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.     

Initiation factor 3 requirement for the formation of initiation complexes with synthetic oligonucleotides

Initiation factor IF-3 is required for the poly (U)-directed binding of N-acetyl-Phe-tRNA to 70S ribosomes as well as for the binding of fMet-tRNA directed by poly (U,G), AUG, and bacteriophage f₂ RNA. The formation of the 70S initiation complex is dependent upon IF-2 and is stimulated by IF-1. The requirement for IF-3 is not alleviated by high concentrations of the synthetic templates.     

The effects of initiation factor 3 on the formation of 30S initiation complexes with synthetic and natural messengers

Initiation factor IF-3 is required for the binding of fMet-tRNA to 70S ribosomes directed by AUG, poly (U,G), f₂RNA and T₄ late RNA as well as for the binding of acPhe-tRNA directed by poly (U). In contrast, IF-3 is not required for the binding of the initiator aminoacyl-tRNAs to isolated 30S subunits directed by the synthetic messengers, but is required for maximal formation of initiation complexes with natural messengers. These data indicate that with synthetic messengers the sole function of IF-3 is to dissociate the 70S ribosomes into subunits, whereas with natural messengers IF-3 is required not only for dissociation of the ribosomes but also for the binding of the messenger to the 30S subunit.     

Resistance of bacterial protein synthesis to double-stranded RNA

Double-stranded RNA fails to inhibit the formation of translation initiation complexes on R17 bacteriophage RNA, overall synthesis of R17 proteins, or the ability of bacterial initiation factor IF-3 to prevent the association of 30S and 50S ribosomal subunits into single ribosomes. Yet, IF-3 can form complexes with double-stranded RNA. However, IF-3 binds to double-stranded RNA with lower apparent affinity than to either R17 RNA or 30S ribosomal subunits; this may explain the resistance of bacterial protein synthesis to double-stranded RNA.     

Participation of initiation factor IF-3 in the binding of AcPhe-tRNA to the 30S ribosomal subunit

Initiation factor IF-3 is required in addition to IF-1 and IF-2 for maximal initial rate of poly(U)-directed binding of AcPhe-tRNA to 30S ribosomal subunits of $\text{E. coli}$. Incubation periods longer than 10 sec, by which time the reaction is virtually over, progressively obscure the requirement for IF-3 in AcPhe-tRNA binding. IF-3 also stimulates the poly(A, G, U)-directed binding of fMet-tRNA to the 30S ribosomal subunit, but in this case, significant stimulation can still be observed even with extended incubation. These results indicate that IF-3 functions similarly in the translation of synthetic mRNA, as it does with natural mRNA, participating in ribosome dissociation and in the formation of the initiation complex from the 30S ribosomal subunit.     

On the role of protein S4 N-terminal residues 1 through 30 in 30S ribosome function.

30S ribosomal protein S4 contains a single cysteine residue at position 31. We have selectively cleaved the peptide bond adjacent to this residue using the reagent 2-nitro-5-thiocyanobenzoic acid. The two resultant fragments were purified. The smaller S4-fragment (1-30) was found to be incapable of interacting with 16S RNA directly. This fragment also is not incorporated into a particle reconstituted from 16S RNA and 20 purified proteins with S4 missing. In contrast, the large S4-fragment (31-203) appears to be fully functional in ribosome assembly. Replacement of S4 with this fragment in the reconstitution reaction leads to a complete 30S ribosome containing all 30S proteins. This particle has a full capacity to bind poly U but has lost all activity for poly U directed phe-tRNA binding. We therefore propose that the N-terminus of protein S4 is not critical for ribosome assembly but is essential for tRNA binding.     

The mechanism of action of initiaton factor 3 in protein synthesis,I. Studies on ribosomes crosslinked with dimethylsuberimidate

The mechanism of action of chain initiation factor 3 in translation was examined by using $\text{E. coli}$ 70S ribosomes which were covalently crosslinked with dimethylsuberimidate. Crosslinked ribosomes were inactive in AUG-dependent fMet-tRNA binding, and were not stimulated by IF-3 in poly(U) translation. IF-3 is known to be required for maximal rates of amino acid incorporation with synthetic polynucleotides at 18 mM Mg²⁺. A direct interaction of IF-3 with 70S ribosomes was demonstrated by crosslinking ¹⁴C-labeled IF-3 to 70S ribosomes. The labeled factor was also crosslinked to 30S and 50S ribosomal subunits. A model is presented proposing the mechanism of action of IF-3 on 70S ribosomes.     

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.     

