Effect of T4 infection on initiation of protein synthesis and messenger specificity of initiation factor 3

No alteration in the messenger specificity of initiation factor 3 (IF-3) is observed upon T4 phage infection of several strains of Escherichia coli. IF-3 present in the 1.0 m NH₄Cl washes of ribosomes from T4-infected cells supports the translation of f2 RNA and T4 late mRNA with the same degree of efficiency as the IF-3 in the ribosomal washes obtained from uninfected cells. At high concentrations the ribosomal washes obtained from T4-infected cells are more inhibitory for both f2 RNA- and T4 late mRNA-directed protein synthesis than the ribosomal washes from uninfected cells. Furthermore, this increased inhibition is also observed in the poly(U)-directed synthesis of polyphenylalanine. These data suggest that translational controls exerted at the level of IF-3 probably do not account for the alterations in protein synthesis observed upon T4 infection.     

Interaction of a fluorescent streptomycin derivative with Escherichia coli ribosomes.

The high salt wash of rabbit reticulocyte ribosomes contains two separate factors which can partially reverse the inhibition of polypeptide chain initiation that results when reticulocyte lysate is incubated in the absence of hemin. These two factors, termed initiation factor (IF) 1 and IF-2, have been separated from each other by chromatography on diethylaminoethyl cellulose and then further purified on hydroxyapatite. IF-1 forms a GTP-dependent complex with methionyl-tRNA_f that is retained on Millipore filters. When these factors are added to a system containing reconstituted, salt-extracted ribosomes, IF-1 promotes the binding of methionyl-tRNA_f to the 40 S subunit, whereas IF-2 promotes the formation of 80 S initiation complexes from 40 S complexes. Addition of small amounts of one factor and a saturating level of the other to the unfractionated lysate and incubation in the absence of hemin produce an additive stimulation of protein synthesis. Each factor can also partially reverse the inhibitory effect of the hemin-controlled translational repressor. The implication of these findings for the mechanism of hemin control of protein synthesis in reticulocyte lysates is discussed.     

Activity of different forms of initiation factor 2 in the vitro synthesis of beta-galactosidase.

Two forms of initiation factor 2, (IF-2α, M_r, 118,000 and IF-2β, M_r 90,000) have been isolated from Escherichia coli extracts and tested for their ability to support β-galactosidase synthesis in a phage DNA-directed in vitro protein synthesis system. Although both forms are equally active in supporting the binding of fMet-tRNA to ribosomes only IF-2α functions in β-galactosidase synthesis.     

Immunological characterization of the complex forms of chloroplast translational initiation factor 2 from Euglena gracilis.

Euglena gracilis chloroplast translational initiation factor 2 (IF-2chl) occurs in several complex forms ranging in molecular mass from 200 to 800 kDa. Subunits of 97 to greater than 200 kDa have been observed in these preparations. Two monoclonal antibodies were prepared against the 97-kDa subunits of IF-2chl. Both of these antibodies recognize all of the higher molecular mass forms of this factor, suggesting that these subunits are closely related. Gel filtration chromatography indicates that the higher molecular mass subunits of IF-2chl are present in the higher molecular mass complexes, whereas the smaller subunits are present in the 200-400 kDa forms of IF-2chl. Probing extracts of light-induced and dark-grown cells with the antibodies indicates that the light induction of this chloroplast factor results from the synthesis of new polypeptide rather than from the activation of an inactive precursor form of the protein. Both the higher and lower molecular mass subunits of IF-2chl are present in 30 S initiation complexes as indicated by Western analysis. The binding of IF-2chl to chloroplast 30 S ribosomal subunits requires the presence of GTP, but does not require fMet-tRNA, messenger RNA, or other initiation factors. Neither polyclonal nor monoclonal antibodies against E. gracilis IF-2chl cross-react with Escherichia coli IF-2 or with animal mitochondrial IF-2.     

Chloroplast translational initiation factor 3. Purification and characterization of multiple forms from Euglena gracilis.

