Crosslinking of chemically reactive A-U-G analogs to ribosomal proteins within initiation complexes.

A-U-G analogs, either reactive on their 5′ or their 3′ side, were employed in affinity labeling of the ribosomal A-U-G binding site. These experiments have been carried out such that the chemically reactive A-U-G analog became covalently bonded to ribosomal proteins only in the presence of fMet-tRNA_f^Met and initiation factors. Subsequent radioimmunodiffusion of A-U-G-labeled proteins identified proteins IF3, S1, S18, S21 and L11 as being in the neighborhood of the ribosomal codon binding site. A location of reactive sites of these proteins relative to the P or A site bound codon is, however, not clear.The A-U-G labeling results are quantitatively as well as qualitatively very different in the absence or presence of fMet-tRNA_f^Met. It is concluded, therefore, that fMet-tRNA_f^Met directs A-U-G into its final binding site. Streptomycin cannot release fMet-tRNA_f^Met from initiation complexes which contain irreversibly bound 5′- {4-(bromoacetamido)phenylphospho}-adenylyl-(3′–5′)-uridylyl-(3′–5′)-guanosine. This suggests that codon-anticodon interaction between A-U-G and fMet-tRNA_f^Met is still intact in the P site of the ribosome.     

Protein synthesis in rabbit reticulocytes: control of protein synthesis initiation by a met-tRNA Met f deacylase and peptide chain initiation factors

The 0.5M KCl wash of rabbit reticulocyte ribosomes (I fraction) catalyzes the deacylation of Met-tRNA_f^Met. Upon DEAE-cellulose column chromatography, the deacylase activity elutes with the 0.1M KCl wash of the column (f1) and is well-resolved from the peptide chain initiation factors (1–3). The deacylase activity is specific for Met-tRNA_f^Met (retic., $\text{E.}$$\text{coli}$). Other aminoacyl tRNAs tested including fMet-tRNA_f^Met (retic., $\text{E.}$$\text{coli}$), Phe-tRNA ($\text{E.}$$\text{coli}$), Val-tRNA (retic.), and Arg-tRNA (retic.) are completely resistant to the action of the deacylase. In the presence of the peptide chain initiation factor (IF1) and GTP, retic. Met-tRNA_f^Met forms the initiation complex Met-tRNA_f^Met:IF1:GTP (2), and in this ternary complex Met-tRNA_f^Met is not degraded by the deacylase. $\text{E.}$$\text{coli}$ Met-tRNA_f^Met binds to IF1 independent of GTP, and in this complex, this Met-tRNA_f^Met is degraded by the deacylase.Prior incubation of f1 with Met-tRNA_f^Met (retic.) strongly inhibited protein synthesis initiation, presumably due to deacylation of the initiator tRNA. This inhibition by f1 was completely prevented when Met-tRNA_f^Met (retic.) was pre-incubated with peptide chain initiation factors.     

Effect of formylation on the chromatographic behavior of methionyl transfer ribonucleic acid

The effect of formylation on the chromatographic behavior of Met-tRNA_f^Met on BD-cellulose has been investigated. Under conditions comparable to those routinely employed in analytical BD-cellulose chromatography, formylated Met-tRNA_f^Met was observed to elute at a significantly higher salt concentration than unformylated Met-tRNA_f^Met. Unformylated Met-tRNA_f^Met elutes well before Met-tRNA_m^Met, whereas fMet-tRNA_f^Met elutes slightly after Met-tRNA_m^Met; thus the net effect of formylation is an apparent inversion of the elution order of the isoaccepting methionyl tRNA species, tRNA_f^Met and tRNA_m^Met. Although aminoacylated tRNA_f^Met and tRNA_m^Met elute slightly later than their respective unacylated forms, aminoacylation alone does not produce the inverted elution order observed upon formylation of Met-tRNA_f^Met.     

Identification of a protein at the ribosomal donor-site by affinity labeling

p-nitrophenylcarbamyl-methionyl-tRNA_f^Met is shown to act as an analogue of fMet-tRNA_f^Met in initiation complex formation. It binds to E. coli ribosomes in the presence of initiation factors and R 17-RNA as messenger. Covalent bond formation occurs in the complex between the Met-tRNA_f^Met derivative and protein of the 50 S ribosomal subunit. The protein labeled predominantly in the reaction has been identified as L 27 indicating that this protein is located at the donor-site of the ribosome.     