A single-stranded nucleic acid-binding protein from Artemia salina. I. Purification and characterization

A protein that binds tightly to single-stranded but not to double-strained nucleic acids has been purified to homogeneity from a high salt wash of ribosomes from cryptobiotic Artemia saline gastrulae. The protein, designated HD40 to indicate a helix-destabilizing protein with a molecular weight of 40,000, is present in the high-salt ribosomal wash at a level of about 2 molecules per 80 S ribosome. The protein is monomeric at salt concentrations from 0.01 to 0.5 M and has an alpha-helix content of approximately 15%. The amino acid composition of HD40 is characterized by a high glycine content (19.5 mol%), the absence of cysteine, and the presence of the unusual amino acid dimethylarginine. The isolated protein binds preferentially to natural RNA over denatured DNA. HD40 inhibits protein synthesis directed by poly(rU) and by Artemia poly(A+) RNA in cell-free systems derived from Artemia and from wheat germ; inhibition is relieved by excess of mRNA. Single-stranded ribo- and deoxyribopolynucleotides are largely protected from degradation by nucleases when complexed with HD40.     

Aurintricarboxylic acid, a preferential inhibitor of initiation of protein synthesis

The effect of aurintricarboxylic acid (ATA) was tested on various aspects of protein synthesis directed by the natural messenger ribonucleic acid (RNA) isolated from R17 RNA bacteriophage. The effects of various levels of ATA (up to 1,000 mum) were tested on overall protein synthesis as well as on binding of messenger RNA and fmet-transfer RNA to ribosomes and on the addition of the 50S ribosome to the 30S ribosome initiation complex. All of the reactions tested could be inhibited by ATA, and none of the tested steps was found to be uniquely sensitive to it. However, the total initiation steps were more sensitive to this chemical than the elongation steps; thus, under appropriate conditions this chemical can preferentially inhibit initiation while elongation of the polypeptide chain is not appreciably affected.     

The binding of dansylated initiation factor 3 to the 30-S subunit of Escherichia coli: a fluorimetric and biochemical study

Initiation factor 3 (IF-3) has been labelled using dansyl (1-dimethylaminonaphthalene-5-sulphonyl) chloride under conditions designed to preserve the biological activity of the factor. The sites of modification of the IF-3 have been determined by peptide mapping and sequencing: about six lysines (73, 80, 91, 96, 99, 112) react in various proportions. However, if an IF-3 molecule bears more than one dansyl group on average then its activity is lost. The extent of incorporation is proportional to the amount of dansyl chloride used in the reaction. Spectrofluorimetric analysis of the dansyl-IF-3 leads to the following conclusions. (a) The motion of the dansyl label does not change greatly upon binding to the 30-S subunit. (b) The label is not close enough to any tryptophan group of the ribosome in the 30-S-subunit . IF-3 complex to allow energy transfer. (c) The IF-3 chain is folded so as to bring the tyrosine groups close to the dansyl-binding sites. (d) The stoichiometry of the binding of IF-3 to 30-S ribosomal subunits is close to 1:1 and the binding constant is 2 x 10(7) M-1. IF-3 also binds non-covalently the fluorescent indicator 8-anilinonaphthalene 1-sulphonate (ANS) with an apparent binding constant of approximately 8000 M-1. An interaction between ANS and poly(A-U-G), both bound to IF-3, was demonstrated. Combining these results with those for dansyl-IF-3 leads to a model for the interaction between IF-3 and the 30-S subunit involving a combination of 'hydrophobic' and electrostatic attraction between the factor and ribosomal RNA.     

Functional heterogeneity of the 30S ribosomal subunit of E. coli

Summary When 30S ribosomal subunits from E. coli are incubated with poly U, two separable components are recovered by zonal centrifugation of the incubation mixture. The faster sedimenting component is an aggregate of 30S subunits and poly U, while the slower one corresponds to the 30S ribosomal subunit. One ribosomal protein, protein 30S-1 is predominantly present in the faster sedimenting aggregate. The amount of poly U-30S subunit complex formed in the incubation mixture is limited by the amount of protein 30S-1 present. Consequently the number of ribosomal binding sites available for Phe-tRNA is limited in a similar fashion by the presence of protein 30S-1. When 30S ribosomal subunits are reconstituted in the absence of protein 30S-1, very little poly U or Phe-tRNA binding capacity is manifest under our assay conditions. We conclude that protein 30S-1 is required for maximum capacity of ribosomes to bind mRNA. Since this protein is present only on a fraction of the ribosome at any one time, it must exchange from one ribosome to another during protein synthesis.Abbreviations Poly U (polyuridylic acid) - t-RNA (transfer ribonucleic acid) - mRNA (messenger ribonucleic acid) - Phe (phenylanine) - A₂₆₀ unit (unit of material which gives an optical density of 1.0 at 260 nm in a one centimeter optical path)     