The chloroplast translational initiation factor 3 (IF-3chl) has been purified by a combination of gravity and high pressure liquid chromatographic steps. IF-3chl activity has been resolved into three forms designated alpha, beta, and gamma. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicates that the alpha form corresponds to a single polypeptide with a molecular mass of approximately 34 kDa. The beta and gamma forms have been purified to near homogeneity, and both forms appear to function as monomers with molecular masses of about 39-42 kDa. All three forms are heat stable. All the forms of IF-3chl detected enhance the poly (A,U,G)-dependent binding of the initiator tRNA to chloroplast 30 S ribosomal subunits in the presence of Escherichia coli IF-1 and IF-2. The chloroplast factor, unlike the corresponding bacterial factor, does not have a strong RNA binding activity.     

Properties and regulation of the GTPase activities of elongation factors Tu and G,and of initiation factor 2

Summary During protein synthesis the interaction with ribosomes of elongation factors Tu (EF-Tu), G (EF-G) and initiation factor 2 (IF-2) is associated with the hydrolysis of GTP which is directly related to the functions of the factors. In this article we review systematically the properties of these GTPase activities in the presence and absence of protein synthesis, and by examining the characteristics of the different minimal systems for the expression of these activities we point to the role of the various effectors and to the enzymological aspects of the systems. For EF-Tu, it has been possible to eliminate any requirement for macromolecular effectors, showing that the factor itself is a GTPase. For EF-G, the presence of at least the 50S ribosomal subunit has remained a requirement, whereas IF-2 needs both the 50S and 30S subunits to exibit GTPase activity. Between the GTPase activities of the three factors there are some striking similarities, but important differences prevail as a consequence of the specificity of the different functions. This can also be seen by examining the respective ribosomal regions implicated in these reactions. When coupled with protein synthesis, the three GTPase activities reveal characteristics differing from those observed in partial systems.     

Initiation of protein synthesis in animal mitochondria. Purification and characterization of translational initiation factor 2

Bovine liver mitochondrial translational initiation factor 2 (IF-2mt) has been purified to near homogeneity. The scheme developed results in a 24,000-fold purification of the factor with about 26% recovery of activity. SDS-polyacrylamide gel electrophoresis indicates that IF-2mt has a subunit molecular mass of 85 kDa. IF-2mt promotes the binding of formyl(f)Met-tRNA to mitochondrial ribosomes but is inactive with the nonformylated derivative. IF-2mt is active on chloroplast 30 S ribosomal subunits, but IF-2chl has no activity in promoting fMet-tRNA binding to animal mitochondrial ribosomes. IF-2mt is sensitive to elevated temperatures and is inactivated by treatment with N-ethylmaleimide. It is partially protected from heat and N-ethylmaleimide inactivation by the presence of either GTP or GDP suggesting that guanine nucleotides may bind to this factor directly. The binding of fMet-tRNA to mitochondrial ribosomes requires the presence of GTP and is inhibited by GDP. DeoxyGTP is very effective in replacing GTP in promoting fMet-tRNA binding to ribosomes and some activity is also observed with ITP. No activity is observed with ATP, CTP, or UTP. Nonhydrolyzable analogs of GTP can promote formation of both 28 S and 55 S initiation complexes indicating that GTP hydrolysis is not required for subunit joining in the animal mitochondrial system.     

Initial rate kinetic analysis of the mechanism of initiation complex formation and the role of initiation factor IF-3.

