Effect of heparin contained in preparations of small cytoplasmic RNAs on cell-free translation.

It has been reported that small cytoplasmic RNA (scRNA) from human placenta inhibits translation of most mRNAs in both wheat germ extracts and reticulocyte lysates (Lorberboum, H., Digweed, M., Erdmann, V. A., Servadio, Y., Weinstein, D., De Groot, N., and Hochberg, A. A. (1986) Eur. J. Biochem. 155, 279-287). We have investigated the mechanism by which scRNA preparations inhibit mRNA translation in vitro. We demonstrate that the inhibitory agent(s) is not sensitive to treatment with various ribonucleases but that translational inhibition is sensitive to incubation with 1 N NaOH at 95 degrees C or to treatment with heparinase. Based on these findings and on the ability of heparin to inhibit cell-free translation by itself, we conclude that the presence of heparin in preparations of scRNA from human placenta is responsible for effects which have previously been attributed to inhibitory RNA molecules. Since heparin is also frequently used in the isolation of translationally inhibitory scRNAs from other sources, we suggest that the sensitivity of these preparations to ribonucleases and heparinase should be examined.     

Translational control at the level of initiation between mRNAs for pre-existing proteins and a 22-kDa heat-shock protein of Chlamydomonas by small cytosolic RNAs

Small cytosolic RNAs (scRNAs) from human placenta inhibit translation of poly(A)-rich RNA from Chlamydomonas in the wheat germ cell-free system. The major exception is the mRNA for a nuclear-coded 22-kDa chloroplast heat-shock protein whose translation is much less affected. Evidence is presented which suggests that scRNAs do not directly interact with the mRNAs but with a factor of the wheat germ system instead. It has been found that run-off translation of polyribosomes is not impaired by scRNAs whereas the formation of initiation complexes in vitro, again with the exception of those of the mRNA for the 22-kDa heat-shock protein, is heavily affected. From this evidence we conclude that scRNAs interfere with the action of one or more of the wheat germ initiation factors and that the translation of the mRNA for the 22-kDa heat-shock protein is much less dependent upon this (these) factor(s).     

Role of cytoplasmic mRNP proteins in translation.

Polyribosomal and free mRNPs from rabbit reticulocytes were isolated and characterized. Translation of mRNPs was studied in the rabbit reticulocyte and wheat germ cell-free systems. Both classes of mRNPs were active in rabbit reticulocyte lysates. However, considerable differences between mRNPs and mRNA have been revealed. High concentrations of mRNA in the form of mRNP did not inhibit protein biosynthesis, whereas the same amounts of deproteinized mRNA caused inhibition of this process. Polyribosomal mRNPs and deproteinized mRNA, but not free mRNPs, are active in the wheat germ cell-free translation system. Translation of free mRNPs in this system can be restored by addition of 0.5 M KCl-wash of rabbit reticulocyte ribosomes. These results suggest the existence of a special repressor/activator regulatory system which controls mRNA distribution between free mRNPs and polyribosomes in rabbit reticulocytes. This regulatory system should include: i) a translation repressor associated with mRNA within free mRNPs, preventing its translation; and ii) a translation activator associated with ribosomes, overcoming the effect of the repressor. Both classes of cytoplasmic mRNPs contain a major 50 kDa protein (p50). The content of this protein per mol of mRNA in free mRNPs is twice as much as in polyribosomal ones. The method of p50 isolation has been developed and some properties of this protein were investigated. It has been shown that small amounts of p50 stimulate, whereas high amounts inhibit mRNA translation. We suggest that p50 has a dual role in protein biosynthesis. In polyribosomal mRNPs (p50:mRNA approximately 2:1, mol/mol), this protein promotes the translation process.(ABSTRACT TRUNCATED AT 250 WORDS)     

Inhibition of protein synthesis in reticulocyte lysates by a double-stranded RNA component in HeLa mRNA

