The study of spermidine-stimulated polypeptide synthesis in cell-free translation of mRNA from lactating mouse mammary gland

The stimulatory effect of spermidine on the translation of poly(A)⁺ mRNA from lactating mouse mammary glands in a wheat germ system was studied. Spermidine stimulated total polypeptide synthesis about 2.5-fold relative to that occurring in the presence of an optimal concentration of Mg²⁺ alone. The size and the number of polysomes were about 1.6-times larger in the presence of spermidine than in its absence. A similar magnitude of increase in peptide chain initiation, 1.4-fold, was found when the extent of peptide chain initiation was measured by determining the residual polypeptide synthesis subsequent to the addition of inhibitor(s) of peptide chain initiation to the in vitro translation system with or without spermidine at various times of the incubation. Time-course study of the release of polypeptide from polysomes showed that spermidine stimulated this process to a much greater extent than peptide chain initiation, indicating that the polyamine also increases the rate of peptide chain elongation. The extent of stimulation of peptide chain elongation by spermidine was estimated to be about 1.5-fold when the disappearance of isotope-labeled nascent peptides from polysomes was measured by pulse-chase experiments. These results indicate that spermidine stimulates the cell-free translation of mammary mRNA by increasing the rates of both initiation and elongation of polypeptide synthesis to almost the same extent. The polyamine also reduced the relative amount of incomplete polypeptides, thereby increasing the yield of full-length translational products.     

Membrane-bound ribosomes of myeloma cells. VI. Initiation of immunoglobulin mRNA translation occurs on free ribosomes

Immunoglobulin heavy (Ig H) and light (Ig L) chain mRNA molecules have been released from the endoplasmic reticulum (ER) membranes as free (F) mRNP particles when MOPC 21 (P3K) mouse myeloma cells are exposed to a hypertonic initiation block (HIB). The subsequent fate of these mRNA sequences has been examined when the cells are returned to normal growth medium. Upon return to isotonicity, all previously translated mRNA molecules reassociate with ribosomes and form functional polysomes. Ig H mRNA is found incorporated first into F polysomes and then into membrane-bound (MB) polysomes. Kinetic studies indicate that the time of passage of Ig H mRNA in F polysomes is approximately 30 s, during which a nascent polypeptide chain of approximately 80 amino acids would have been completed. When the rate of polypeptide elongation is depressed with emetine during the recovery from HIB, both Ig H and L mRNA molecules accumulate in small F polysomes. These results indicate that the formation of Ig-synthesizing polysomes proceeds in the sequence: mRNA leads to F polysomes leads to MB polysomes. With the additional observation that during HIB recovery puromycin completely prevents the reassociation of Ig mRNA with the ER, these findings support a model of MB polysome formation in which the specificity of membrane attachment is determined by the nature of the N- terminal amino acid sequence of the nascent polypeptide chain.     

Evidence for the presence of an inhibitor on ribosomes in mouse L cells infected with mengovirus.

After infection of mouse L cells with mengovirus, there is a rapid inhibition of protein synthesis, a concurrent disaggregation of polysomes, and an accumulation of 80S ribosomes. These 80S ribosomes could not be chased back into polysomes under an elongation block. The infected-cell 80S-ribosome fraction contained twice as much initiator methionyl-tRNA and mRNA as the analogous fraction from uninfected cells. Since the proportion of 80S ribosomes that were resistant to pronase digestion also increased after infection, these data suggest that the accumulated 80S ribosomes may be in the form of initiation complexes. The specific protein synthetic activity of polysomal ribosomes also decreased with time of infection. However, the transit times in mock-infected and infected cells remained the same. Cell-free translation systems from infected cells reflected the decreased protein synthetic activity of intact cells. The addition of reticulocyte initiation factors to such systems failed to relieve the inhibition. Fractionation of the infected-cell lysate revealed that the ribosomes were the predominant target affected. Washing the infected-cell ribosomes with 0.5 M KCI restored their translational activity. In turn, the salt wash from infected-cell ribosomes inhibited translation in lysates from mock-infected cells. The inhibitor in the ribosomal salt wash was temperature sensitive and micrococcal nuclease resistant. A model is proposed wherein virus infection activates (or induces the synthesis of) an inhibitor that binds to ribosomes and stops translation after the formation of the 80S-ribosome initiation complex but before elongation. The presence of such an inhibitor on ribosomes could prevent them from being remobilized into polysomes in the presence of an inhibitor of polypeptide elongation.     