Initial rate kinetics of the formation of ternary complexes of Escherichia coli 30S ribosomal subunits, poly(uridylic acid), and N-acetylphenylalanyl transfer ribonucleic acid in the presence and in the absence of IF-3 are consistent with the hypothesis that the ternary complex is formed through a random order of addition of polynucleotide and aminoacyl-tRNA to separate and independent binding sites on the 30S ribosomes. The transformation of an intermediate into a stable ternary complex which probably entails a rearrangement of the ribosome structure leading to a codon-anticodon interaction represents the rate-limiting step in the formation of the ternary complex. The rate constant of this transformation, as well as the association constants for the formation of the 30S-poly(U) and 30S-N-AcPhe-tRNA binary complexes, are enhanced by the presence of IF-3 which acts as a kinetic effector on reactions which are intrinsic properties of the 30S ribosome. The IF-3-induced modification of these kinetic parameters of the 30S ribosomal subunit can per se explain the effect of IF-3 on protein synthesis without invoking a specific action at the level of the mRNA-ribosome interaction. This seems to be confirmed by the finding that IF-3 can stimulate several-fold the formation of a ternary complex even if one by-passes the ribosome-template binding step by starting with a covalent 30S-polynucleotide binary complex. Furthermore, the above-mentioned changes induced by IF-3 appear to be compatible with the previously proposed idea that the binding of the factor modifies the conformation of the 30S subunit. The random order of addition of substrates determined for the 30S-N-AcPhe-tRNA-poly(U) model system was found to be valid also for the more physiological 30S initiation complex containing poly(A,U.G) and (fMet-tRNA formed at low Mg2+ concentration in the presence of GTP and all three initiation factors.     

Requirements for in vitro reconstruction of protein synthesis

Translation of f2am3 RNA and MS2 RNA in a system containing purified ribosomes and precharged aminoacyl-tRNA, does not occur in the presence of the "known" initiation (IF-1, IF-2 and IF-3), elongation (EF-Tu, EF-Ts and EF-G) and termination (RF-1, RF-2) factors. Translation in this system requires at least three additional protein factors. These are EF-P and the rescue protein as well as a previously undescribed factor we call W, which is found in the high-salt ribosomal eluate.     

Bacteriophage T7 morphogenesis and gene 10 frameshifting in Escherichia coli showing different degrees of ribosomal fidelity.

Summary Bacteriophage T7 infection has been studied in Escherichia coli strains showing both increased and decreased ribosome fidelity and in the presence of streptomycin, which stimulates translational misreading, in an effort to determine effects on the apparent programmed translational frameshift that occurs during synthesis of the gene 10 capsid protein. Quantitation of the protein bands from SDS-PAGE failed to detect any significant effects on the amounts of the shifted 10B protein relative to the in-frame 10A protein under all fidelity conditions tested. However, any changes in fidelity conditions led to inhibition of phage morphogenesis in single-step growth experiments, which could not be accounted for by reduced amounts of phage protein synthesis, nor, at least in the case of decreased accuracy, by reduced amounts of phage DNA synthesis. Reduction in phage DNA synthesis did appear to account for a substantial proportion of the reduction in phage yield seen under conditions of increased accuracy. Similar effects of varying ribosomal fidelity on growth were also seen with phage T3, and to a lesser extent with phage T4. The absence of change in the high-frequency T7 gene 10 frameshift differs from earlier reports that ribosomal fidelity affects low-frequency frameshift errors.     

Expression and functional analysis of Euglena Gracilis chloroplast initiation factor 3

A portion of a cDNA predicted to encode the mature form of Euglena gracilis chloroplast translational initiation factor 3 (IF-3_chlM, molecular mass, 46402) and the portion of this factor homologous to bacterial IF-3 (IF-3_chlH, molecular mass 22829) have been cloned and expressed in Escherichia coli as histidine-tagged proteins. The homology domain can be expressed in reasonable levels in E. coli. However, IF-3_chlM is quite toxic and can only be produced in small amounts. Both forms of the chloroplast factor are associated with E. coli ribosomes. Purification procedures have been developed for both IF-3_chlM and IF-3_chlH using Ni-NTA affinity chromatography followed by ion exchange chromatography. IF-3_chlM and IF-3_chlH are active in promoting ribosome dissociation and in promoting the binding of fMet-tRNA to E. coli ribosomes. However, IF-3_chlH has at least 5-fold more activity than either native IF-3_chl or IF-3_chlM in promoting initiation complex formation on chloroplast 30S ribosomal subunits in the presence of a mRNA carrying a natural translational initiation signal. This observation suggests that regions of IF-3_chl lying outside of the homology domain may down-regulate the activity of this factor.This work was supported in part by National Institutes of Health Grant GM24963.     