Double-stranded RNA (dsRNA) inhibits protein synthesis initiation in rabbit reticulocyte lysates by the activation of a latent dsRNA-dependent cAMP-independent protein kinase which phosphorylates the α-subunit of the eukaryotic initiation factor eIF-2. In this study, we describe a dsRNA-like component which is present in preparations of HeLa mRNA (poly A⁺) isolated from total cytoplasmic RNA. The inhibitory species in the HeLa cytoplasmic mRNA was detected by (a) its ability to inhibit protein synthesis with biphasic kinetics in reticulocyte lysates translating endogenous globin mRNA, and (b) by the inefficient translation of HeLa cytoplasmic mRNA in a nuclease-treated mRNA-dependent reticulocyte lysate. The inhibitory component was characterized as dsRNA by several criteria including (i) the ability to activate the lysate dsRNA-dependent eIF-2α kinase (dsI); (ii) the prevention of both dsI activation and inhibition of protein synthesis by high levels of dsRNA or cAMP; (iii) the reversal of inhibition by eIF-2; and (iv) the inability to inhibit protein synthesis in wheat germ extracts which lack latent dsI. By the same criteria, the putative dsRNA component(s) appears to be absent from preparations of HeLa mRNA isolated exclusively from polyribosomes.     

A cytoplasmic ribonucleoprotein complex containing a small RNA inhibitor of protein synthesis

Ribonucleoprotein complexes (RNP) sedimenting between 10 and 15 S were isolated from the postpolysomal cytoplasmic fraction of embryonic chicken muscle. These RNP complexes lack mRNA but contain RNA with a sedimentation coefficient of 4.4 S. The 4.4 S RNA did not arise as a product of degradation during the course of the isolation procedure nor did it contain oligo(U)- or poly(A)-rich regions. Furthermore, the 4.4 S RNA-containing RNP complex was easily separable from free mRNPs and, therefore, is not considered as part of the free mRNP complexes. Both the 4.4 S RNA and 10 to 15 S RNP were able to inhibit translation of either "capped" or "uncapped" mRNA in a heterologous cell-free system. This inhibitory effect may result from interference of 4.4 S RNA with an early event in mRNA translation. A large number of polypeptides of Mr = 14,000 to 220,000 were present in the 10 to 15 S RNP. Among these, the most prominent polypeptides were of Mr = 36,000; 48,000; 52,000; 58,000; 65,000; 78,000; 84,000; 96,000; 105,000; 165,000; and 220,000. With the exception of the Mr = 36,000 polypeptide, these major components were also found in the nonpolysomal cytoplasmic mRNA protein complexes (free mRNP).     

Insulin silences apolipoprotein B mRNA translation by inducing intracellular traffic into cytoplasmic RNA granules

Insulin is a potent inducer of global mRNA translation and protein synthesis, yet it negatively regulates apolipoprotein B (apoB) mRNA translation, via an unknown mechanism. ApoB mRNA has a long half-life of 16 h, suggesting intracellular storage as mRNPs likely in the form of RNA granules. The availability of apoB mRNA for translation may be regulated by the rate of release from translationally silenced mRNPs within cytoplasmic foci called processing bodies (P bodies). In this report, we directly imaged intracellular apoB mRNA traffic and determined whether insulin silences apoB mRNA translation by entering cytoplasmic P bodies. We assessed the colocalization of apoB mRNA and β-globin mRNA (as a control) with P body (PB) markers using a strong interaction between the bacteriophage capsid protein MS2 and a sequence specific RNA stem-loop structure. We observed statistically significant increases in the localization of apoB mRNA into P bodies 4-16 h after insulin treatment (by 72-89%). The movement of apoB mRNA into cytoplasmic P bodies correlated with reduced translational efficiency as assessed by polysomal profiling and measurement of apoB mRNA abundance. PB localization of β-globin mRNA was insensitive to insulin treatment, suggesting selective regulation of apoB mRNA by insulin. Overall, our data suggest that insulin may specifically silence apoB mRNA translation by reprogramming its mRNA into P bodies and reducing the size of translationally competent mRNA pools. Translational control via traffic into cytoplasmic RNA granules may be an important mechanism for controlling the rate of apoB synthesis and hepatic lipoprotein production.     

