An electron microscopic analysis of pathways for bacteriophage T4 DNA recombination

The interaction between ribosomes of Bacillus stearothermophilus and the RNA genomes of R17 and Qβ bacteriophage has been studied. Whereas Escherichia coli ribosomes can initiate the synthesis of all three RNA phage-specific proteins in vitro, ribosomes of B. stearothermophilus were previously shown to recognize only the A (or maturation) protein initiation site of f2 or R17 RNA. Under these same conditions, a Qβ region is bound and protected from nuclease digestion. Qβ RNA, however, does not direct the synthesis of any formylmethionyl dipeptide in the presence of B. stearothermophilus ribosomes, nor does the binding of either this Qβ region or the R17 A protein initiation site to these ribosomes show the same fMet-tRNA requirement for recognition of initiator regions as that previously established with E. coli ribosomes. Analysis of a 38-nucleotide sequence in the protected Qβ region reveals no AUG or GUG initiator codon. These observations suggest that messenger RNA may be recognized and bound by B. stearothermophilus ribosomes quite independently of polypeptide chain initiation.Binding experiments using R17 RNA and mixtures of components from B. stearothermophilus and E. coli ribosomes confirm the conclusion drawn by Lodish (1970a) that specificity in the selection of authentic phage initiator regions by the two species resides in the ribosomal subunit(s). However, anomalous attachment of B. stearothermophilus ribosomes to R17 RNA, which is observed upon lowering the incubation temperature of the binding reaction, is clearly a property of the initiation factor fraction. The results are discussed with respect to current ideas on the role of ribosomes and initiation factors in determining the specificity of polypeptide chain initiation.     

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.     

Initial velocity kinetic analysis of 30 S initiation complex formation in an in vitro translation system derived from Escherichia coli

The analysis of initial velocity kinetic data was used to examine the order in which fMet-tRNA and the coat cistron of genomic bacteriophage R17 or Q beta RNA bind to the 30 S ribosome subunit. These data were obtained using a quantitative assay for protein synthesis in Escherichia coli extracts where the rate of accumulation of protein product is dependent on the concentration of mRNA and is partially dependent on fMet-tRNA. Under the conditions of this assay, the amount of protein synthesized was proportional to the formation of ternary complexes between the mRNA, fMet-tRNA, and the 30 S ribosomal subunit. The results from the initial velocity and alternative substrate experiments are consistent with a rapid equilibrium ordered mechanism as opposed to a rapid equilibrium random mechanism. Analysis of the rate of coat protein synthesis at varied concentrations of mRNA and fixed concentrations of fMet-tRNA indicated that fMet-tRNA was the first substrate to bind to the 30 S subunit when either coat cistron was used as the mRNA. This scheme assumes the existence of a relatively slow step in protein synthesis that occurs after both the initiating tRNA and mRNA are bound to the ribosome and which allows substrate addition to reach thermodynamic equilibrium.     

Oligonucleotide Sequence of Replicase Initiation Site in Qβ RNA

THE single stranded RNA genome of bacteriophage Qβ has been variously estimated to consist of from 3,500¹ to 4,500² nucleotides. It contains three known cistrons³, which correspond to three of the four Qβ-specific proteins synthesized in vivo and in vitro^4–6. These are: (1) the gene for the maturation or A protein (molecular weight 41,000 (refs. 4, 5)), (2) that for the major coat protein of the virus (molecular weight 14,000 (ref. 9)) and (3) the gene for the phage-specific subunit of the Qβ replicase (molecular weight 64,000 (ref. 10) or 69,000 (ref. 24)), listed in the probable order^7,8 that they occur on the Qβ RNA. The fourth Qβ-specific protein, A₁ or IIb (molecular weight 36,000 (refs. 4–6, 10)), has recently been shown by Weiner and Weber to have an N-terminal sequence which is identical (for eight amino-acids) to that of the coat protein⁷. Because increased amounts of A₁ appear in virus particles grown in cells containing a UGA suppressor, Weiner and Weber postulate⁷ that this protein is the product of natural read-through at the UGA termination signal of the Qβ coat cistron. Such read-through (involving about 600 nucleotides) could occur entirely within a large “intercistronic” region between the coat and replicase genes, or could involve translation, either in or out of phase, of the replicase cistron. In hopes of distinguishing between these alternatives, I have isolated and examined the nucleotide sequence of the region surrounding the initiator codon of the Qβ replicase gene.     