Yeast AEP3p Is an Accessory Factor in Initiation of Mitochondrial Translation

Initiation of protein synthesis in mitochondria and chloroplasts normally uses a formylated initiator methionyl-tRNA (fMet-tRNA_f^Met). However, mitochondrial protein synthesis in Saccharomyces cerevisiae can initiate with nonformylated Met-tRNA_f^Met, as demonstrated in yeast mutants in which the nuclear gene encoding mitochondrial methionyl-tRNA formyltransferase (FMT1) has been deleted. The role of formylation of the initiator tRNA is not known, but in vitro formylation increases binding of Met-tRNA_f^Met to translation initiation factor 2 (IF2). We hypothesize the existence of an accessory factor that assists mitochondrial IF2 (mIF2) in utilizing unformylated Met-tRNA_f^Met. This accessory factor might be unnecessary when formylated Met-tRNA_f^Met is present but becomes essential when only the unformylated species are available. Using a synthetic petite genetic screen in yeast, we identified a mutation in the AEP3 gene that caused a synthetic respiratory-defective phenotype together with Δfmt1. The same aep3 mutation also caused a synthetic respiratory defect in cells lacking formylated Met-tRNA_f^Met due to loss of the MIS1 gene that encodes the mitochondrial C₁-tetrahydrofolate synthase. The AEP3 gene encodes a peripheral mitochondrial inner membrane protein that stabilizes mitochondrially encoded ATP6/8 mRNA. Here we show that the AEP3 protein (Aep3p) physically interacts with yeast mIF2 both in vitro and in vivo and promotes the binding of unformylated initiator tRNA to yeast mIF2. We propose that Aep3p functions as an accessory initiation factor in mitochondrial protein synthesis.     

Thermodynamic Characterization of ppGpp Binding to EF-G or IF2 and of Initiator tRNA Binding to Free IF2 in the Presence of GDP, GTP, or ppGpp

In addition to their natural substrates GDP and GTP, the bacterial translational GTPases initiation factor (IF) 2 and elongation factor G (EF-G) interact with the alarmone molecule guanosine tetraphosphate (ppGpp), which leads to GTPase inhibition. We have used isothermal titration calorimetry to determine the affinities of ppGpp for IF2 and EF-G at a temperature interval of 5-25 °C. We find that ppGpp has a higher affinity for IF2 than for EF-G (1.7-2.8 μM K_dversus 9.1-13.9 μM K_d at 10-25 °C), suggesting that during stringent response in vivo, IF2 is more responsive to ppGpp than to EF-G. We investigated the effects of ppGpp, GDP, and GTP on IF2 interactions with fMet-tRNA^fMet demonstrating that IF2 binds to initiator tRNA with submicromolar K_d and that affinity is altered by the G nucleotides only slightly. This—in conjunction with earlier reports on IF2 interactions with fMet-tRNA^fMet in the context of the 30S initiation complex, where ppGpp was suggested to strongly inhibit fMet-tRNA^fMet binding and GTP was suggested to strongly promote fMet-tRNA^fMet binding—sheds new light on the mechanisms of the G-nucleotide-regulated fMet-tRNA^fMet selection.     

Recognition of altered E. coli formylmethionine transfer RNA by bacterial T factor

Treatment of $\text{E.}\text{coli}$ formylmethionine tRNA with sodium bisulfite produces six C → U base changes in the tRNA structure. Four of these modifications have no effect on the ability of tRNA_f^Met to be aminoacylated or formylated. Prior to bisulfite treatment, Met-tRNA_f^Met is not able to form a ternary complex with bacterial T factor and GTP, as measured by Sephadex G-50 gel filtration. After bisulfite treatment, a large portion of the modified tRNA is bound as T-GTP-Met-tRNA_f^Met. Formylation of bisulfite-modified Met-tRNA_f^Met completely eliminates T factor binding. Unmodified tRNA_f^Met is unique among the tRNAs sequenced to date in having a non-hydrogen-bonded base at the 5′ terminus. Bisulfite-catalyzed conversion of this unpaired C₁ to U₁ results in formation of a normal U₁-A₇₃ base pair at the end of the acceptor stem. It is likely that this structural alteration is responsible for the recognition of bisulfite-modified Met-tRNA_f^Met by T factor.     