Regulation of polypeptide chain initiation and activity of initiation factor eIF-2 in Chinese-hamster-ovary cell mutants containing temperature-sensitive aminoacyl-tRNA synthetases

The regulation of polypeptide chain initiation has been investigated in extracts from a number of well-characterized Chinese hamster ovary (CHO) cell mutants containing different temperature-sensitive aminoacyl-tRNA synthetases. These cells exhibit a large decline in the rate of initiation when cultures are shifted from the permissive temperature of 34 degrees C to the non-permissive temperature of 39.5 degrees C. During a brief incubation with [35S]Met-tRNAMetf or [35S]methionine, formation of initiation complexes on native 40S ribosomal subunits and 80S ribosomes is severely impaired in extracts from the mutant cell lines exposed to 39.5 degrees C. Wild-type cells exposed to 39.5 degrees C do not show any inhibition of protein synthesis or initiation complex formation. Inhibition of formation of 40S initiation complexes in the extracts from mutant cells, incubated at the non-permissive temperature, is shown to be independent of possible changes in mRNA binding or the rate of polypeptide chain elongation and is not due to any decrease in the total amount of initiation factor eIF-2 present. However, assays of eIF-2 X GTP X Met-tRNAMetf ternary complex formation in postribosomal supernatants from the temperature-sensitive mutants reveal a marked defect in the activity of eIF-2 after exposure of the cells to 39.5 degrees C and addition of exogenous eIF-2 to cell-free protein-synthesizing systems from cells incubated at 34 degrees C and 39.5 degrees C eliminates the difference in activity between them. The activity of the initiation factor itself is not directly temperature-sensitive in the mutant CHO cells. The results suggest that the activity of aminoacyl-tRNA synthetases can affect the ability of eIF-2 to bind Met-tRNAMetf and form 40S initiation complexes in intact cells, indicating a regulatory link between polypeptide chain elongation and chain initiation.     

Analysis of the two steps in polypeptide chain initiation inhibited by pactamycin.

Earlier work has shown that the inhibition by pactamycin (PM) of polypeptide chain initiation in reticulocyte extracts is associated with (1) a defect in the joining of the 60S subunit to the smaller initiation complex to form an 80S complex ("joining reaction") (Kappen, L. S., Suzuki, H., and Goldberg, I. H. (1973), Proc. Natl. Acad. Sci. U.S.A. 70, 22) and (2) a block after the synthesis of the initial dipeptide (Kappen, L. S., and Goldberg, I. H. (1973), Biochem. Biophys. Res. Commun. 54, 1083). The relative contributions of these two effects to the action of PM and their relationship to one another were evaluated in a system employing sparsomycin that permits both initiation at a certain number of initiation sites and limited oligopeptide formation without termination and release. The degree to which PM blocks the "joining reaction" and leads to the accumulation of 48S initiation complexes that either remain free or are bound to polysomes without the corresponding 60S subunit ("half-mers") was estimated by treatment of polysomes with RNase. Met-tRNAfMet binding factors are required to stabilize the RNase-generated 48S complexes. Under conditions where the initiation factor required for the "joining reaction" functions catalytically, presumably by cycling on and off initiation complexes, PM usually inhibits 80S complex formation 50-70%. Where "joining" is not limiting (presence of at least stoichiometric amounts of joining factor or high Mg2+ concentration) PM leads to the maximal accumulation of the initial dipeptide, Met-Val, in the P-site on the ribosome, indicating a block in a subsequent step in elongation. Binding studies with [3H]PM and the inability of PM to inhibit elongation of preformed Met-Val indicate that PM must interact with the ribosomes at an early stage of initiation. Taken together these data are compatible with the suggestion that PM does not interfere with the ribosomal "joining reaction" per se, but prevents the release and reuse of the joining factor, and in so doing blocks a step in elongation after formation of the initial dipeptide and its translocation to the P-site on the ribosome.     

Inhibition of polypeptide chain initiation in Daudi cells by interferons. Evidence that activity of initiation factor eIF-2 and availability of mRNA are unimpaired.