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.     

Affinity labeling of specific regions of 23 S RNA by reaction of N-bromoacetyl-phenylalanyl-transfer RNA with Escherichia coli ribosomes

Reaction of the affinity-labeling reagent N-bromoacetyl-[¹⁴C]phenylalanyl-tRNA with Escherichia coli ribosomes results in covalent labeling of 23 S ribosomal RNA in addition to the previously reported labeling of ribosomal proteins. The reaction with the 23 S RNA is absolutely dependent on the presence of messenger RNA. Covalent attachment of the affinity label to 23 S RNA was demonstrated by its integrity in strongly dissociating solvents, and the conversion of the labeled material to small oligonucleotides by ribonuclease treatment. After digestion of labeled 23 S RNA with T₁ ribonuclease, the radioactivity is found mainly in two oligonucleotide fragments. These results support models in which both ribosomal RNA and ribosomal protein contribute to the structure of the region of the ribosome surrounding the peptidyl transferase center.     

A single UGA codon functions as a natural termination signal in the coliphage q beta coat protein cistron

The coat protein cistron of coliphage Qβ has been shown previously to code for two proteins, both of which are structural components of the mature virion (Weiner and Weber, 1971). The predominant translational product is normally terminated Qβ coat protein, but a second product is also made resulting from inefficient translational termination at the end of the coat protein cistron and subsequent read-through into the intercistronic region. Because the molar fraction of this read-through (or IIb) protein relative to normal coat protein in the viral capsid increases from 2.2% to 7.2% when a UGA suppressor strain is used as host for Q/gb infection, the inefficient termination signal in the Qβ coat cistron must be either a single UGA codon or two UGA codons in tandem.A partial amino acid sequence, which includes the suppressed termination signal, has now been obtained for the IIb protein. This sequence proves that a single UGA codon is used alone as the natural translational termination signal of the coliphage Qβ coat cistron. Evidence is also presented that in both the su^- and su⁺_uga host, the ratio of read-through protein to normally terminated coat protein is 1.5 to threefold higher in vivo than in the purified virus. Thus, in the process of self-assembly, the viral capsid prefers to incorporate normally terminated coat protein rather than the read-through product.     

The regulatory region of MS2 phage RNA replicase cistron. Functional activity of individual MS2 RNA fragments

The present work deals with the structural-functional organization of regulatory regions of messenger RNAs. Some principles of the action of a translational repressor (coat protein) and the formation of the ribosomal initiation complex at the replicase cistron have been studied with MS2 phage RNA. When the complex of MS2 RNA with the coat protein is treated with T₁ ribonuclease, the coat protein selectively protects mainly two fragments (59 and 103 nucleotides in length) from digestion; these fragments contain the intercistronic regulatory region and the beginning of the MS2 replicase cistron. These polynucleotides have been isolated in a pure state and their primary structure has been established.It has been established that both MS2 RNA fragments contain all the necessary information for specific interaction with MS2 coat protein and form a complex with it with an efficiency close to that observed in the case of native MS2 RNA. They also provide the normal polypeptide chain initiation at the replicase cistron. Enzymatic binding of the second aminoacyl-tRNA and electrophoretic analysis of N-terminal dipeptides prove that only the true initiator codon of the replicase cistron is recognized by a ribosome despite the presence of a few additional AUG triplets within the polynucleotides. Under conditions of limited hydrolysis by T₁ ribonuclease, the beginning of the replicase cistron has been removed from the shortest polynucleotide leading to a complete loss of its ability to bind both the coat protein and a ribosome.Some principles of the functioning of the regulatory region in MS2 RNA as well as the nature of the initiator signal of protein biosynthesis are discussed.     