Analysis of the control of citrulline synthesis in isolated rat-liver mitochondria

Irradiation of chicken muscle cells with ultraviolet light (254 nm) to cross-link RNA and protein moieties was used to examine the polypeptide complements of cytoplasmic mRNA-protein complexes (mRNP). The polypeptides of translationally active mRNP complexes released from polysomes were compared to the repressed nonpolysomal cytoplasmic (free) mRNP complexes. In general, all of the polypeptides present in free mRNPs were also found in the polysomal mRNPs. In contrast to polysomal mRNPS, polypeptides of Mr 28 000, 32 000, 46 000, 65 000 and 150 000 were either absent or present in relatively smaller quantities in free mRNP complexes. On the other hand, the relative proportion of polypeptides of Mr 130 000 and 43 000 was higher in free mRNPs than in polysomal mRNP complexes. To examine the role of cytoplasmic mRNP complexes in protein synthesis or mRNA metabolism, the changes in these complexes were studied following (a) inhibition of mRNA synthesis and (b) heat-shock treatment to alter the pattern of protein synthesis. Actinomycin D was used to inhibit mRNA synthesis in chick myotubes. The possibility of newly synthesized polypeptides of cytoplasmic mRNP complexes being assembled into these complexes in the absence of mRNA synthesis was examined. These studies showed that the polypeptides of both free and polysomal mRNP complexes can bind to pre-existing mRNAs, therefore suggesting that polypeptides of mRNP complexes can be exchanged with a pool of RNA-binding proteins. In free mRNP complexes, this exchange of polypeptides is significantly slower than in the polysomal mRNP complexes. Heat-shock treatment of chicken myotubes induces the synthesis of three polypeptides of Mr = 81 000, 65 000 and 25 000 (heat-shock polypeptides). Whether this altered pattern of protein synthesis following heat-shock treatment could affect the polypeptide composition of translationally active polysomal mRNPs was examined. The results of these studies show that, compared to normal cells, more newly synthesized polypeptides were assembled into polysomal mRNPs following heat-shock treatment. A [35S]methionine-labeled polypeptide of Mr = 80 000 was detected in mRNPs of heat-shocked cells, but not of normal cells. This polypeptide was, however, detected by AgNO3 staining of the unlabeled polypeptide of mRNP complexes of normal cells. These results, therefore, suggest that the assembly of newly synthesized 80 000-Mr polypeptide to polysomal mRNPs was enhanced following induction of new heat-shock mRNAs. The results of these studies reported here have been discussed in relation to the concept that free mRNP complexes are inefficiently translated in vivo.(ABSTRACT TRUNCATED AT 400 WORDS)     

Insulin modulation of human apolipoprotein B mRNA translation: studies in an in vitro cell-free system from HepG2 cells.

Insulin modulation of apolipoprotein B gene expression was studied at the translational level by the use of a cell-free translation system from a hepatoma cell-line, HepG2. Extracts of HepG2 cells lysed with lysolecithin were found to have high in vitro protein synthesizing activity utilizing endogenous mRNA. The level of peptide chain initiation was high, as suggested by a significant inhibition of translation by edeine. The translation products of endogenous mRNA in HepG2 cell-free lysate were probed with anti-apolipoprotein B antibodies to investigate its synthesis. A 550 kilodalton (kDa) polypeptide was selected by a polyclonal antibody, as well as a monoclonal antibody, against the C-terminal end of apolipoprotein B molecule. This in vitro synthesized polypeptide was also found to compare well in size with the in vivo product. The HepG2 lysate was also shown to efficiently synthesize in vitro a number of other proteins including albumin, apolipoprotein E, apolipoprotein A1, and actin. The in vitro synthesis of polypeptides as large as 500 kDa was unexpected and has not previously been demonstrated in a cell-free system. The HepG2 translation system was used to investigate the effect of insulin on the in vitro translation of apolipoprotein B. Lysates prepared from HepG2 cells treated with insulin were found to have lower translational activity (by an average of 52.3%) for apolipoprotein B compared with lysates from control untreated cells. In vitro synthesis of actin and apolipoprotein E were unaffected under these conditions. The insulin-stimulated decline in in vitro apolipoprotein B synthesis was not due to a change in apolipoprotein B mRNA levels as determined by slot- and Northern-blot analyses, suggesting that the inhibitory effect of insulin may be exerted partly at the level of apolipoprotein B mRNA translation.     