The accompanying paper [McNurlan & Clemens (1986) Biochem. J. 237, 871-876] shows that the inhibition of proliferation of Daudi cells by human interferons is associated with impairment of the overall rate of protein synthesis. We have examined whether two of the mechanisms which are believed to control translation in interferon-treated virus-infected cells may be responsible for the inhibition of protein synthesis during the antiproliferative response in these uninfected cells. Although the rate of polypeptide chain initiation is lower in interferon-treated Daudi cells, as indicated by the disaggregation of polysomes, there is no significant inhibition of activity of initiation factor eIF-2 or of [40 S . Met-tRNAf] initiation complex formation in cell extracts. The phosphorylation state of the alpha subunit of eIF-2 remains unaltered. There is no major decrease in mRNA content as a proportion of total RNA up to 4 days of interferon treatment, as judged by poly(A) content, although the amount of total mRNA/10(6) cells eventually declines. The mRNA present in extracts from interferon-treated cells remains translatable when added to an mRNA-dependent reticulocyte lysate system. We conclude that neither the interferon-inducible eIF-2 protein kinase pathway nor the 2',5'-oligo(adenylate)-ribonuclease L pathway are responsible for the inhibition of polypeptide chain initiation. Rather, the data suggest impairment at the level of formation of [80 S ribosome X mRNA] initiation complexes.     

Investigation of sesquiterpene lactones as protein synthesis inhibitors of P-388 lymphocytic leukemia cells

The mode of action of helenalin and bis(helenalinyl) malonate as protein synthesis inhibitors of P-388 lymphocytic leukemia cells was investigated. The initial characterizations were carried out in crude lysates of the P-388 cells. In the lysate, there was a 4 min lag after the addition of drug before inhibition of protein synthesis occurred. Both drugs allowed run-off of preformed polysomes, but did significantly inhibit the formation of the 80 S initiation complex suggesting a preferential inhibition of one or more initiation reactions. The effect of these drugs on inhibition of both elongation and initiation reactions was further investigated using more fractionated systems prepared from P-388 cells. Poly(U)-directed polyphenylalanine synthesis was marginally inhibited by both drugs, but the degree of inhibition was not sufficient to explain the inhibition observed in either the lysate or in whole cell preparations of P-388. The formation of the ternary initiation complex was not significantly inhibited by either drug, but the conversion of this complex to the 48 and 80 S initiation complexes was inhibited. The inhibition of 48 S initiation complex formation by both drugs was sufficient to explain their inhibition of protein synthesis in whole cells.     

Specificity of factors isolated from free polysomes and microsomes on in vitro protein synthesis in plasmacytoma cells

A simple procedure for measuring chain initiation in complete in vitro systems is described. The capacity of free and membrane-bound polysomes prepared by a detergent technique or by nitrogen cavitation to incorporate radioactive amino acids into proteins was compared with the capacity of these polysomes to initiate polypeptide chains.The extent of amino acid incorporation by polysomes prepared by either of these methods did not differ significantly. However, chain initiation determined by measuring the incorporation of radioactive subunits into polysomes showed that polysomes prepared by the detergent technique were less effective than polysomes made by nitrogen cavitation in chain initiation.Crude initiation factors, prepared by washing either free polysomes or microsomes with 0.5 M KCl, stimulated chain initiation and amino acid incorporation by both types of polysomes. Free polysomes were stimulated almost to the same extent by factors isolated from free polysomes or microsomes. Membrane-bound polysomes on the other hand showed a specific requirement for microsomal factors.The extent of stimulation by crude polysomal factors was dependent on the concentration of high speed supernatant in the assay system.     

Lack of inhibition by l-1-chloro-4-phenyl-3-toluene-p-sulphoamidobutan-2-one (l-1-tosylamido-2-phenylethyl chloromethyl ketone) of the formation of bacterial polypeptide chain initiation complex (Short Communication)

The chymotrypsin inhibitor l-1-chloro-4-phenyl-3-toluene-p-sulphonamidobutan-2-one does not inhibit the function of the initiation factor during the formation of the polypeptide chain initiation complex in vitro. Since the inhibitor has been shown previously to inhibit polypeptide chain elongation by reacting with elongation factor EF-Tu, the inhibitor can be used to investigate the initiation and elongation steps of protein biosynthesis separately.     

Regulation of mitochondrial protein synthesis at the polyribosomal level.