Puromycin binding to the donor (P-) site of Escherichia coli ribosomes

Puromycin inhibits the interaction of peptidyl-tRNA analogues AcPhe-tRNA_ox-red^Phe, AcPhe-tRNA^Phe and fMet-tRNA_f^Met with the donor (P-) site of Escherichia coli ribosomes. affects almost equally both the rate of the binding and the equilibrium of the system. This means that the effect is due to direct competition for the P-site, but not due to the indirect influence via the acceptor (A-) site. The inhibition was observed also in 30 S ribosomal subunits, therefore the puromycin binding site is situated far from the peptidyl transferase center. Quantitative measurements show that the affinity of puromycin for its new ribosomal binding site is similar to its affinity for the acceptor site of the peptidyl transferase center.     

Isolation and characterization of two forms of Met-tRNAf deacylase from rabbit reticulocyte ribosomes

We have separated and purified two forms of Met-tRNA_f deacylase (or two separate enzymes), an activity that mediates in part the suppression of polypeptide chain initiation that occurs in heme deficiency or with double-stranded RNA, 1000-fold from the 0.5 M KCl wash of rabbit reticulocyte ribosomes. Deacylase I is a minor activity with an S_20,w of 5.9, D_20,w of 4.9 and M_r of 110 000, while deacylase II is the major activity with an S_20,w of 3.3, D_20,w of 7.1 and M_r of 43 000. Both convert crude reticulocyte or pure yeast, wheat germ, and E. coli [³⁵S]Met-tRNA_f to [³⁵S]methionine and tRNA^Met_f and have no effect on reticulocyte [³⁵S]fMet-tRNA_f, [³H]Ala-tRNA or [³H]Lys-tRNA. However, while deacylase I has similar activity throughout the pH range of 6.1–8.1, deacylase II has a sharp pH optimum at 7.9 and is almost completely inactive at 6.1. In addition, deacylase II shows a much greater affinity for pure Met-tRNA_f than deacylase I (K_m of 1.5–3 nM vs. 100 nM), and, while deacylase II is selectively inhibited by tRNA^Met_f, deacylase I is inhibited similarly by any added tRNA.     

Initiation of mammalian protein synthesis: Dynamic properties of the assembly process in vitro

Binding of the Met-tRNA^Met_f·eIF-2 GTP complex to the 40 S ribosomal subunit is the first step in initiation of eukaryotic protein synthesis. The extent of binding and the stability of the complex are enhanced by initiation factors eIF-3 and eIF-4C, AUG and elevated magnesium concentration. The reversibility of reaction steps occurring during the assembly of the initiation complex is measured as the rate of Met-tRNA^Met_f exchange in the initiation complex and its intermediates. This rate progressively decreases and Met-tRNA^Met_f binding becomes irreversible upon binding of mRNA. The association of the 40 S Met-tRNA^Met_f mRNA initiation complex with the 60 S ribosomal subunit is again reversible as long as elongation does not occur.     

Protein synthesis in rabbit reticulocytes. XIII. Lack of mRNA (poly r (A)) binding activity in highly purified EIF-1.

Met-tRNA_f^Met binding factor (EIF-1) has been purified more than 100 fold over crude high salt (0.5 M KCl) ribosomal wash. The purified factor binds 2 nmoles Met-tRNA_f^Met per mg protein and shows very little poly r(A) binding activity. Crude ribosomal high salt wash possesses significant amounts of poly r(A) binding activity and also binds to other RNAs. The bulk of this unspecific RNA binding protein is separated from EIF-1 by DEAE-cellulose chromatography.     

Two forms of methionyl-transfer RNA synthetase from Mycobacterium smegmatis

Two methionyl-transfer RNA synthetases (A and B forms) have been isolated from $\text{Mycobacterium smegmatis}$. The homogeneous preparations of the enzymes showed 1500 fold increase in specific activity in aminoacylation of methionine specific tRNA. The A and B forms differed in their specificity of aminoacylation of tRNA_m^Met and tRNA_f^Met; enzyme B exhibited much higher specificity for tRNA_f^Met. The molecular activities of A and B enzymes for aminoacid and tRNA were identical. The turnover number for aminoacid was 27 fold greater than that for tRNA, while the Km values for tRNA were lower by a factor of 10⁶ as compared to the aminoacid. Both the enzymes catalysed ATP-pyrophosphate exchange reaction to the same extent.     

