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)     

Polysome-associated proteins in herpes simplex virus-infected cells

In the cytoplasm of eucaryotic cells, mRNA is associated with proteins. These mRNA-protein complexes, termed messenger ribonucleoprotein (mRNP) particles, are divided into two functional classes. The first class contains free (non-ribosome-associated) mRNPs which have been termed informosomes by others. The second class of mRNPs, those associated with polysomes, are actively engaged in protein synthesis and are termed polysomal mRNPs. The experiments described in this paper examined the proteins associated with polyribosomes in uninfected and herpes simplex virus type 1-infected cells. The data indicate that after infection with herpes simplex virus type 1, specific changes occur in the proteins which normally are found associated with these polysomal mRNPs. These changes include both the appearance of new and possibly virus-specific proteins and the loss of normal host-specific proteins. The relationship of these changes to the patterns of protein synthesis in these cells is also discussed.     

Cytoskeletal association of muscle-specific mRNAs in differentiating L6 rat myoblasts

The importance of the cytoskeleton in protein synthesis was studied in differentiating L6 rat myoblasts. Soluble and cytoskeletal fractions obtained after gentle, non-ionic detergent lysis of myoblasts and myotubes were analysed for the presence of ribosomes and mRNPs. Polysomal mRNPs were predominantly associated with the cytoskeletal framework and free mRNPs were present in both soluble and cytoskeletal fractions. An examination of the distribution of specific mRNAs in the polysomal and free mRNP populations of both cytoplasmic fractions revealed differences in the pattern of their distribution. It is further demonstrated that in the L6 rat myoblast system, ribosomes and mRNA (or mRNP) are not associated with the microfilaments, unlike in other systems studied.     

Specific mRNP complexes. Characterization of the proteins bound to histone H4 mRNAs isolated from L6 myoblasts

These studies were designed to identify the proteins associated with specific mRNAs. L6 myoblasts contain a unique poly(A)-rich H4 mRNA as well as poly(A)-minus H4 mRNA subspecies. We have characterized the proteins present in both poly(A)-rich and poly(A)-minus histone H4 mRNP complexes following ultraviolet cross-linking in vivo. In addition, the muscle-specific myosin heavy chain (MHC) mRNP complex was characterized in myoblasts. [35S]Methionine-labelled poly(A)-rich and poly(A)-minus RNP complexes were prepared from both the polysomal and free (post-polysomal) RNP compartments. From each fraction the mRNP encoding histone H4 or MHC was purified by hybrid selection to a cloned human histone H4 gene or MHC cDNA. A unique set of 6-16 proteins was found bound to each of the specific mRNP complexes. These proteins were a subset of the total population of either polysomal or free RNP proteins and some proteins appeared common among the different hybrid-selected RNP fractions. The results demonstrate that (a) mRNAs bind a different set of proteins depending upon whether they are present in the polysomal or free mRNP fraction; (b) the presence of poly(A) sequences affects the proteins which bind to H4 mRNA in the free RNP compartment.     

Cross-linked proteins associated with a specific mRNA in the cytoplasm of HeLa cells

Cytoplasmic messenger RNAs of eukaryotic cells are distributed between polysomal and post-polysomal fractions (free) as protein-bound complexes. These studies were designed to determine whether a specific mRNA isolated from different subcellular compartments is complexed with the same family of polypeptides. As a first approach we have examined the proteins associated with mRNA which codes for histone H4. To perform these experiments HeLa cells were exposed to ultraviolet light to cross-link in vivo polypeptides which are closely associated with nucleic acid. To identify the polypeptides associated with mRNA specific for histones a genomic probe for histone H4 mRNA was immobilized on epoxy-cellulose. By hybrid selection specific mRNPs containing histone mRNA were isolated. Our results reveal the existence of a number of polypeptides associated with both polysomal and post-polysomal histone mRNAs. In polysomal histone mRNA two polypeptides of Mr = 49 000 and 52 500 were the major components. In contrast polypeptides of Mr = 43 000 and 57 000 were the major polypeptide components of post-polysomal (or free) histone mRNA. Furthermore, these results also suggest that the polypeptides associated with either polysomal or free H4 histone mRNA represent a subset of proteins found in poly(A)-free fractions or poly(A)-rich mRNA fractions.     

Identification of the proteins in direct contact with duck globin mRNA

Proteins in direct contact with translationally active and repressed duck globin mRNA were determined by irradiating blood or lysates with ultraviolet light. Cross-linked proteins from polyribosomes and free mRNP particles were 14C-labeled by reductive methylation and identified on SDS-polyacrylamide gels upon autoradiography. Results indicate that ten cross-linked proteins are common to both polysomal and free mRNP, however, a 44 kDa protein appears to be specific for repressed mRNP particles. Furthermore, the notable lack of cross-linked proteins in the 20-30 kDa range in free mRNP supports the view that the characteristic low molecular mass 'prosomal' proteins, previously found associated with translationally repressed duck globin free mRNP [(1984) EMBO J. 3, 29-34], do not interact directly with the mRNA molecule.     

Characterization of mouse reticulocyte free globin mRNP

Globin messenger ribonucleoprotein particles (free and polysomal) from mouse reticulocyte lysates were characterized for their mRNA composition, translational activity as well as the proteins in direct contact with them. In contrast to the homogeneous single-peak distribution of rabbit and duck reticulocyte free mRNPs, mouse free mRNP particles were heterogeneously dispersed on the sucrose density gradient into two major domains called region I and region II. Region I appeared enriched with alpha-globin mRNP and region II with beta-globin mRNP. mRNP from both regions was translationally active. Examination of lysates prepared from beta-thalassemic mice revealed a reduction of translatable beta minor mRNP within region I, supporting the hypothesis of a compensatory recruitment of beta minor free mRNP into polysomes in beta-thalassemic mice.     