Functional heterogeneity of the 30 S ribosomal subunit of Escherichia coli. 3. Requirement of protein S1 for translation

Poly(U)-dependent polyphenylalanine synthesis is completely dependent on the presence of ribosomal protein S1. Polysomes generated under the direction of poly(U) contain approximately one molecule of S1 per ribosome. Isolation of 30 S ribosomes from poly(U)-generated polysomes by a procedure requiring a low concentration of Mg²⁺ (0·25 mM) results in loss of S1. S1 is probably also required for the phage RNA-dependent binding of formylmethionyl-tRNA. The data are discussed in relation to current concepts of the functional aspects of ribosome heterogeneity.     

Impaired initiation complex formation on ribosomes treated with colicin E3.

Ribosomes treated with colicin E3 are impaired, when tested with phage R17RNA as messenger, in amino acid incorporation, binding of fMet-tRNA, and formation of fMet-puromycin. Studies with subunits showed that formation of the 30S initiation complex is inhibited. The results are consistent with the recent findings that the “E3-fragment” (3′ end of 16S RNA) binds to 30S protein S1, and that both are involved in initiation on natural messenger.     

Spatial organization of template polynucleotides on the ribosome determined by fluorescence methods.

The spatial organization of template polynucleotides on the ribosome and the dynamics of their interaction with 30 S subunits have been studied by fluorescence spectroscopy. The topography of the mRNA in the ribosome has been determined using singlet-singlet energy transfer. This method has allowed us to estimate distances between donors and acceptors of energy which have been linked to the terminal residues of template polynucleotides (poly- and oligo(U) and oligo(A] and 16 S RNA or to SH-groups of ribosomal proteins S1 and S8. The dynamics of mRNA-ribosome interaction have been investigated by the fluorescence stopped-flow technique. It has been shown that the binding to the 30 S subunit of poly(U) with length much shorter (16 nucleotides) than that covered by the ribosome is greatly enhanced by protein S1. However, the final position of oligo(U)16 on the 30 S subunit, which probably includes the ribosomal decoding site, proves to be quite different from that occupied by oligo(U)16 on a free protein S1. Interaction of oligo- and poly(U) with the 30 S subunit occurs in at least two steps: the first one is as fast as the interaction of poly(U) with free S1, whereas the second step represents a first-order reaction. Therefore, the second step may reflect some rearrangement of the template in the ribosome after its primary binding. It is suggested that protein S1 in some cases may fulfill the role of a transient binding site for mRNA in the course of its interaction with the ribosome. The general shape of the template in the mRNA binding region of the ribosome has been studied using various synthetic ribopolynucleotides and has been shown to be similar. It can be represented by a loop(s) or "U-turn(s)". On the basis of estimation of distances from the ends of poly(U) to some well-localized points on the 30 S ribosomal surface, a tentative model of mRNA path through the ribosome is proposed.     

Studies on the role of amino acid residues 31 through 46 of ribosomal protein S4 in the mechanism of 30 S ribosome assembly.

We have described previously the isolation of a large fragment of 30 S ribosomal protein S4 (Changchien &; Craven, 1976). This S4-fragment is produced by the digestion of the S4–16S RNA complex with trypsin and it retains a full capacity to associate specifically with 16S RNA. It was also demonstrated that the S4-fragment has approximately 46 amino acid residues missing from the N-terminus and an intact C-terminus (also shown by Newberry et al., 1977). Preliminary experiments with this S4-fragment indicated that it could not fully replace the intact protein S4 in the process of 30 S ribosome assembly in vitro.We have also recently reported (Changchien et al., 1978) the preparation of a new fragment of protein S4 which has only 30 amino acid residues cleaved from the N-terminus. This was achieved by the use of the reagent 2-nitro-5-thiocyanobenzoic acid which selectively modifies the cysteine residue at position 31 followed by a cleavage of the adjacent peptide bond.We have now fully characterized the capacity of these two fragments, S4-fragment (47–203) and S4-fragment(31–203), to participate in the 30 S ribosome assembly process in vitro. Using 2-dimensional polyacrylamide gel electrophoresis, we find that when S4-fragment(47–203) is a component of the in vitro assembly reaction, proteins S1, S2, S10, S18 and S21 fail to become incorporated into the final particle. In contrast, S4-fragment(31–203) appears to participate in the reconstitution reaction without impairment allowing the complete incorporation of all 20 proteins of the 30 S subunit. The resultant particle, containing the S4-fragment (31–203), is fully active in the binding of poly(U), but is completely inactive for non-enzymatic poly(U)-directed binding of Phe-tRNA (Changchien et al., 1978). These results suggest that residues 1 through 30 of protein S4 are not involved in the assembly of the 30 S ribosome, but are required for the proper construction of the tRNA binding site. In addition residues 31 through 46 must be somehow critically important for the assembly of proteins S1, S2, S10, S18 and S21. We present evidence to show that the absence of residues 31 through 46 of protein S4 prevents a conformational change in the structure of 16 S RNA which normally accompanies the RI to RI transition and that this results in the inability of these proteins to participate in the assembly process.     