Localization of Qβ Maturation Cistron Ribosome Binding Site

THE RNA of phage Qβ consists of about 3,500 nucleotides¹ and comprises three known cistrons coding for maturation protein (a structural component of the viral particle also designated as A or A₂ protein), coat protein and the β subunit of the viral replicase². When ribosomes are bound to intact Qβ RNA they attach predominantly to one binding site, namely that at the beginning of the coat cistron³. This binding site is located at about the 1,400th nucleotide from the 5′ end¹.     

Binding of mammalian ribosomes to MS2 phage RNA reveals an overlapping gene encoding a lysis function.

The main binding site for mammalian ribosomes on the single-stranded RNA of bacteriophage MS2 is located nine tenths of the way through the coat protein gene. Translation initiated at an AUG triplet in the +1 frame yields a 75 amino acid polypeptide which terminates within the synthetase gene at a UAA codon, also in the +1 frame. Partial amino acid sequence analysis of the product synthesized in relatively large amounts by mammalian ribosomes confirms this assignment of the overlapping cistron. The same protein is made in an E. coli cell-free system, but only in very small amounts. Analysis of the translation products directed by RNA from op3, a UGA nonsense mutant of phage f2, identifies the overlapping cistron as a lysis gene. In this paper we show that the op3 mutation is a C yield U transition occurring in the second codon of the synthetase cistron, which explains the lowered production of phage replicase (as well as lack of lysis) upon op3 infection of nonpermissive cells. We discuss the properties of the overlapping gene in relation to its lysis function, recognition of the lysis initiator region by E. coli versus eucaryotic ribosomes and op3 as a ribosome binding site mutant for the f2 synthetase cistron.     

Biochemical characterization and messenger specificity of polypeptide chain initiation factors from Escherichia coli

Three protein factors are required for maximum poly(U, G)- or AUG-directed binding of fMet-tRNA to ribosomes. The same three factors are both necessary and sufficient for “natural” mRNA-directed binding of fMet-tRNA to ribosomes. Bound fMet-tRNA cosediments with the 70S ribosome as does bound mRNA. All three factors are required for the fMet-tRNA and GTP-dependent binding of mRNA to the 70S initiation complex.     

Rapid peptide bond formation on isolated 50S ribosomal subunits

The catalytic site of the ribosome, the peptidyl transferase centre, is located on the large (50S in bacteria) ribosomal subunit. On the basis of results obtained with small substrate analogues, isolated 50S subunits seem to be less active in peptide bond formation than 70S ribosomes by several orders of magnitude, suggesting that the reaction mechanisms on 50S subunits and 70S ribosomes may be different. Here we show that with full-size fMet-tRNA(fMet) and puromycin or C-puromycin as peptide donor and acceptor substrates, respectively, the reaction proceeds as rapidly on 50S subunits as on 70S ribosomes, indicating that the intrinsic activity of 50S subunits is not different from that of 70S ribosomes. The faster reaction on 50S subunits with fMet-tRNA(fMet), compared with oligonucleotide substrate analogues, suggests that full-size transfer RNA in the P site is important for maintaining the active conformation of the peptidyl transferase centre.     

Differential requirements for polypeptide chain initiation complex formation at the three bacteriophage R17 initiator regions.

The initiation specificity of washed E. coli ribosomes in the presence and absence of purified initiation factors and/or S1 protein has been examined in protection experiments using 32P-labelled R17 RNA. We find that the three bacteriophage initiator regions do not exhibit equal requirements for either of these components during initiation complex formation. Specifically, both factors and S1 stimulate ribosome binding to the beginnings of the coat and replicase cistrons to a greater extent than they promote recognition of the A protein initiation site. The differential effects are therefore inversely correlated with the degree of mRNA-16S rRNA complementarity exhibited by the three initiator regions. We also observe that S1 suppresses ribosome binding to spurious sites in the R17 RNA.     

