Interferon treatment of Ehrlich ascites tumor cells: effects on exogenous mRNA translation and tRNA inactivation in the cell extract.

We reported earlier that in cell extracts that were prepared from interferon-treated Ehrlich ascites tumor cells and preincubated and passed through Sephadex G-25 (S60INT), the translation of exogenous mRNA (viral and host) was impaired and the impairment could be overcome to a large extent by adding a crude tRNA preparation from Ehrlich ascites tumor cells but not from Escherichia coli. We find now that the rate of inactivation of some tRNA's (especially those specific for leucine, lysine, and serine) but not those of many others is faster in S30INT than in corresponding extracts from control cells. This increased rate of tRNA inactivation may perhaps account for the need for added RNA to overcome at least partially the impairment of translation in S30INT. The relationship of the increased rate of tRNA inactivation to the antiviral effect of interferon is unclear. So far no significant difference has been detected in the amount of tRNA needed to overcome the impairment of encephalomyocarditis virus RNA translation in S30INT between tRNA from interferon-treated cells and tRNA from control cells. Futhermore, no difference was found in the rate of inactivation in S30INT between leucine-specific tRNA's from interferon-treated and from control cells. tRNA's specific for leucine and lysine were not inactivated (unless very slowly) during incubation under out conditions in an extract from interferon-treated (or from control) cells unless the extract had been passed through Sephadex G-25 or dialyzed. The translation fo exogenous mRNA was, however, impaired in an extract from interferon-treated cells that had not been passed through Sephadex G-25. This impairment was apparently not overcome by added tRNA.     

Release of the inhibition of messenger RNA translation in extracts of interferon-treated Ehrlich ascites tumor cells by added transfer RNA

In an extract of Ehrlich ascites tumor (EAT) cells which had been “preincubated” for 45 min to lower endogenous protein synthesis (S30_C) the translation of exogenous encephalomyocarditis (EMC) viral mRNA proceeds at a constant rate for over 90 min. In a similarly treated extract of interferon-treated EAT cells (S30_INT) the translation proceeds at a lower rate than in the S30_C for about 30 min and then stops. The impairment of the translation in the S30_INT is mediated by one or more inhibitors. After the cessation of translation the viral mRNA in the S30_INT is in large polysomes. The size of these changes little (if any) during a further 15 min incubation. The addition of mouse tRNA (but not ribosomal RNA or $\text{E. coli}$ tRNA) to the S30_INT after the cessation of viral mRNA translation results in the restart of translation at a rate close to that in the S30_C. This effect of tRNA is diminished by pactamycin, which inhibits peptide chain initiation but not elongation. These results indicate that addition of tRNA allows the elongation of incomplete peptide chains and the initiation of new chains. The need for added tRNA may be due to the fact that in S30_INT the amino acid acceptance of some of the endogenous tRNA species (but not of added tRNAs) is impaired. This impairment is pronounced for leucine and very slight, if any, for five other amino acids tested (i.e. isoleucine, methionine, phenylalanine, threonine, and valine).     

Interferon, double-stranded RNA and RNA degradation. Fractionation of the endonucleaseINT system into two macromolecular components; role of a small molecule in nuclease activation

We reported earlier that a) the incubation of an extract from interferon-treated Ehrlich ascites tumor cells with double-straded RNA and ATP results in the activation of an endonuclease and b) after the activation the double-stranded RNA and ATP can be degraded without impairing the activity of the endonuclease. We report now the separation and partial purification of two macromolecular components (DE1_INT and DE2_INT) involved in the process. Upon incubation with double-stranded RNA and ATP component DE1_INT generates a heat-stable product of low molecular weight (designated as nuclease activator). On incubation with the nuclease activator a latent nuclease in component DE2_INT is activated.     

Inhibition of protein synthesis directed by added viral and cellular messenger RNAs in extracts of interferon-treated Ehrlich ascites tumor cells. Location and dominance of the inhibitor(s)

Protein synthesis directed by exogenous (viral or cellular) messengers is impaired, but endogenous protein synthesis is not affected in an extract of interferon-treated Ehrlich ascites tumor cells (INT-extract). Protein synthesis directed by exogenous messengers is also impaired in a mixture of an INT-extract with an extract from control cells. This reveals that the impairment is due to one or more inhibitors in the INT-extract. The nondialyzability of the inhibitor(s) is probably an indication of large molecular size. In a not incubated INT-extract much of the inhibitory activity is in the high speed sediment fraction i.e., is presumably bound directly or indirectly to ribosomes. During incubation of the extract most of the inhibitory activity is released into the high speed supernatant fraction. The dose-response curve shows that in our conditions the translation of cellular messengers (from mouse L cells) is as sensitive to impairment by the inhibitor(s) as that of viral messengers (from reovirus or from encephalomyocarditis virus).     