Small cytoplasmic RNAs and their location within the cytoplasm

These studies were designed to establish the location of various species of small RNAs within the subcellular cytoplasmic compartments. Four cytoplasmic RNA-containing compartments were examined: (A) cytoskeleton-bound polyribosomal ribonucleoprotein (RNP) complexes, (B) soluble-phase polyribosomal RNP complexes, (C) cytoskeleton-bound free RNP complexes, (D) soluble-phase free RNP complexes. The presence of the small cytoplasmic RNA (scRNA) population and histone H4 and actin mRNAs in each compartment was examined to determine their spatial distribution within the cytoplasm. The 7S signal recognition RNA and the 5S and 5.8S rRNAs were distributed among all four compartments, while 4S tRNAs were localized largely in fraction D. Fraction C contained a group of seven abundant scRNAs, of approximately 105-348 nucleotides in length, which were localized almost entirely within the cytoskeleton-bound free RNP compartment. Actin mRNAs were localized in fraction A, the actively translating cytoskeleton-bound compartment. Actin mRNAs were localized in fraction A, the actively translating cytoskeleton-bound compartment. Following cytochalasin B treatment, actin mRNAs were released into the soluble phase, implicating a dependence on the integrity of actin filaments in its binding. Such treatment also released several of the scRNAs from their cytoskeleton-bound location. In contrast histone H4 mRNAs were much more widely dispersed, being present in all four cytoskeletal compartments. Approximately 60% of the H4 mRNAs, however, were localized within the soluble-phase polyribosomes in fraction B. Cytochalasin B treatment released only the small portion of untranslated histone H4 mRNA associated with the cytoskeleton in fraction C, suggesting that the binding of these H4 mRNAs was dependent in some manner upon the integrity of actin filaments.     

Fertilization triggers unmasking of maternal mRNAs in sea urchin eggs.

Fertilization of sea urchin eggs results in a large increase in the rate of protein synthesis which is mediated by the translation of stored maternal mRNA. The masked message hypothesis suggests that messenger ribonucleoprotein particles (mRNPs) from unfertilized eggs are translationally inactive and that fertilization results in alterations of the mRNPs such that they become translationally active. Previous workers have isolated egg mRNPs by sucrose gradient centrifugation and have assayed their translational activity in heterologous cell-free systems. The conflicting results they obtained are probably due to the sensitivity of mRNPs to artifactual activation and inactivation. Previously, we demonstrated that unfractionated mRNPs in a sea urchin cell-free translation system were translationally inactive. Now, using large-pore gel filtration chromatography, we partially purified egg mRNPs while retaining their translationally repressed state. Polysomal mRNPs from fertilized eggs isolated under the same conditions were translationally active. The changes in the pattern of proteins synthesized by fractionated unfertilized and fertilized mRNPs in vitro were similar to those changes observed in vivo. Treatment of egg mRNPs with buffers containing high salt and EDTA, followed by rechromatography, resulted in the activation of the mRNPs and the release of an inhibitor of translation from the mRNPs. Analysis of the inhibitory fraction on one-dimensional sodium dodecyl sulfate gels indicated that this fraction contains a complex set of proteins, several of which were released from high-salt-EDTA-activated mRNPs and not from inactive low-salt control mRNPs. One of the released proteins may be responsible for the repression of egg mRNPs in vitro and be involved in the unmasking of mRNPs at fertilization.     

Encephalomyocarditis Virus Infection of Mouse Plasmacytoma Cells I. Inhibition of Cellular Protein Synthesis

Mouse plasmacytoma ascites tumor cells (MOPC 460) were efficiently infected with encephalomyocarditis virus. Inhibition of host protein synthesis was evident after 2 h and complete by 4 h postinfection. The mechanism by which virus infection results in inhibition of host cell protein synthesis was studied in vitro. Cell-free protein-synthesizing systems, prepared from uninfected and infected cells, were found to be equally active with respect to their abilities to translate cellular and viral mRNAs. The plasmacytoma cell-free system was also shown to be insensitive to the addition of double-stranded viral RNA. Host cellular mRNA was isolated from uninfected and infected cells. No difference in the amount or size distribution of the mRNA was detected. However, the mRNA from infected cells was translated only 46 to 49% as actively as that from uninfected cells. mRNA isolated from cells in which initiation of protein synthesis was inhibited with pactamycin was similarly inactivated. Simultaneous addition of viral RNA and cellular mRNA to the plasmacytoma cell-free system resulted in a complete suppression of the translation of the cellular message, whereas viral RNA was translated normally.     

