the elongation complexes remain bound to template and are competent for RNA synthesis. Other products were not elongated in the presence of heparin, indicating that the elongation complex was terminated. Lastly, recombinant RdRps from two other flaviviruses and from the Pseudomonas phage phi6 also could use circular RNA templates for RNA-dependent RNA synthesis, although the phi6 RdRp could only use circular RNAs made from the 3'-terminal sequence of the phi6 genome.     

Histone or Bacterial Basic Protein required for Replication of Bacteriophage RNA

IN spite of the apparent simplicity of RNA bacteriophage, several proteins, both phage and bacterial, are required for the synthesis of Qβ RNA in vitro. The polymerase complex alone contains one phage-coded and three host proteins^1,2. The specific role of these proteins in Qβ RNA replication is unknown, but because they demonstrate an associative interaction and are always found with active enzyme, it has been suggested that all four contribute to polymerase activity¹.     

A mutant of Escherichia coli blocked in peptide elongation: altered elongation factor Ts

Among our transfer RNA-dependent growth mutants, one, HAK88, was found that carries an altered elongation factor Ts. The activity of mutant EFTs to bind GDP to EFTu, or to form the ternary complex (aminoacyl-tRNA-EFTu-GTP) is thermolabile. The effect of magnesium on the formation of EFTu-GDP from the EFTu-EFTs complex of HAK8 shows that a four to fivefold increase of the duplex formation occurs when the magnesium concentration is increased from 10^?6m to 10^?2m at 0 °C and at 41 °C. However, at higher temperatures, formation of the binary EFTu-GDP from the EFTu-EFTs complex of HAK88 is depressed, even at 10^?3m to 10^?2m-magnesium. The binding of GDP to the wild-type or mutant EFTu-EFTs complex at 0 °C and 42 °C indicates that the formation of EFTu-GDP is inhibited at 42 °C only when mutant complex is used for the assay. Binding of GTP to complete bacteriophage Qβ replicase (which is known to contain EFTs) formed in phage-infected HAK88 is also inhibited at 42 °C.     

The 5'-terminal sequence of Q 6S RNA

[γ-³²P]GTP-Labeled Qβ 6S RNA yielded only one major radioactive oligonucleotide after digestion with pancreatic ribonuclease. Nearest neighbor analysis of this 5′-oligonucleotide demonstrated that approximately 95% of the molecules terminate with the same sequence, pppGpGpCp. This sequence is the complement of the only major 3′-sequence found in this RNA. Both strands of 6S RNA therefore appear to have identical 3′- and 5′-terminal trinucleotide sequences.     

Purification and properties of a methionine formylmethionyl-tRNA-binding initiation factor from pig liver

(i) A factor, EIF-2, that binds methionyl-tRNA_f^Met in the presence of GTP has been isolated from pig liver. (ii) Dodecylsulfate-gel electrophoresis and sedimentation equilibrium centrifugation indicate that the factor has a molecular weight of 122,000 and that it consists of three unequal subunits. (iii) The apparent K_D for binding of methionyl-tRNA_f^Met varies with factor concentration. GTP participates in the binding with a K_D of 0.5 μm. β,γ-Methylene-guanosine triphosphate supports 40% of the binding observed with GTP. GDP is a competitive inhibitor with a K_i of 0.2 μm. The optimal, free Mg²⁺ concentration is approximately 50 μm. GTP and Mg²⁺ stabilize the factor against thermal inactivation and inactivation by N-ethyl maleimide. (iv) The factor is required for the formation of a sucrose gradient-stable complex between methionyl-tRNA_f^Met and the 40S ribosomal subunit. The presence of template is not necessary, but poly(A,U,G) increases the binding observed 1.5-fold. (v) The factor markedly stimulates synthesis in a reconstituted protein-synthesizing system with globin messenger RNA as template.     

Temperature sensitivity of protein synthesis initiation. Inactivation of a ribosomal factor by an inhibitor formed at elevated temperatures.

When a reticulocyte lysate, supplemented with hemin, was warmed at 42 °C, its protein-synthesizing activity was greatly decreased. This was accompanied by the reduced formation of the 40 S·Met-tRNA_f initiation complex. This complex preformed at 34 °C, however, was stable and combined with added globin mRNA and the 60 S ribosomal subunit to form the 80 S complex at the elevated temperature. When the ribosome-free supernatant fraction of lysates was warmed at 42 °C with hemin and then added to the fresh lysate system, it inhibited protein synthesis by decreasing the formation of the 40 S complex. This decrease in protein synthesis by warmed lysates or warmed supernatant could be overcome by high concentrations of GTP and cyclic AMP. This effect of GTP and cyclic AMP was antagonized by ATP. The results indicate that the inactivation of protein synthesis by the lysate warmed at 42 °C is due to the formation of an inhibitor in the supernatant. The ribosomal KCl extract prepared from the lysate that had been warmed at 34 °C and then incubated at this temperature for protein synthesis supported protein synthesis by the KCl-washed ribosome at both 34 and 42 °C. On the contrary, the extract from lysates that had been warmed at 42 °C and then incubated at 34 °C could not support protein synthesis at 42 °C, although it was almost equally as promotive as the control extract in supporting protein synthesis at 34 °C. The results indicate that the factor which can protect protein synthesis against inactivation at 42 °C is itself inactivated in lysates warmed at 42 °C. However, the activity of this extract to support formation of the ternary complex with Met-tRNA_f and GTP was not reduced. Native 40 S ribosomal subunits isolated from lysates that had been warmed at 42 °C and then incubated for protein synthesis indicated that the quantity of subunits of density 1.40 g/cm³ in a CsCl density gradient were decreased while those of density 1.49 g/cm³ were increased. The factor-promoted binding of Met-tRNA_f to the 40 S subunit of lower density from the warmed and unwarmed lysates was equal, suggesting that the ribosomal subunit was not inactivated. These results were discussed in terms of the action of the inhibitor formed in the supernatant at 42 °C, which may inactivate a ribosomal factor essential for protein synthesis initiation.