Impairment of reovirus mRNA methylation in extracts of interferon-treated Ehrilich ascites tumor cells: further characteristics of the phenomenon.

We reported earlier that the methylation of unmethylated reovirus mRNA (reo mRNAU) by the cellular methylating enzymes is impaired in extracts of uninfected, interferon-treated Ehrilich ascites tumor cells (S30INT). We find now that after the methylation of reo mRNAU has stopped in S30INT, the RNA can be reisolated and further methylated in an extract of control cells (S30C). Thus the impairment of methylation in S30INT cannot be due to cleavage or irreversible inactivation of reo mRNAU. Freshly added reo mRNAU can be methylated in S30INT in which the methylation of previously added reo mRNAU has stopped. This indicates that the impairment is due to the depletion of S-adenosylme thionine (the methyl donor), the accumulation of S-adenosylhomocysteine (an inhibitor of methylation), or the irreversible inactivation of reo mRNAU. Freshly added reo mRNAU can be methylated in S30INT in which the methylation of previously added reo mRNAU has stopped. This indicates that the impairment is not due to the depletion of S-adenosylmethionine (the methyl donor), the accumulation of S-adenoxylhomocysteine (an inhibitor of methylation), or the irreversible inactivation of the methylating enzymes. It may be due, however, to the unavailability of reo mRNAU for methylation. The extent of the impairment of reo mRNAU methylation in S30INT decreases with an increasing concentration of reo mRNAU but is not affected by added poly (U), ribosomal RNA, or encephalomyocarditis virus RNA (an mRNA that is probably not capped or methylated at its 5' end). The methylation of reo mRNAU is also impaired in an extract from cells that have not been treated with interferon but with the interferon inducer poly(I) - poly(C). The inhibitor is apparently a macromolecule that is inactivated during incubation. It decreases the methylation at the 7 position of the 5' terminal guanylate residue. In vitro, the rate of reo mRNA synthesis by reovirus cores in the presence of S30INT is the same as in the presence of S30C. However, the methylation of the de novo synthesized reo mRNA by the core-associated methylating enzyme(s) in vitro is inhibited by S30INT but not by S30C. The relevance of these phenomena to the inhibition of reovirus replication in interferon-treated cells remains to be established.     

Binding of aminoacyl-tRNA to rat liver ribosomal proteins

Rat liver ribosome treatment with ethanol and 1 M NH₄Cl releases some 31–33 ribosomal proteins. This split protein fraction binds Phe-tRNA, Ac-Phe-tRNA, Met-tRNA_M and f-Met-tRNA_F in the absence of K⁺ and Mg⁺⁺ ions. When the split protein fraction is passed through Sephadex G-100 only six proteins are retained in the column: S10, S14, S15, S19, L35, and L36. The aminoacyl-tRNA binding activity of this protein fraction retained in the Sephadex G-100 column is similar to that of the total split protein fraction, suggesting that the above six proteins, or only some of them, are involved in the binding reaction.     

Simultaneous microdetermination of homovanillic acid and 5-hydroxyindoleacetic acid in brain tissue using Sephadex G-10 and QAE-Sephadex A-25

Homovanillic acid (HVA) and 5-hydroxyindoleacetic acid (5-HIAA) in animal brains were simultaneously purified by two steps of column chromatography on Sephadex G-10 and QAE-Sephadex A-25. Perchloric acid extracts of brain tissue were directly passed through a column of Sephadex G-10. The gel retained both HVA and 5-HIAA, thereby separating them from Cl0^?₄ which interferes with subsequent purification process and from endogenous substances which give blank fluorescence. HVA was loosely adsorbed on the gel and was easily desorbed with dilute acetic acid. This effluent was successively passed onto a column of QAE-Sephadex A-25 placed beneath the G-10 column and the adsorbed HVA was eluted with 0.1 M Na₂HPO₄. The 5-HIAA remaining on the Sephadex G-10 without being desorbed by acetic acid was eluted with dilute ammonia. The recovery of both acid metabolites by this column procedure was more than 90%. Thus, it is possible to determine the levels of HVA and 5-HIAA in single brains of small rodents.     