A critical role of water in the specific cleavage of the anticodon loop of some eukaryotic methionine initiator tRNAs

We have noticed that during a long storage and handling, the plant methionine initiator tRNA is spontaneously hydrolyzed within the anticodon loop at the C34-A35 phosphodiester bond. A literature search indicated that there is also the case for human initiator tRNA^Met but not for yeast tRNA^Met _i or E. coli tRNA^Met _f. All these tRNAs have an identical nucleotide sequence of the anticodon stems and loops with only one difference at position 33 within the loop. It means that cytosine 33 (C33) makes the anticodon loop of plant and human tRNA^Met _i susceptible to the specific cleavage reaction. Using crystallographic data of tRNA^Met _f of E. coli with U33, we modeled the anticodon loop of this tRNA with C33. We found that C33 within the anticodon loop creates a pocket that can accomodate a hydrogen bonded water molecule that acts as a general base and catalyzes a hydrolysis of C-A bond. We conclude that a single nucleotide change in the primary structure of tRNA^Met _i made changes in hydration pattern and readjustment in hydrogen bonding which lead to a cleavage of the phosphodiester bond.     

Association of a GDP binding activity with initiation factor eIF-2 from calf liver

A highly purified preparation of the eucaryotic initiation factor eIF-2 from calf liver which forms a ternary complex with GTP and Met-tRNA_f^Met also exhibits a potent GDP binding activity. The factor preparation specifically forms a binary complex with GDP, other ribonucleoside diphosphates and GTP are inactive. Evidence is presented indicating that the GTP-dependent Met-tRNA_f^Met binding and binary complex formation with GDP are mediated by the same protein which has an apparent molecular weight of 67,000 as judged by glycerol density gradient centrifugation.     

Role of GTP in the Positioning of Formylmethionyl-tRNA<Subscript>f</Subscript> on the <Emphasis Type="Italic">E. coli</Emphasis> Ribosome

FORMATION of the E. coli initiation complex between ribosomal subunits, natural messenger RNA and formyl-methionyl-tRNA_f (fMet-tRNA_f) requires the presence of initiation factors and GTP^1–3. In the binding reaction, GTP can be replaced by an analogue, guanylyl-5′-methylene-diphosphonate (GMP-PCP), but the complex does not then react with puro-mycin. Hydrolysis of GTP is therefore required for the formation of an active initiation complex able to carry out peptide bond formation⁴.     

Highly charged radioactive initiator methionyl transfer RNA from in vivo labeled HeLa cells

³⁵S-Labeled Met-tRNA_f^Met can be prepared from HeLa cells, for studies of translation in vitro, with both a high degree of charging and a relatively high specific radioactivity. HeLa cells are labeled with [³⁵S]methionine in vivo, in the presence of cycloheximide to reduce translation. Their cytoplasmic RNA is then isolated by phenol extraction and subjected to cellulose ion-exchange chromatography in order to partially purify labeled Met-tRNA_f^Met and resolve it from Met-tRNA_m^Met.     

Transfer of methionyl residues by leucyl,phenylalanyl-tRNA-protein transferase

Leucyl, phenylalanyl-tRNA-protein transferase also catalyzes transfer of methionyl residues as indicated by (i) copurification over a 1000-fold range of transfer activities for all three amino acids and (ii) loss of methionyl transfer activity in a mutant of $\text{E.}\text{coli}$ lacking the transferase and reappearance of this activity in a transferase revertant. The purified enzyme was found to use Met-tRNA_m^Met in preference to Met-tRNA_f^Met as donor substrate. Peptides containing a basic amino acid at the NH₂-terminus functioned as acceptors for the transfer of methionyl residues.     

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.     

Directional transition from initiation to elongation in bacterial translation

The transition of the 30S initiation complex (IC) to the translating 70S ribosome after 50S subunit joining provides an important checkpoint for mRNA selection during translation in bacteria. Here, we study the timing and control of reactions that occur during 70S IC formation by rapid kinetic techniques, using a toolbox of fluorescence-labeled translation components. We present a kinetic model based on global fitting of time courses obtained with eight different reporters at increasing concentrations of 50S subunits. IF1 and IF3 together affect the kinetics of subunit joining, but do not alter the elemental rates of subsequent steps of 70S IC maturation. After 50S subunit joining, IF2-dependent reactions take place independent of the presence of IF1 or IF3. GTP hydrolysis triggers the efficient dissociation of fMet-tRNA^fMet from IF2 and promotes the dissociation of IF2 and IF1 from the 70S IC, but does not affect IF3. The presence of non-hydrolyzable GTP analogs shifts the equilibrium towards a stable 70S–mRNA–IF1–IF2–fMet-tRNA^fMet complex. Our kinetic analysis reveals the molecular choreography of the late stages in translation initiation.