Polysomes consisting of two to eight monosomes were isolated from yeast mitochondria by lysing the mitochondria with Triton X-100 and centrifugation in a 20 to 40% linear sucrose gradient. When yeast spheroplasts were pulse-labeled with [3H]-Leucine in the presence of cycloheximide to block cytoplasmic protein synthesis, radioactivity which was trichloroacetic acid-precipitable was present mainly in the polysome region. Incorporation of leucine was blocked by erythromycin, a specific inhibitor of mitochondrial protein synthesis. Release of radioactivity to the top of the gradient resulted from treating labeled polysomes with either puromycin or ribonuclease (in the latter case with the breakdown of polysomes), indicating that the radioactivity was present in nascent polypeptide chains. Yeast cells were grown in chloramphenicol for 3 hours and in fresh medium for 1 hour and then pulse-labeled with either [3H]leucine or [14C]formate. Three parameters showed a 2-fold increase in cells grown in chloramphenicol prior to pulse labeling: the polysome to monosome ratio, the amount of labeled precursor incorporated into proteins, and the rate of polypeptide chain initiation as judged by the formation of fMet-puromycin. Conversely, these parameters were all decreased approximately 50% in cells treated with cycloheximide prior to pulse labeling. Mitochondria were also isolated from cells previously grown in chloramphenicol or cycloheximide and incubated in vitro with [3H]leucine under optimal conditions. Acid-precipitable radioactivity in the polysome region was increased 3-fold in mitochondria from cells grown previously in chloramphenicol and decreased 75% in those grown in cycloheximide. Furthermore, chain initiation was deomonstrated in the isolated mitochondria by formation of fMet-puromycin. The rate of chain initiation in vitro was increased 2-fold in mitochondria isolated from chloramphenicol-treated cells.     

Predominant synthesis of fibroin heavy and light chains on the membrane-bound polysomes prepared from the posterior silk gland of the silkworm, Bombyx mori

Membrane-bound polysomes were prepared from the posterior silk gland of the silkworm, Bombyx mori, on the fourth to fifth day in the fifth larval instar. The polysomes, when supplemented with a soluble fraction from the posterior silk gland, exhibited the elongation reaction of the growing polypeptide-chains, but the initiation reaction of polypeptide synthesis was not demonstrated in this system. The predominant products synthesized on the membrane-bound polysomes were fibroin heavy chain (H-chain) and light chain (L-chain), while polypeptides of heterogeneous size classes were synthesized on the 105,000 X g-sedimentable polysomes. A substantial fraction of the fibroin L-chain synthesized was bound to the H-chain by disulfide bond. Most of the newly synthesized fibroin H- and L-chains on the membrane-bound polysomes were proved to be present within microsomal membrane vesicles because of their insensitivity to digestion with proteases in the absence of Triton X-100.     

Preparation and characterization of a cell-free system from Chinese hamster ovary cells that translates natural messenger ribonucleic acid and analysis of intermediary reactions

A cell-free system from cultured Chinese hamster ovary cells has been developed, which translates endogenous mRNAs, exogenous natural mRNAs, and synthetic polynucleotide templates. The analysis of most of the reactions involved in initiation, elongation, and termination of protein synthesis can be carried out in this system. The postmitochondrial fraction, containing ribosomal 40 and 60 S subunits, 80 S ribosomes, polysomes, and cytosol proteins, incorporates amino acids into protein. The preparation is capable of recycling endogenous mRNA by initiating protein synthesis on polysomal mRNA, and of initiating protein synthesis on exogenous templates. When endogenous mRNA is degraded with micrococcal nuclease, polysomes are no longer evident and protein synthesis is markedly depended on added mRNA, ATP, GTP, and a nucleoside triphosphate-generating system. Amino acid incorporation is linear for over 2 h, polysomes containing nascent polypeptide chains are reformed and, with time, most of the protein synthesized is released into the media. Gel electrophoretic analysis of the product formed in response to globin mRNA indicates that most of the radioactivity migrates as a single peak, in the region corresponding to globin. Comparison of the electrophoretic pattern obtained from labeled Chinese hamster ovary cells with that from incubations of cell extract and Chinese hamster ovary mRNA indicates that essentially all of the polypeptides formed by the intact cell are synthesized by the cell-free system. Sucrose gradient centrifugation of incubations containing mRNA-depleted extract and [³⁵S]methionine, in the absence of added mRNA, is used to detect initiation intermediates in the formation of the [40 S Met-tRNA_f] complex and, with added natural mRNA plus cycloheximide, to detect intermediates in the formation of the 80 S initiation complex. Chain elongation reactions are measured by the incorporation of [³H]phenylalanine into polyphenylalanine in extracts supplemented with poly(U), or by the formation of nascent polypeptide chains on polysomes with natural mRNA. Chain termination is measured by analyzing the amount of radioactive protein released into the cytosol.     

