Binding of the structural protein soc to the head shell of bacteriophage T4

Qβ plus strands with a 70 S ribosome bound to the coat cistron initiation site were used as template for Qβ replicase. Minus strand synthesis proceeded until the replicase reached the ribosome. The ribosome was removed and elongation was continued in a substrate-controlled, stepwise fashion. The nucleotide analog N⁴-hydroxyCMP was introduced into the positions complementary to the third and fourth nucleotides of the coat cistron. The minus strands were elongated to completion, purified and used as template for Qβ replicase. The final plus strand preparation consisted of four species, with the sequences -A-U-G-G- (wild type), -A-U-A-G- (mutant C₃), -A-U-G-A- (mutant C₄) and -A-U-A-A- (mutant $\text{C}{}_3\text{C}{}_4$) at the coat initiation site. The ribosome binding capacity of the mutant RNAs relative to wild type was <0.1 (C₃), 3.2 (C₄) and 0.3 ($\text{C}{}_3\text{C}{}_4$). The finding that mutant C₃ no longer formed an initiation complex suggests that the interaction of the ribosome binding site with fMet-tRNA plays an essential role in the formation of the 70 S initiation complex. The fact that mutant C₄ RNA bound more efficiently than wild type, and that mutant $\text{C}{}_3\text{C}{}_4$ RNA showed substantial ribosome binding capacity whereas the single mutant C₃ did not, can be explained by assuming that an A residue following the A-U-G triplet interacts with a complementary U residue in the anticodon loop sequence. In the case of $\text{C}{}_3\text{C}{}_4$ this additional base-pair may offset the reduced codon-anticodon interaction resulting from the modification of the A-U-G codon.     

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.     

Differential effect of Ca+2 on the translation of yeast mitochondrial and some viral RNA'S in an E.coli cell-free system.

Addition of 6mM CaCl₂ to an $\text{E. coli}$ cell-free system resulted in a several-fold enhancement of yeast mt RNA translation and in a severe inhibition of protein synthesis directed by MS2, Qβ and T₅ RNA's. CaCl₂ did not alter the Mg⁺² optimum or the time-course of protein synthesis and had no apparent effect on RNA degradation. Formaldehyde treatment of MS2 RNA markedly diminished the CaCl₂-mediated inhibition of its translation. Addition of equimolar amounts of EGTA, together with CaCl₂, abolished the effect of the latter on cell-free protein synthesis. FMet tRNA binding to ribosomes was enhanced by CaCl₂ in the presence of mt RNA, inhibited in the presence of MS2 RNA, and unaffected in the presence of formaldehyde-treated MS2 RNA. Maximal effect on initiation complex formation was observed with 0.1 mM CaCl₂.     

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.     

Resynchronization of RNA synthesis by coliphage Qbeta replicase at an internal site of the RNA template

In previous work Qβ replicase has been used to synthesize labelled 5′ terminal segments of Qβ plus or minus strands of defined length. A procedure has now been developed which allows resynchronization of Qβ replicase at an internal position and synthesis of a labelled minus-strand segment complementary to the coat cistron ribosome binding site and the intercistronic region between the A₂ (maturation) and the coat cistron. Resynchronization is accomplished by binding a ribosome to Qβ RNA and allowing Qβ replicase to initiate and elongate up to the ribosome, using unlabelled ribonucleoside triphosphates. The ribosome is dissociated by EDTA treatment and the EDTA is removed. The replicating complex remains functional after this treatment, and addition of labelled substrates leads to synchronized elongation. The radioactive part of the product recovered after a short elongation period with labelled substrates was shown to be complementary to the coat protein ribosome binding site.     

Effects of 3′-deoxyadenosine triphosphate on in vitro RNA synthesis of plant RNA-dependent RNA polymerases

3′-deoxyadenosine triphosphate inhibited $\text{in}\text{vitro}$ [³H]UMP incorporation by RNA-dependent RNA polymerases from tobacco and cowpea plants. The inhibition of [³H]UMP incorporation could be reversed by simultaneous addition of higher ATP concentrations but not with increasing concentrations of UTP or when excess ATP was added 10 min after the inhibitor. These results suggest 3′-deoxyadenosine triphosphate competes specifically with ATP in reaction mixtures and results in premature termination of RNA synthesis $\text{in}\text{vitro}$ by RNA-dependent RNA polymerase.     

The two effects of rifampicin on the RNA polymerase reaction.

At 25°C rifampicin strongly stimulates the synthesis of the dinucleotide pppA-U catalyzed by the DNA-dependent RNA polymerase from $\text{Escherichia coli}$. If the antibiotic is added to the enzyme during the synthesis of RNA the stimulatory effect on the dinucleotide synthesis is distinctly retarded as is its inhibitory action on RNA synthesis. It is proposed that this lag period is due to a retardation of the binding of rifampicin to RNA polymerase which is required for its action. Because of this slower binding rifampicin — although an inhibitor of RNA chain elongation — mimics the action of an inhibitor of RNA chain initiation.     

Complete amino acid sequence of the coat protein of the Pseudomonas, aeruginosa RNA bacteriophage PP7

As part of a project intending to assess the evolutionary kinship between the RNA coliphages and RNA bacteriophages of other bacterial genera, we have sequenced the coat protein of $\text{Pseudomonas}\text{,}\text{aeruginosa}$ RNA phage PP7. Like the coat proteins of coliphages MS2 and Qβ and of the broad host range RNA phage PRR1, PP7 coat protein (127 residues) is highly hydrophobic, and contains a cluster of basic residues between positions 40 to 60. Minimal mutation distance values were calculated for comparison of PP7 coat protein with each MS2, Qβ and PRR1 coat proteins. Application of the Moore-Goodman criterion to those values, shows that these four RNA bacteriophage coat proteins very likely descent from a common ancestor.     