Translation of bacteriophage R17 and Qbeta RNA in a mammalian cell-free system

The polycistronic RNAs from both bacteriophage R17 and Qβ are translated in a mammalian cell-free system of purified and partially purified components. The requirement of one of the partially purified initiation factors (IF-E₃ from rabbit reticulocytes) for the phage RNA translation is strikingly different from that for rabbit globin messenger RNA translation. The phage RNA-directed products are characterized by acrylamide gel electrophoresis and compared with those synthesized in an Escherichia coli cell-free system. There is good agreement between the respective coat proteins and the presumptive synthetase proteins. R17 RNA directs the synthesis of two additional defined polypeptides. However, their possible relationship with the A-protein cistron has not yet been investigated. The RNA from the amB2 mutant of R17, which carries an amber triplet at position 6 in the coat protein cistron, directs the synthesis of the same polypeptides as the wild-type RNA with the exception of the coat protein which is completely abolished. This identifies the product made with wild-type RNA as coat protein and provides a direct in vitro assay for the suppression of nonsense mutations in eukaryotic cells.     

Inhibition of peptide chain termination by antibodies specific for ribosomal proteins

The effects of antibodies specific for the Escherichia coli 30 S and 50 S ribosomal proteins have been determined for in vitro peptide chain termination and two partial reactions, the codon-directed binding of E. coli release factor to the ribosome and peptidyl-tRNA hydrolysis with RF². Antibodies to ribosomal proteins L7 and L12 inhibit the initial binding of RF to the ribosome, and as a result, the subsequent peptidyl-tRNA hydrolysis. The kinetics of ribosomal inactivation for in vitro termination by anti-L7/L12 indicate that Fab fragments bind to three ribosome sites, and suggest that each of three copies of L7/L12 is involved in the binding of RF to the ribosome. When 70 S ribosome substrates are pretreated with anti-L11 and anti-L16 RF-dependent peptidyl-tRNA, hydrolysis is partially inhibited but the interaction of RF with the ribosome is not affected. The inactivation of in vitro termination by a mixture of anti-L11 and anti-L16 is not co-operative. Pretreatment of the 30 S ribosomal subunit (but not 70 S ribosomal substrate) with antibodies to the 30 S proteins, S9 and S11, results in strong inhibition of codon-directed hydrolysis of peptidyl-tRNA. While these antibodies inhibit ribosome subunit association, a requirement for peptide chain termination, and thereby may inhibit the in vitro termination reactions indirectly, the codon-directed binding of RF is markedly more affected than peptidyl-tRNA hydrolysis by anti-S9 and anti-S11. Antibody to S2 and anti-S3 exhibit a similar but less marked differential effect on the partial reactions of in vitro termination under the same conditions. When dissociated ribosomes are pretreated with anti-L11, in vitro termination is completely inhibited and both codon-directed binding of RF and peptidyl-tRNA hydrolysis are affected. L11 may, therefore, be at or near the interface between the ribosome subunits and like S9 and S11 not completely accessible to antibody in 70 S ribosomes. Pretreatment of dissociated ribosomes with antibodies to a number of other ribosomal proteins (L2, L4, L6, L14, L15, L17, L18, L20, L23, L26, L27) results in partial inhibition of all termination reactions although these antibodies have no effect on termination when incubated with 70 S ribosome substrates. The antibodies probably affect in vitro termination indirectly as a result of either preventing correct ribosome subunit association, or preventing correct positioning of the fMet-tRNA at the ribosome P site.     

Effect of a Purified Initiation Factor F3 (B) on the Selection of Ribosomal Binding Sites on Phage MS2 RNA

STUDIES with T4 mRNA showed that initiation factor F2 (C) promotes the attachment of ribosomes to mRNA¹. On the 30S ribosomal subunit this effect is independent of the function of F2 in the binding of formylmethionyl tRNA², whereas formation of a 70S-mRNA complex depends on the binding of fMet-tRNA³. Template competition experiments⁴ showed that, with F2 (C), the ribosome seems to have the same affinity for synthetic polynucleotides as for natural mRNA. Addition of initiation factor F3 (B), however, leads to preferential binding of ribosomes to the natural mRNA. This suggests⁴ that while factor F2 (C) binds the ribosome to any site on the mRNA, the function of factor F3 (B) is to recognize some specific signal in natural mRNA corresponding, perhaps, to the beginning of a cistron. Fractionation of initiation factor F3 (B) into several species differing in their specificity for different mRNA templates⁵ gave further support to the hypothesis that this protein can select binding sites. An excellent system to demonstrate this effect of F3 (B) would be the binding of ribosomes to RNA from E. coli RNA bacteriophages, since Steitz⁶ has analysed and determined the nucleotide sequence of the three binding sites corresponding to the three cistrons of R17 mRNA. Experiments were thus undertaken to study the effect of a purified fraction of F3 (B) on the binding of ribosomes to the different sites of such a phage RNA.     