Binding of labeled initiation factor IF-1 to ribosomal particles and the relationship to the mode of IF-1 action in ribosome dissociation.

The binding of labeled initiation factor IF-1 to ribosomal particles has been studied in relation to the mode of action of this factor in the dissociation of 70-S ribosomes. It is demonstrated that IF-1 interacts specifically with active 70-S tight couples and free 30-S subunits. The binding of IF-1 to both 70-S and 30-S particles is not influenced by the Mg2+ concentration and the affinity of the factor for both particles is about the same. The interaction of IF-1 with these particles is highest at low Tris-HCl concentrations. Under these conditions IF-1 shows a slight dissociating activity. Using 3H-labeled IF-1 and 14C-labeled IF-3 the formation of a 30-S-subunit.IF-1 . IF-3 complex from 70-S ribosomes is demonstrated. Our studies show that IF-3 enhances the binding of IF-1 to the 30-S subunit. In contrast to IF-1, which binds about equally well to 70-S and 30-S particles in the absence of IF-3, 14C-labeled IF-3 binds predominantly to the 30-S subunit. This finding confirms the view that IF-3 acts as an anti-association factor. On the other hand, IF-1 enhances the supply of 30-S subunits in the presence of IF-3 by acting on the 30-S moiety of the 70-S ribosome.     

Function of initiation factor 1 in the binding and release of initiation factor 2 from ribosomal initiation complexes in Escherichia coli.

1. Studies on the function of initiation factor 1 (IF-1) in the formation of 30 S initiation complexes have been carried out. IF-1 appears to prevent the dissociation of initiation factor 2 (IF-2) from the 30 S initiation complex. The factor has no effect on either the initial binding of IF-2 nor does it increase the amount of IF-2 dependent fMet-tRNA and GTP bound to the 30 S subunit. Bound fMet-tRNA remains stable to sucrose gradient centrifugation even in the absence of IF-1. 2. It is postulated that the presence of IF-2 on the 30 S complex is necessary so that at the time of junction with the 50 S subunit to form a 70 S complex, the 70 S-dependent GTPase activity of IF-2 can hydrolyze GTP. This hydrolysis provides a means by which GTP can be removed to facilitate formation of a 70 S initiation complex active in peptidyl transfer. In support of this postulate, it was observed that 30 S initiation complexes formed in the absence of IF-1 could be depleted of their complexes were still able to accept 50 S subunits to form 70 S complexes which could still donate fMet-tRNA into peptide linkages. These results indicate that 30 S complexes lacking GTP do not require IF-2 for formation of active 70 S complexes. 3. IF-1, which is required to prevent dissociation of IF-2 from the 30 S initiation complex, is also required for release of IF-2 from ribosomes following 70 S initiation complex formation. The mechanisms of the release of IF-2 has been studied in greater detail. Evidence is presented which rules out the presence of a stable IF-2 GDP complex on the surface of the 70 S ribosome following GTP hydrolysis and of any exchange reactions between IF-1 and guanine nucleotides necessary for effecting the release of IF-2. IF-2 remains on the 70 S initiation complexes after release of guanine nucleotides and can be liberated solely by addition of IF-1.     

Host interference with viral gene expression: mode of action of bacterial factor i

The mechanism of interference with R17 viral RNA expression by a host protein, factor i, was studied. Formation of initiation complexes on native bacteriophage R17 RNA molecules, as well as translation of R17 RNA in vitro, is blocked almost quantitatively by factor i. This inhibition is readily overcome by the addition of excess R17 RNA. Extensive complex formation between factor i and R17 RNA occurs during inhibition of initiation complex formation. Moreover, the extent of inhibition of R17 RNA translation correlates closely with the extent of complex formation between factor i and R17 RNA, and exhibits the same sigmoid concentration dependence on factor i.Although initiation complex formation is totally dependent upon initiation factor IF-3, neither this function of IF-3, nor its ability to prevent the association of 30 S and 50 S ribosomal subunits into single ribosomes, is affected by factor i. IF-3, even when present in tenfold molar excess over factor i, fails to relieve the inhibition of initiation on R17 RNA.It is concluded that factor i is a translational represser acting directly on messenger RNA. It is suggested that this repression is cistron-specific, affecting only viral coat protein synthesis. Messenger RNA discrimination by factor i does not involve initiation factor IF-3.     