Translational active mRNPs from rabbit reticulocytes are qualitatively different from free mRNA in their translatability in cell-free system

The translatability of polyribosomal and free mRNPs from rabbit reticulocytes and their mRNA was compared. Both classes of mRNPs turned out to be active in rabbit reticulocyte lysates. Considerable differences between mRNPs and mRNA have been revealed. The most striking feature of mRNPs was that high concentrations of mRNPs do not inhibit protein biosynthesis, whereas high concentrations of mRNA strongly inhibit this process. This inhibition is specific for mRNA and does not occur at the addition of the same amount of rRNA from E. coli. The features of mRNP translation are not the result of addition of the supplementary translation factors within particles. The specific function of mRNP proteins in the process of translation is under discussion.     

Plant stress granules and mRNA processing bodies are distinct from heat stress granules

Similar to the situation in mammalian cells and yeast, messenger ribonucleo protein (mRNP) homeostasis in plant cells depends on rapid transitions between three functional states, i.e. translated mRNPs in polysomes, stored mRNPs and mRNPs under degradation. Studies in mammalian cells showed that whenever the dynamic exchange of the components between these states is disrupted, stalled mRNPs accumulate in cytoplasmic aggregates, such as stress granules (SGs) or processing bodies (PBs). We identified PBs and SGs in plant cells by detection of DCP1, DCP2 and XRN4, as marker proteins for the 5'-->3' mRNA degradation pathway, and eIF4E, as well as the RNA binding proteins RBP47 and UBP1, as marker proteins for stored mRNPs in SGs. Cycloheximide-inhibited translation, stress treatments and mutants defective in mRNP homeostasis were used to study the dynamic transitions of mRNPs between SGs and PBs. SGs and PBs can be clearly discriminated from the previously described heat stress granules (HSGs), which evidently do not contain mRNPs. Thus, the role of HSGs as putative mRNP storage sites must be revised.     

Adenosine diphosphate ribosyltransferase and protein acceptors associated with cytoplasmic free messenger ribonucleoprotein particles

ADP-ribosyltransferase activity has been characterized in free messenger ribonucleoprotein particles (mRNP) from mouse plasmacytoma cells. This enzymatic activity appears to be associated with the free mRNP and not due to nuclear contamination. The enzyme activity is not stimulated by added DNA or histone H1 and represents 34 per cent of the total cellular ADP-ribosyltransferase activity while the DNA contamination in free mRNP is less than 4 per cent of the total cellular DNA. Moreover, the ADP-ribosyltransferase specific activity per mg of DNA is about 75-fold higher in free mRNP than in the nuclei. During CsCl gradient centrifugation of the cytoplasmic fraction, the ADP-ribosylated material separates out at a buoyant density similar to that of free mRNP.This ADP-ribosyltransferase activity is inhibited by thymidine, nicotinamide and 3-aminobenzamide, while it is highly stimulated by exogenous pancreatic RNase. The in vitro synthesized acid insoluble material is rendered partly soluble by treatment by a proteolytic enzyme or by snake venom phosphodiesterase resulting in phosphoribosyl-AMP formation: the pancreatic RNase does not solubilize this material. Several ADP-ribosylated proteins are detected by lithium dodecylsulfate gel electrophoresis.Such an ADP-ribosyltransferase activity has also been detected in free mRNP from rat liver. It is suggested that this ADP-ribosylation of specific free mRNP proteins may be associated with free mRNP structure and/or with some chemical covalent type of modification rendering mRNA available for translation.     

Atomic force microscopy reveals binding of mRNA to microtubules mediated by two major mRNP proteins YB-1 and PABP

A significant fraction of mRNAs is known to be associated in the form of mRNPs with microtubules for active transport. However, little is known about the interaction between mRNPs and microtubules and most of previous works were focused on molecular motor:microtubule interactions. Here, we have identified, via high resolution atomic force microscopy imaging, a significant binding of mRNA to microtubules mediated by two major mRNP proteins, YB-1 and PABP. This interaction with microtubules could be of critical importance for active mRNP traffic and for mRNP granule formation. A similar role may be fulfilled by other cationic mRNA partners.     

Structural organization of mRNA complexes with major core mRNP protein YB-1

YB-1 is a universal major protein of cytoplasmic mRNPs, a member of the family of multifunctional cold shock domain proteins (CSD proteins). Depending on its amount on mRNA, YB-1 stimulates or inhibits mRNA translation. In this study, we have analyzed complexes formed in vitro at various YB-1 to mRNA ratios, including those typical for polysomal (translatable) and free (untranslatable) mRNPs. We have shown that at mRNA saturation with YB-1, this protein alone is sufficient to form mRNPs with the protein/RNA ratio and the sedimentation coefficient typical for natural mRNPs. These complexes are dynamic structures in which the protein can easily migrate from one mRNA molecule to another. Biochemical studies combined with atomic force microscopy and electron microscopy showed that mRNA–YB-1 complexes with a low YB-1/mRNA ratio typical for polysomal mRNPs are incompact; there, YB-1 binds to mRNA as a monomer with its both RNA-binding domains. At a high YB-1/mRNA ratio typical for untranslatable mRNPs, mRNA-bound YB-1 forms multimeric protein complexes where YB-1 binds to mRNA predominantly with its N-terminal part. A multimeric YB-1 comprises about twenty monomeric subunits; its molecular mass is about 700 kDa, and it packs a 600–700 nt mRNA segment on its surface.     

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)