Relationship between changes in the translational apparatus and actinomycin production in Streptomyces antibioticus.

As previously reported (G. H. Jones, 1975), transfer ribonucleic acids (tRNA's) and ribosomes from actinomycin-producing cultures of Streptomyces antibioticus show a decreased ability to function in aminoacylation and translation as compared with the corresponding components from younger cells. Further, specific changes in the isoacceptor patterns are revealed when tRNA's from actinomycin-producing cells are compared with those of younger cells by reverse- phase column chromatography. A specific glycyl-tRNA species is eliminated from the reverse-phase profile of tRNA's from actinomycin-producing S. antibioticus cells as compared with younger cells. Changes in isoacceptor patterns were also observed for the amino acids methionine, valine, phenylalanine, and leucine. Actinomycin synthesis was inhibited by growing S. antibioticus cells in the presence of alpha-methyl-DL-tryptophan. Inhibition of actinomycin synthesis reversed the changes in tRNA observed in normally grown control cultures, although it had no demonstrable effect on the growth of the cells. Thus, tRNA from 48-h-old, alpha-methyl-tryptophan-grown cells had amino acid acceptor activity that was equal to or greater than that of tRNA from 12-h-old, normally grown cells. Similarly, the reverse-phase chromatographic pattern for glycyl-tRNA's from 48-h-old, alpha-methyl-tryptophan-grown cells was identical to that of the glycyl-tRNA's from 12-h-old, normally grown cells. In contrast, the ability of ribosomes from 48-h-old, alpha-methyl-tryptophan-grown cells to function in polypeptide synthesis in vitro was essentially identical to that of 48-h-old, normally grown cells. Ribosomes from 12-h-old, normally grown cells were severalfold more active in in vitro polypeptide synthesis.     

Isopentenyl pyrophosphate isomerase and prenyltransferase from tomato fruit plastids

Isopentenyl pyrophosphate isomerase has been isolated from an extract of tomato fruit plastids and purified 245-fold by fractionation with ammonium sulfate, gel filtration on Bio-Gel A 1.5m, ion-exchange chromatography on DEAE-cellulose, gel filtration on Sephadex G-100, and chromatofocusing. Gel filtration on Sephadex G-100 separated the isopentenyl pyrophosphate isomerase from a prenyltransferase fraction that catalyzed the conversion of isopentenyl pyrophosphate to acid-labile compounds in the presence of dimethylallyl, geranyl, or farnesyl pyrophosphates. The molecular weights of the isopentenyl pyrophosphate isomerase and prenyltransferase were determined to be 34,000 and 64,000, respectively, by gel filtration on Sephadex G-100. The only cofactor required by either the isomerase or the prenyltransferase was a divalent cation, either Mg²⁺ or Mn²⁺. Isopentenyl pyrophosphate isomerase could also be totally inactivated by 1 × 10^?3m iodoacetamide, and this property was utilized in the assay of prenyltransferase activity in the presence of contaminating isomerase. The inactivation of isomerase by iodoacetamide is consistent with the stabilization of isopentenyl pyrophosphate isomerase by dithiothreitol. The K_m of isopentenyl pyrophosphate isomerase for isopentenyl pyrophosphate was found to be 5.7 × 10^?6.     

Oxidation of 4-thiouridine in intact Escherichia coli tRNAs.

Treatment of intact tRNAs from Escherichia coli B with mild oxidizing agents, such as KI-I₂, appears to quantitatively oxidize the 4-thiouridine present in these molecules to the disulfide form as judged by the loss of absorbance near 330 nm. Chromatography of these oxidized tRNAs on Sephadex G-75 did not reveal tRNA dimers or larger aggregates, suggesting intra- rather than intermolecular disulfide-bond formation. Enzymatic hydrolyses of both unlabeled and ³⁵S-labeled oxidized tRNAs followed by chromatography on columns of Sephadex G-25 indicated that 4-thiouridine did form covalent linkages with some component(s) in the tRNA that were reversible upon reduction. It was not clear whether 4-thiouridine formed disulfides only with itself, other sulfurcontaining nucleosides, or some non-sulfur-containing component. Data presented suggest that an earlier report on the isolation of 4-thiouridylate disulfide from oxidized tRNAs of E. coli was an artifact, resulting from oxidation of the thionucleotide during chromatography on Bio-Gel.     