Euglena gracilis chloroplast initiation factor 2. Identification and initial characterization

The chloroplast protein synthesis factor responsible for the binding of fMet-tRNAMeti to chloroplast 30 S ribosomal subunits (IF-2chl) has been identified in whole cell extracts of Euglena gracilis. The IF-2chl activity is present in considerably higher amounts in extracts of light-grown cells than in extracts of dark-grown cells. About 90% of this activity is found in the postribosomal supernatant of the cell. Chromatography on phosphocellulose results in the partial purification of IF-2chl and separates the chloroplast factor from the cytoplasmic factor eIF-2A. The binding of fMet-tRNAMeti to chloroplast 30 S subunits is message-dependent as observed for prokaryotic systems. In addition, GTP stimulates the IF-2chl-dependent reaction 3-fold. The binding reaction shows broad monovalent and divalent cation optima. The activity of IF-2chl is stimulated 2-fold by the addition of either Escherichia coli IF-1 or IF-3, and 4-fold by the inclusion of both factors. Chloroplast IF-2 is quite active on the homologous 30 S ribosomal subunits but shows little activity on E. coli 30 S or wheat germ 40 S subunits.     

Structure and function of RNA replicase of bacteriophage Qbeta.

(1) The RNA replicase induced by bacteriophage Qbeta consists of four non-identical subunits designated as alpha (mol. wt. 74000), beta (mol. wt. 64000), gamma (mol. wt. 47000) and delta (mol. wt. 33000), only one (subunit beta) of which is specified by the phage genome. (2) Subunit alpha (30 S ribosomal protein "S1" as well as translational interference factor "i") is required only for (+) strand-directed RNA synthesis in the presence of the host factor. (3) Qbeta replicase lacking subunit alpha (R-alpha) is capable of replicating templates other than (+) strand, such as (--), "6S" RNA, poly(C) etc., in the absence of the host factor. (4) Subunit beta is suggested to be the nucleotide-polymerizing enzyme, but is unable to initiate RNA synthesis by itself. (5) Subunits gamma and delta are identical to the protein synthesis elongation factors, EF-Tu and EF-Ts, respectively, and are required only for initiation of RNA synthesis, but not for elongation. (6) A model of Qbeta replicase is presented in order to discuss observed template-enzyme interactions.     

Purified internal G-domain of translational initiation factor IF-2 displays guanine nucleotide binding properties

Translational initiation factor IF-2 is involved in a multistep pathway leading to the synthesis of the first peptide bond. IF-2 is a guanine nucleotide binding protein (G-protein) and catalyzes GTP hydrolysis in the presence of ribosomes. According to sequence homologies with other G-proteins, particularly EF-Tu, a theoretical model for the tertiary structure of the putative G-domain of IF-2 has been previously proposed [Cenatiempo, Y., Deville, F., Dondon, J., Grunberg-Manago, M., Hershey, J. W. B., Hansen, H. F., Petersen, H. U., Clark, B. F. C., Kjeldgaard, M., La Cour, T. F. M., Mortensen, K. K., & Nyborg, J. (1987) Biochemistry 26, 5070-5076]. A short fragment of IF-2 encompassing the putative G-domain was purified by limited proteolysis of a chimeric protein, synthesized from a gene fusion, between a segment of the IF-2 gene and lacZ. The N- and C-terminal sequences of this IF-2 peptide were characterized. Its calculated length is 181 amino acids and its molecular mass 19.4 kDa, whereas it migrates at 14 kDa in SDS-polyacrylamide gels. This segment of IF-2 can form binary complexes with GDP and can be cross-linked to GTP, therefore indicating that it really corresponds to the G-domain. However, in contrast to the situation described for the purified G-domain of EF-Tu, the IF-2 fragment did not hydrolyze GTP even in the presence of ribosomes. It is assumed that active centers of IF-2 located outside the G-domain are needed for the latter reaction.(ABSTRACT TRUNCATED AT 250 WORDS)     