Protein synthesis inhibition by 8-oxo-12,13-epoxytrichothecenes

The Fusarium mycotoxin, 4-deoxynivalenol, is an abundant, natural contaminant of corn and wheat. 8-Oxo-12,13-epoxytrichothecenes related to 4-deoxynivalenol were synthesized; they either lacked the 7-hydroxyl but contained a hydroxyl at C-4 (7-deoxynivalenol) or lacked substituents at C-3 and C-7 (3,7-dideoxynivalenol). The ability of these synthetic analogs and their acetylated derivatives to inhibit protein synthesis by cultured mammalian cells was compared to that of 4-deoxynivalenol. Whereas the 50% inhibitory dose (ID50) for murine erythroleukemia cells was about 1 microgram/ml for 4-deoxynivalenol and 3,7-dideoxynivalenol, all of the other analogs were at least 10-fold less potent. When tested at their ID50 dose, all of the 8-oxotrichothecenes, except 4-deoxynivalenol and 3,7-dideoxynivalenol, caused polysome 'run-off', indicating that, at this dose, they are inhibitors of polypeptide chain initiation. With 4-deoxynivalenol and 3,7-dideoxynivalenol, polysomes remained at control levels indicating that these toxins prevent polypeptide chain elongation. From these results and comparisons to previous studies of 8-oxo-12,13-epoxytrichothecenes (trichothecolone, trichothecin, nivalenol and fusarenone X), trichothecenes with substituents at both C-3 and C-4 predominantly inhibit polypeptide chain initiation, whereas those lacking one substituent at either site are inhibitors of chain elongation.     

Translational elongation rate changes in encephalomyocarditis virus-infected and interferon-treated cells.

Infection of mouse L cells with encephalomyocarditis virus results in a rapid inhibition of host protein synthesis before the synthesis of viral proteins. Although no alterations in initiation factor activities have been demonstrated in encephalomyocarditis virus-infected mouse cells, a defect in polypeptide chain elongation has been shown to occur in infected cell extracts. We investigated the significance of this elongation defect in the host shutoff phenomenon in vivo. Average polypeptide chain elongation rates were measured at various times after infection. Interferon was used as a reagent to separate temporarily the virus-induced alterations. Encephalomyocarditis virus infection of L cells was shown to lead to a progressive reduction in the elongation rate. Whereas interferon pretreatment delayed the decrease in elongation rate in a dose-dependent manner, it failed to alter the kinetics of host shutoff, suggesting that slowing of elongation steps played no significant role in this phenomenon. In addition, interferon pretreatment of either mock-infected or virus-infected cells led to no elongation defect that could be attributed to interferon action.     

Studies on the mode of action of hygromycin B, an inhibitor of translocation in eukaryotes.

Hygromycin B is an unusual aminoglycoside antibiotic active against both prokaryotic and eukaryotic cells. Hygromycin B at 0.38 mM concentration completely halts yeast cell growth in rich media, presumably by preventing protein synthesis by cytoplasmic ribosomes. Polypeptide synthesis in cell-free extracts from rabbit reticulocytes, wheat germ and yeast is strongly blocked by low concentrations of hygromycin B. The antibiotic inhibits peptide chain elongation by yeast polysomes by preventing elongation factor EF-2-dependent translocation, although it does not affect either the formation of the EF-2-GTP-ribosome complex or the EF-2- and ribosome-dependent GTP hydrolysis which takes place uncoupled from translocation. The inhibition of translocation by hygromycin B might result from the stabilization of peptidyl-tRNA bound to the ribosomal acceptor site, since the stability of [3H]Phe-tRNA-EF-1-poly(U)-ribosome and [3H]Phe-tRNA-poly(U)-ribosome complexes is increased in the presence of hygromycin B. The inhibition of polyphenylalanine synthesis by reticulocyte ribosomes and enzymic translocation of peptidyl-tRNA by yeast polysomes can be reversed by increasing concentrations of EF-2 suggesting a relationship between the binding sites of EF-2 and hygromycin B on the ribosome. Neither non-enzymic translocation, that takes place in the presence of high potassium concentrations, nor the peptide bondforming step are affected by hygromycin B.     