Uptake and aminoacylation of exogenous Escherichia coli tRNA by mouse fibroblasts.

Mouse fibroblasts (L-cells) in suspension culture take up exogenous $\text{Escherichia coli}$ tRNA in the presence of DEAE-Dextran. Tritium-labeled formylmethionine tRNA and valine tRNA are both taken up at very low levels. Tritium activity is associated solely with 4S material as judged by chromatography of cell extracts on Sephadex G-100. Further analysis of this material on a dihydroxyboryl-substituted cellulose indicates that a small portion of the tRNA taken up is acylated by the L-cells.     

Preparation and characterization of eukaryotic initiation factor EIF-3. Formation of binary (EIF-3-Met-tRNAf) and ternary (EIF-3-Met-tRNAf-GTP) complexes.

The 133,000 X g supernatant fraction prepared from ascites cells in 20 mM KCl (low CKl supernatant) contained the initiation factors EIF-1 and EIF-2 (and the elongation factore EF-1 and EF-2) but lacked EIF-3; thus, low KCl supernatant could be used to assay for EIF-3. EIF-3 was prepared from a crude initiation factor perparation (a 250 mM KCl extract of ascites cell ribosomes precipitated with 70% saturated ammonium sulfate) by chromatography on DEAE-Sephadex A-50 and hydroxylapatite. The EIF-O had no detectable EIF-1 and little or no EIF-2. Factor EIF-3 was required fro translation of encephalomyocarditis virus RNA. The molecular weight of EIF-3 was estimated by Sephadex G-200 filtration to be 139,000; the sedimentation coefficient was calculated to be about 5.8. EIF-3 formed a binary complex specifically with the initiator tRNA, Met-tRNAf, and if GTP was present the factor formed a ternary complex (EIF-3-Met-tRNAf-GTP). The EIF-3 preparation had no methionyl-tRNA synthetase activity to account for binding. Complex-formation was with eukaryotic Met-tRNAf and no other aminoacyl-tRNA. The binary and ternary complexes were retained quantitatively on Millipore filters (which was the most convenient assay), but they could also be demonstrated by filtration through Sephadex G-100 or by glycerol gradient centrifugation. GTP increased the rate, the amount, and the stability of complex formed; the ration of GTP to Met-tRNAf in the ternary complex appeared to be 1. The binary and the ternary complexes transferred Met-tRNAf to the 40 S ribosomal subunits, but not to 60 S subparticles. The factor-dependent binding of Met-tRNAf to the 40 S subunit did not require mRNA (or GTP). In the presence of 60 S subunits, the initiator tRNA bound to 40 S subunits was not transferred to 80 S ribosomes even if mRNA was added--that reaction may require another initiation factor. Treatment of EIF-3 with N-ethylmaleimide led to loss of its activity in complex formation and in support of the translation of encephalomyocarditis virus RNA. In addition to forming the binary and ternary complexes, and supporting the translation of encephalomyocarditis virus RNA, EIF-3 also increases the number of free ribosomal subunits by either preventing their association or causing dissociation of 80 S couples.     

Preparation of Cells Permeable to Macromolecules by Treatment with Toluene: Studies of Transfer Ribonucleic Acid Nucleotidyltransferase

Transfer ribonucleic acid (tRNA) nucleotidyltransferase was studied after making cells permeable to macromolecules by treatment with toluene. The conditions of toluene treatment necessary for obtaining maximal activity were defined. Toluene treatment was most efficient when carried out for 5 min at 37 C at pH 9.0 on log-phase cells. No activity could be detected if cells were treated at 0 C, or in the presence of MgCl₂, or if the cells were in the stationary phase of growth. However, inclusion of lysozyme and ethylenediaminetetraacetic acid during the toluene treatment did render stationary phase cells permeable. The properties of tRNA nucleotidyltransferase from toluene-treated cells were essentially identical to those of purified enzyme with regard to pH optimum, specificity for nucleoside triphosphates and tRNA, and apparent K_m values for substrates. In addition to tRNA nucleotidyltransferase, a variety of other enzymes which incorporate adenosine 5′-triphosphate into acid-precipitable material could also be detected in toluene-treated cells. Centrifugation of cells treated with toluene revealed that tRNA nucleotidyltransferase leaked out of cells, whereas other activities remained associated with the cell pellets. Chromatography of the material extracted from toluene-treated cells on Sephadex G-100 indicated that toluene treatment selectively extracts lower molecular weight proteins. The usefulness of such a procedure as an initial step in purification of such enzymes, and its application to tRNA nucleotidyltransferase, is discussed.     