Replication of RNA viruses: specific binding of the Q RNA polymerase to Q RNA

The specific binding in vitro of the Qβ RNA polymerase to Qβ RNA has been detected by the formation of an enzyme-Qβ RNA complex that did not exchange bound RNA molecules and was not dissociated by 0.8 m NaCl. Formation of this nondissociating complex required GTP and two host protein factors, but not ATP, CTP, UTP, or Mg²⁺ ions. GDP, GMP, dGTP, ITP, and β,γ-methylene GTP did not replace GTP in the reaction. Complex formation at 0 °C was not observed, and the rates of the reaction at 30 °C and 25 °C were 41% and 23%, respectively, of the rate at 37 °C. The reaction occurred with intact Qβ RNA and with polycytidylic acid template but not with bacterial or other bacteriophage RNA. With limiting amounts of enzyme, the amount of Qβ RNA bound in the nondissociating complex was the same as the amount of [γ-³²P]GTP incorporated into nascent RNA chains, indicating a close relationship between complex formation and the initiation of RNA synthesis. The two reactions appear to be separate, however, because in the absence of Mg²⁺ ions, when complex formation occurred readily, no RNA synthesis could be detected either by incorporation of labeled substrate into acid-insoluble material or by formation of short RNA chains still attached to the enzyme. In the presence of factor protein and GTP, a maximum of one active enzyme molecule was bound per molecule of Qβ RNA template, as determined by a liquid polymer phase-separation procedure. These results suggest that formation of the nondissociating complex measures recognition by the Qβ RNA polymerase of a single Qβ RNA site utilized for the initiation of synthesis.     

Synthesis and properties of a new fluorescent analog of ATP: Adenosine-5′-triphosphoro-γ-1-(5-sulfonic acid) napthylamidate

An analog of ATP has been synthesized which contains the fluorophore, 1-aminonapthalene-5-sulfonate attached via a γ-phosphoamidate bond. This analog is strongly fluorescent (quantum yield = 0.63) with an emission maximum at 460 nm; the excited state lifetime is 20 nsec. It is a substrate for DNA-dependent RNA polymerase of $\text{E. coli}$ and wheat germ RNA polymerase II. It is also a substrate for $\text{E. coli}$ valyl t-RNA synthetase, venom phosphodiesterase, and potato apyrase. Cleavage of the α-β phosphoryl bond as a result of RNA synthesis or by venom phosphodiesterase produces a 15 nm red shift in the fluorescence emission spectrum. This property should make this nucleotide useful for studies of the mechanisms of enzymatic reactions involving cleavage of the α-β phosphoryl bond.     

Crystal Structure of the Bacteriophage Qβ Coat Protein in Complex with the RNA Operator of the Replicase Gene

The coat proteins of single-stranded RNA bacteriophages specifically recognize and bind to a hairpin structure in their genome at the beginning of the replicase gene. The interaction serves to repress the synthesis of the replicase enzyme late in infection and contributes to the specific encapsidation of phage RNA. While this mechanism is conserved throughout the Leviviridae family, the coat protein and operator sequences from different phages show remarkable variation, serving as prime examples for the co-evolution of protein and RNA structure. To better understand the protein–RNA interactions in this virus family, we have determined the three-dimensional structure of the coat protein from bacteriophage Qβ bound to its cognate translational operator. The RNA binding mode of Qβ coat protein shares several features with that of the widely studied phage MS2, but only one nucleotide base in the hairpin loop makes sequence-specific contacts with the protein. Unlike in other RNA phages, the Qβ coat protein does not utilize an adenine-recognition pocket for binding a bulged adenine base in the hairpin stem but instead uses a stacking interaction with a tyrosine side chain to accommodate the base. The extended loop between β strands E and F of Qβ coat protein makes contacts with the lower part of the RNA stem, explaining the greater length dependence of the RNA helix for optimal binding to the protein. Consequently, the complex structure allows the proposal of a mechanism by which the Qβ coat protein recognizes and discriminates in favor of its cognate RNA.     

Thirty Years of Studies of Qβ Replicase: What Have We Learned and What Is Yet to Be Learned?

Qβ replicase (RNA-directed RNA polymerase of bacteriophage Qβ) has an unsurpassed capacity to amplify polynucleotides in vitro. In 1986, the Group of Viral RNA Biochemistry was organized at the Institute of Protein Research in order to exploit this property for the synthesis of messenger RNAs to be used in cell-free translation systems. Although the task has not been implemented in full, this work has led to a number of unexpected important results including uncovering the nature of the “template-free” RNA synthesis by Qβ replicase, discovering the ability of RNA molecules for spontaneous recombination, revealing the unusual mechanism Qβ replicase uses to discriminate between its proper and improper templates, and discovering a new function of the largest ribosomal protein S1, that is also one of the replicase subunits. Finally, our work resulted in the invention of the molecular colonies technique that has become the basis for the next generation sequencing methods and provided a new insight into the origin of life. However, Qβ replicase has not yet revealed all its secrets, and its studies promise further interesting findings.