Mode of action of bottromycin A2: effect of bottromycin A2 on polysomes

When bottromycin A2 was added to an in vitro protein synthesis system carried out by naturally occurring polysomes, it inhibited protein synthesis effectively. Examination of the 3 steps of peptide chain elongation revealed that the binding of aminoacyl-tRNA to the polyribosomes was inhibited by bottromycin A2. In contrast, we concluded that the peptide bond formation and the translocation steps in this system were not inhibited by bottromycin A2 on the basis of the following observations: (1) The break-down of polysomes, which is dependent on EFG, puromycin and RR (ribosome releasing) factor, was insensitive to bottromycin A2; (2) The puromycin dependent release of polypeptide from polysomes, with or without EFG, was not inhibited by bottromycin A2. Thus bottromycin specifically interferes with proper functioning of the A sites of polysomes. This is consistent with the results obtained using the model system with synthetic polynucleotides.     

Inhibition of host protein synthesis in vaccinia virus-infected cells in the presence of cordycepin (3''-deoxyadenosine).

Cordycepin inhibited efficiently viral mRNA and polyadenylic acid syntheses in vaccinia virus-infected cells, but allowed the shutoff of host protein synthesis to occur. Therefore, cordycepin was used to study this shutoff in the absence of gene expression. Ribosome transit time was increased in infected cells, revealing an inhibition at the level of elongation and/or release of polypeptide chains. However, the disappearance of heavy polysomes in vaccinia virus-infected cells showed that the inhibition of host protein synthesis resulted predominantly from a block at the stage of initiation. This conclusion was confirmed by the recovery of heavy polyribosomes when low levels of cycloheximide were added to slow down ribosome release from the mRNA. Similar amounts of cellular mRNA (present in the polyribosomes) were found in vaccinia virus-infected cells and in mock-infected cels (exposed to cordycepin), showing that the cellular mRNA was not inactivated in these conditions. It was concluded that a component of the vaccinia virion inhibits, in the absence of viral RNA and polyadenylic acid syntheses, host protein synthesis at the level of initiation and, to a lesser extent, at the level of elongation (and/or release) of polypeptide chains.     

Isolation of mRNA from membrane-bound polysomes synthesizing Sepia officinalis haemocyanin in Xenopus laevis oocytes

Isolation and translation in Xenopus laevis oocytes of the mRNAs from the nuclear pellet and the cytoplasmic supernatant of the branchial glands from Sepia officinalis, homogenized in the presence of vanadyl-ribonucleoside complexes, revealed that the membrane-bound polysomes for haemocyanin sedimented together with the nuclei. Centrifugation on a 15-50% sucrose gradient of these polysomes, released by treatment with Triton X-100, yielded a major peak of heavy ones. The messenger fraction, isolated from this heavy fraction, directed the synthesis of the large 390 000 Mr haemocyanin polypeptide chain in oocytes. A large mRNA on heavy membrane-bound polysomes thus synthesizes the whole haemocyanin chain of S. officinalis.     

Cytoplasm from Poliovirus-infected HeLa Cells inhibits Cell-free Haemoglobin Synthesis

INFECTION of HeLa cells with poliovirus causes an inhibition of host cell protein synthesis with a concomitant conversion of polysomes to single ribosomes^{1, 2}. This process is thought to be mediated by a product of the viral genome, for infection of cells with virus particles which have been inactivated by ultraviolet irradiation does not affect the rate of protein synthesis¹. The inhibition acts directly on translation rather than on the production of mRNA^{1, 3}, yet neither chain elongation nor the release of polypeptide chains from ribosomes seems to be affected². Chain initiation, therefore, is the only possible target. Willems and Penman have suggested that cellular mRNA is inactivated after infection, preventing its reassociation with ribosomes³. To test these hypotheses, we assayed for the presence of inhibitors of initiation in poliovirus-infected HeLa cell cytoplasm, using a lysate of rabbit reticulocytes that initiates the synthesis of new polypeptide chains at a rate comparable with that in intact cells.