Irreversible inhibition of ribonucleotide reductase from Ehrlich tumor cells by a modulator analog

Periodate-oxidized ATP (ATP-PI) was prepared and studied as a modulator analog of ATP in the ribonucleotide reductase system from Ehrlich tumor cells. ATP-PI could not replace ATP as an activator of CDP reduction, but was found to be an effective inhibitor of both CDP and ADP reduction. The inhibition was time dependent with 1 μM ATP-PI causing 100% inhibition after 20 hrs. The inhibition was shown to be irreversible by the Ackermann-Potter plot and enzyme activity was not restored by passage of the ATP-PI-treated enzyme over a Sephadex G-25 column. ¹⁴C-ATP-PI eluted with the protein peak on Sephadex G-25 chromatography.     

Inhibition of Protein Synthesis in Cell-Free Systems from Interferon-Treated, Infected Cells: Further Characterization and Effect of Formylmethionyl-tRNA(F)

The translation of encephalomyocarditis virus (EMC) RNA is markedly inhibited in cell-free systems from interferon-treated, vaccinia virus-infected L-cells (10, 11). The polypeptide products synthesized in response to EMC RNA in cell-free systems from these and untreated infected cells have been analyzed by electrophoresis on polyacrylamide gels. Qualitatively, the same EMC-specific polypeptides were synthesized throughout. In experiments using preincubated microsomes from normal Krebs cells to assay cell sap from L-cells which had been exposed to interferon prior to infection, only the amount of the EMC-specific polypeptide products was reduced. This result suggests that there is an inhibition very early in translation in interferon-treated, infected cells. Initiation seems a priori the more attractive site for this inhibition, but an effect shortly after initiation cannot be excluded. With unfractionated cell-free systems from interferon-treated infected L-cells, however, there appeared to be an additional minor inhibitory effect on polypeptide chain elongation, in that the EMC-specific polypeptides synthesized showed not only a reduction in amount but also a bias towards lower molecular weight. The formylated methionyl initiator tRNA (Fmet-tRNA_F) was used as a further probe into the apparent effect on intiation. With this reagent we have confirmed that there is one major initiation site for the translation of EMC RNA in these cell-free systems. In addition, the results have shown that EMC-specific polypeptide chains initiated with Fmet escape the major interferon-mediated inhibition at or shortly after initiation.     

Macromolecular synthesis in Streptomyces antibioticus: in vitro systems for aminoacylation and translation from young and old cells.

In vitro systems for the aminoacylation of transfer ribonucleic acid (tRNA) and for polypeptide synthesis have been constructed from young (12-h cultures, not producing actinomycin) and old (48-h cultures, producing actinomycin) cells of Streptomyces antibioticus. When Escherichia coli aminoacyl-tRNA synthetases were used to acylate S. antibioticus tRNA's, it was observed that, per absorbance unit of tRNA, the tRNA's from 48-h cells had a lower ability to accept the amino acids, leucine, serine, pheynlalanine, methionine, and valine than did the tRNA's from 12-h cells. Individual differences were observed between aminoacyl-tRNA synthetases from 12-h cells and those from 48-h cells with respect to the rate and extent of aminoacylation of E. coli tRNA with the five amino acids listed above. In vitro systems for the synthesis of polyphenylalanine have been constructed from 12- and 48-h cells. Ribsomes and soluble enzymes from 12-h cells are more efficient than those from 48-h cells in supporting polyphenylalanine synthesis, and, although the activity of both systems can be stimulated by the addition of E. coli tRNA, the higher level of incorporation observed in the unstimulated 12-h system (ribosomes and soluble enzymes) is maintained. Indeed, the difference in capacity for polyphenylalanine synthesis between in vitro systems from 12- and 48-h cells is greater when the systems are maximally stimulated by E. coli tRNA. Cross-mixing experiments reveal that enzymes from 48-h cells support a slightly higher level of polyphenylalanine synthesis than enzymes from 12-h cells with ribosomes from either cell type, and that the ribosomes are the primary agents responsible for the decreased efficiency of the in vito system from 48-h cells are compared with that from 12-h cells. To determine whether ribosome-associated factors were responsible for the relative inefficiency of the ribosomes from 48-h cells in translation, salt-washed ribosomes from 12- and 48-h cells were examined for their abilities to catalyze polyphenylalanine synthesis. Even after salt washing, ribosomes from 12-h cells were about five times higher in specific activity (counts per minute of polyphenylalanine synthesized per absorbance at 260 nm of ribosomes) than equivalent amounts of ribosomes from 48-h cells. Analysis of the proteins of salt-washed ribosomes of the two cell types by acrylamide gel electrophoresis suggests that the relative amounts of individual proteins present on ribosomes from 12-h cells are different from the amounts present on ribosomes from 48-h cells. These results are discussed in terms of the regulation of translation in S. antibioticus.     