Chain initiation factor 3 crosslinks to E. coli 30S and 50S ribosomal subunits and alters the UV absorbance spectrum of 70S ribosomes

We report a direct procedure to determine the proteins near the IF-3 binding site in purified 30S and 50S ribosomal subunits. This procedure introduces only limited numbers of cleavable crosslinks between IF-3 and its nearest neighbors. The cleavable crosslinking reagent, 2-iminothiolane, was used to crosslink IF-3 in place to both 30S and 50S subunits. Ribosomal proteins S9/S11, S12, L2, L5 and L17 were found, by this approach, to be in close proximity to the factor in purified IF-3-subunit complexes. In addition, IF-3 was shown to alter the ultraviolet absorbance spectrum of E. coli 70S ribosomes at 10 mM Mg2+. The magnitude of the observed difference spectrum at a constant IF-3/ribosome ratio of 1.0, is linearly dependent upon ribosome concentration over the range 5 nM - 55 nM. Titration experiments indicated that the observed effect is maximal at an IF-3/ribosome ratio of approximately 1.0. These results are taken to indicate a conformational change in the 70S ribosome induced by IF-3.     

Enrichment of the poly (A) sequence and lack of enhancement of total RNA synthesis in cultured Xenopus hepatocytes by estradiol-17 beta

The effect of estradiol-17 beta on RNA synthesis and the amounts of total RNA and polyadenylic acid were determined in primary cultures of Xenopus laevis liver parenchymal cells. Results showed that estradiol did not alter the RNA content significantly; control cells contained 11.9 +/- 0.34 micrograms and estradiol-treated cells 12.4 +/- 0.17 micrograms per 10(6) cells on day 2 of estradiol treatment, and 22.0 +/- 0.61 micrograms and 24.0 +/- 1.09 micrograms on day 5. Hybridization with [3H]poly(U) revealed that estradiol increased the poly(A) content about 1.2-fold more than in the controls on day 2 and 1.6-fold on day 5 of estradiol treatment. The actual rate of RNA synthesis was estimated from analyses of the kinetics of [3H]adenosine incorporation into the ATP pool and into RNA. The initial rate of incorporation of ATP into RNA on day 5 of estradiol treatment was 29.38 pmol/min/10(6) cells and the rate of the controls of 29.35. Subsequent accumulation kinetics of [3H]adenosine into RNA showed no difference between estradiol and the control cells. Thus, estradiol did not alter the rate of total RNA synthesis and the total RNA content significantly, but it did increase the poly(A) content.     

Polyamines in bacteriophage R17 and its RNA.

Bacteriophage R17 and its RNA were found to contain significant amounts of spermidine but not of putrescine. When isolated at 0.01 M KCl, up to 1,000 molecules of spermidine were associated with the virion. The phage RNA isolated with phenol plus sodium lauryl sulfate contained approximately 70 to 90 molecules of spermidine. The association appeared to be ionic because the bound spermidine could be dissociated by KCl, MgCl2, or both. Effects of polyamines on in vitro translation were studied using both poly(U) and phage R17-RNA as mRNA. Addition of spermidine to the system at suboptimal concentrations of Mg2+ resulted in marked stimulations of the rate of protein synthesis. Putrescine alone had no effect but stimulated the incorporation in the presence of suboptimal concentrations of spermidine plus Mg2+. The isolated amino acid-incorporating system contained suboptimal soluble and bound polyamines. A comparison of incorporation was made in this system using R17-RNA with and without bound spermidine. No effects of these bound cations were detected on the rate or extent of incorporation of valine. The ratio of incorporation of histidine (present in non-coat proteins) to valine (total protein) revealed little difference as a functions of cation in the system or a function of the spermidine present in R17-RNA.