Translation by Escherichia coli ribosomes of alfalfa mosaic virus RNA 4 can be initiated at two sites on the monocistronic message.

Substantial evidence is provided to corroborate our previous finding that Escherichia coli ribosomes recognize two binding sites on the 5' end of alfalfa mosaic virus (AMV) RNA 4 [for a preliminary report see Castel, A., Kraal, B., Kerklaan, P. R. M., Klok, J., and Bosch, L. (1977) Proc. Natl Acad. Sci. U.S.A. 74, 5509--5513]. Translation can start at either site using AcPhe-tRNA or fMet-RNA as initiator and takes place in the same reading frame along the monocistronic mRNA. The size and composition of the isolated extra NH2-terminal fragment of the acetylphenylalanyl product were found to be in agreement with the 5' non-coding region of the messenger. Removal of the 5'-terminal cap structure of AMV RNA 4 did not influence significantly both initiation reactions. Ribosomal protein S1 was essential for binding as well as incorporation of both fMet-tRNA and AcPhe-tRNA. A similar interaction on the ribosome was found for AcPhe-tRNA directed by AMV RNA 4 as for fMet-tRNA directed by either AMV RNA 4 or MS2 RNA with respect to the influence of initiation factors. It is concluded that the heterologous plant viral messenger is reliably translated in the E. coli system and that E. coli ribosomes recognize with high specificity an extra initiation site close to the 5' extremity of the messenger. The relationship of this site to a hypothetical entry site involved in the early recognition in the initiation mechanism between ribosome and messenger is discussed.     

Studies on the function of intracellular ribonucleases. V. Ribonuclease activity in ribosomes and polysomes prepared from rat liver and hepatomas

The RNase activity and properties of ribosome and polysome preparations from normal rat liver and some hepatomas have been examined. Polysome and ribosome preparations from the Novikoff, McCoy MDAB, and Dunning hepatomas had considerably higher specific RNase activity than corresponding preparations from normal rat liver, Novikoff ascites, or Morris 5123 hepatomas. The optimum pH of the RNase was approximately 8.5 for all samples tested, and the samples showed no evidence of latent RNase activity when treated with 3 M sodium chloride, EDTA, urea, or p-chloromercuribenzenesulfonic acid. The RNase activity appeared to be associated principally with breakdown products and/or subunits smaller than 80S. In the presence of Mg⁺⁺ ions, subunits could reaggregate to form monomer ribosomes indistinguishable from the natural products, but some of the reassociated ribosomes could contain RNase activity which had been bound to the smaller particles. Similar results were obtained with spermine. In the hepatomas, evidence was obtained for the preexistence of considerable amounts of the smaller, RNase-containing subunits in the cell. When a small amount of crystalline bovine pancreatic RNase was added to partly dissociated ribosomes, the RNase was found only in association with the smaller subunits, and little or no enzyme was taken up by ribosomes or polysomes. The results have led to the conclusion that RNase is not a normal constituent of the ribosome or polysome, but that RNase may become associated with these particulates if dissociation and reassociation take place. Some implications of these findings for the stability of messenger RNA and for the mechanism of its breakdown are discussed.     

RNase catalyzed hydrolysis of ribosomes in several functional states

The RNase A catalyzed hydrolysis of rRNA in ribosomes has been studied for nonwashed 50S and 70S ribosomes, for washed 50S and 70S ribosomes, for runoff 50S ribosomes and for 70S ribosomes in polysomes. The regions available to hydrolysis in the 50S ribosome remain available when the 50S ribosomes become a part of a 70S ribosome or a polysome. The regions available to hydrolysis in the 30S ribosome become unavailable when the 30S ribosome becomes part of a 70S ribosome or a polysome. Removal of tRNA, mRNA and factors from the 50S and 70S ribosome lowers the rate of hydrolysis of one site in the 23S rRNA. This shows that the conformation of one region of the 23S RNA changes for ribosomes in different functional states.