Reactions at the 3' terminus of transfer ribonucleic acid. IX. tRNA nucleotidyltransferase activity in bacteriophage T4-infected Escherichia coli

There was no detectable increase in tRNA nucleotidyltransferase activity upon infection of $\text{Escherichia coli}$ A19 with bacteriophage T4. Three mutant strains which contained low levels of tRNA nucleotidyltransferase activity also showed no increase in activity after infection. tRNA nucleotidyltransferase was purified from both uninfected and T4-infected cells and examined for possible modification. It was found that enzyme purified from both types of cells eluted from DEAE cellulose at the same specific conductivity. In addition, the molecular weight of tRNA nucleotidyltransferase purified from both uninfected and T4-infected cells was approximately 45,000 daltons as determined by chromatography on Sephadex G-100. These results suggest that T4-infection does not lead to synthesis of a new virus-specific tRNA nucleotidyltransferase nor does it cause modification of the host enzyme.     

Regulation of the intracellular concentration of T4 induced tRNA

Summary We have studied the biosynthesis of T4 induced tRNA's upon infection of E. coli B ^E cells in low phosphate (l.p.) medium (10^-4 M PO ₄ ^--- ). Under our experimental conditions the onset of phage DNA synthesis occurs at about 15 min after infection, while the first intracellular phage appears one hour later. Amounts of newly synthesized DNA and phage burst size are equivalent to the values obtained in standard (M9) medium (10^-1 M PO ₄ ^--- ). We present evidence that the synthesis of mature tRNA's and of at least one dimeric precursor drastically declines 20 min after infection. In addition we show that T4 induced tRNA molecules are stable and that the triphosphate nucleoside precursor pool does not change significantly during infection. Therefore we conclude that T4 induced tRNA molecules behave similarly to other early gene products.     

Interchangeability of factors and tRNA's in bacterial and eukaryotic translation initiation systems

Summary Once formylated, eukaryotic initiator tRNA behaves in anE. coli translation system like the homologous initiator, in its binding to ribosomes and ability to form a peptide bond with puromycin. Conversely, anE. coli initiator tRNA, either formylated or not, can bind to reticulocyte ribosomes in the presence of poly AUG and reticulocyte factors, but no transfer to puromycin is obtained. Thus, eukaryotic ribosomes seem to impose a more stringent discrimination as far as the biological specificity of initiator tRNA is concerned than doE. coli ribosomes.The possibility to interchange initiation factors has also been examined. When added to reticulocyte 40S subunits,E. coli initiation factors catalyze poly AUG dependent binding ofE. coli initiator tRNA whether formylated or not. Thus, ability ofE. coli factors to discriminate between the N-formyl substituted and unformylated initiator is lost when the ribosomal context is modified. Also in support to the role of the ribosome in tRNA selection is the fact that eukaryotic tRNA's which are recognized by a completeE. coli ribosomal system fail to react whenE. coli factors are crossed with reticulocyte ribosomes.Reticulocyte IF prepared by 2 hrs KCl extraction from ribosomes (IF_2hrs) shows no catalytic activity onE. coli ribosomes whereas IF prepared by shorter KCl extraction (IF_1/2hr) stimulates low but appreciableE. coli or reticulocyte fMet-tRNA binding to 70S ribosomes. A similar activity is displayed by partially purified IF-M₁. Both IF_1/2hr and IF-M₁ dependent binding to heterologous ribosomes readily take place in the absence of GTP and no transfer to puromycin is observed. Complementation betweenE. coli IF₁ and reticulocyte IF-M₁ for fMet-tRNA binding to reticulocyte 40S subunits has been obtained suggesting functional similarities between IF-M₁ andE. coli IF₂. The possible role of IF-M₁ in the homologous reaction is discussed.