Molecular cloning and phylogenetic analysis of the small cytoplasmic RNA from Listeria monocytogenes

A molecular cloning strategy has been designed to isolate the gene that encodes the small cytoplasmic RNA (scRNA) component of bacterial signal recognition particles. Using this strategy a putative Listeria monocytogenes scRNA lambda gt11 recombinant clone was isolated. A previously described complementation assay developed to genetically select functional homologues of 4.5S RNA and scRNA of bacteria confirmed that the lambda gt11 recombinant clone isolated encoded for the scRNA from L. monocytogenes. A secondary structure for this scRNA is proposed and a phylogenetic comparison of the 276 base L. monocytogenes scRNA with previously characterised Gram-positive bacterial scRNAs is also presented.     

Possible involvement of poly(A) in protein synthesis.

The experiments of this paper have re-evaluated the possibility that poly(A) is involved in protein synthesis by testing whether purified poly(A) might competitively inhibit in vitro protein synthesis in rabbit reticulocyte extracts. We have found that poly(A) inhibits the rate of translation of many different poly(A)+ mRNAs and that comparable inhibition is not observed with other ribopolymers. Inhibition by poly(A) preferentially affects the translation of adenylated mRNAs and can be overcome by increased mRNA concentrations or by translating mRNPs instead of mRNA. The extent of inhibition is dependent on the size of the competitor poly(A) as well as on the translation activity which a lysate has for poly(A)+ RNA. In light of our results and numerous experiments in the literature, we propose that poly(A) has a function in protein synthesis and that any role in the determination of mRNA stability is indirect.     

Inhibitory action of different RNA fractions on the translation of globin mRNA in vitro.

Preparations of 28S rRNA and 12S RNA, obtained from sheep lymphocytes, were shown to inhibit the translation of globin mRNA. An inhibition by a given amount of 12S or 28S RNA was only obvious at saturating or near saturating levels of globin mRNA, suggesting that the inhibitory RNAs interacted with some factor essential for protein synthesis other than mRNA. The inhibitory RNAs had no effect on the translation of the synthetic template polyuridylic acid. It is suggested therefore that the target for inhibitory RNAs might be a natural mRNA specific initiation factor.     

Partial characterizatio and proposed mode of action of inhibitory heLa cell surface polypeptides

Polypeptides removed from the HeLa cell surface by mild pronase treatment rapidly inhibit protein synthesis when added to HeLa cells or cell-free translation system derived from HeLa cells. The inhibitory activity is heat stable. Protein and carbohydrate components of these polypeptides are required for inhibition of protein synthesis in vivo and in vitro. Two peaks of activity can be recovered from polyacrylamide gels, corresponding to polypeptides with molecular weights of approximately 29 000 and 41 000. Inhibition of protein synthesis in cell-free translation systems appears to be primarily an effect on elongation of polypeptide chains, whereas in the intact cell the primary target may be polypeptide chain initiation.     

The DEAD-box RNA helicase Ded1p affects and accumulates in Saccharomyces cerevisiae P-bodies

Recent results suggest that cytoplasmic mRNAs can form translationally repressed messenger ribonucleoprotein particles (mRNPs) capable of decapping and degradation, or accumulation into cytoplasmic processing bodies (P-bodies), which can function as sites of mRNA storage. The proteins that function in transitions between the translationally repressed mRNPs that accumulate in P-bodies and mRNPs engaged in translation are largely unknown. Herein, we demonstrate that the yeast translation initiation factor Ded1p can localize to P-bodies. Moreover, depletion of Ded1p leads to defects in P-body formation. Overexpression of Ded1p results in increased size and number of P-bodies and inhibition of growth in a manner partially suppressed by loss of Pat1p, Dhh1p, or Lsm1p. Mutations that inactivate the ATPase activity of Ded1p increase the overexpression growth inhibition of Ded1p and prevent Ded1p from localizing in P-bodies. Combined with earlier work showing Ded1p can have a positive effect on translation, these results suggest that Ded1p is a bifunctional protein that can affect both translation initiation and P-body formation.