The Pseudomonas aeruginosa initiation factor IF-2 is responsible for formylation-independent protein initiation in P. aeruginosa

Formylation of the initiator methionyl-tRNA (Met-tRNAfMet) was generally thought to be essential for initiation of protein synthesis in all eubacteria based on studies conducted primarily in Escherichia coli. However, this view of eubacterial protein initiation has changed because some bacteria have been demonstrated to have the capacity to initiate protein synthesis with the unformylated Met-tRNAfMet. Here we show that the Pseudomonas aeruginosa initiation factor IF-2 is required for formylation-independent protein initiation in P. aeruginosa, the first bacterium shown to have the ability to initiate protein synthesis with both the initiator formyl-methionyl-tRNA (fMet-tRNAfMet) and Met-tRNAfMet. The E. coli IF-2, which participates exclusively in formylation-dependent protein initiation in E. coli, was unable to facilitate utilization of Met-tRNAfMet in initiation in P. aeruginosa. However, the E. coli IF-2 was made to function in formylation-independent protein initiation in P. aeruginosa by decreasing the positive charge potential of the cleft that binds the amino end of the amino acid attached to the tRNA. Furthermore increasing the positive charge potential of this cleft in the P. aeruginosa IF-2 prevented the protein from participating in formylation-independent protein initiation. Thus, this is the first demonstration of a eubacterial IF-2 with an inherent capacity to facilitate utilization of Met-tRNAfMet in protein initiation, discounting the dogma that eubacterial IF-2 can only allow the use of fMet-tRNAfMet in protein initiation. Furthermore these findings give important clues to the basis for discriminating the initiator Met-tRNA by IF-2 and for the evolution of alternative mechanisms for discrimination.     

Requirement of chain initiation factor 3 and ribosomal protein S1 in translation of synthetic and natural messenger RNA.

Amino acid incorporation directed by poly(A), poly(U) or R17 RNA has been examined in S1-depleted protein synthesizing systems. We observe that the translation of either synthetic or natural messenger RNA is strictly dependent on the presence of chain initiation factor 3 and ribosomal protein S1. With poly(A) or poly(U) both IF-3 and S1 stimulate amino acid incorporation at least 25-fold, and with R17 RNA the stimulation is approximately 15-fold. More than one copy of S1 per ribosome decreases amino acid incorporation directed by poly(U) or R17 RNA. Initiation complex formation with R17 RNA is also stimulated optimally by the addition of one copy of S1 per ribosome. The function of IF-3 and S1 in protein synthesis is considered.     

Involvement of ribosomal protein S1 in the assembly of the initiation complex.

Antibodies against ribosomal protein S1 (anti-S1) have been used to determine the function of S1 in the partial reactions involved in the translation of MS2 RNA in vitro. Vacant ribosomes are fully sensitive to the antibodies, whereas elongating ribosomes are resistant. We have determined at which stage of translation the resistance to anti-S1 is acquired. We find that insensitivity to anti-S1 already arises upon mixing 30-S subunits with MS2 RNA. Apparently the two particles form a complex in which S1 is functionally protected against its antibody. Complex formation depends on elevated temperature, a suitable ionic environment and it is stimulated by the initiation factor IF-3. It does not depend on IF-1, IF-2 or fMet-tRNA. Thus ribosomes have the potential to recognize the messenger in the absence of fMet-tRNA. Protein S1 appears directly involved in this primary recognition reaction.