The function of proteins that interact with mRNA

Specific proteins are associated with mRNA in the cytoplasm of eukaryotic cells. The complement of associated proteins depends upon whether the mRNA is an integral component of the polysomal complex being translated, or, alternatively, whether it is part of the non-translated free mRNP fraction. By subjecting cells to ultraviolet irradiation in vivo to cross-link proteins to mRNA, mRNP proteins have been shown to be associated with specific regions of the mRNA molecule. Examination of mRNP complexes containing a unique mRNA has suggested that not all mRNA contain the same family of associated RNA binding proteins. The function of mRNA associated proteins may include a role in providing stability for mRNA, and/or in modulating translation. With the recent demonstrations that both free and polysomal mRNPs are associated with the cytoskeletal framework, specific mRNP proteins may play a role in determining the subcellular localization of specific mRNPs.     

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)     

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.     

Membrane-bound ribosomes of myeloma cells. V. Subcellular distribution of immunoglobulin mRNA molecules

The subcellular distribution of the most abundant mRNA sequences, particularly those of the immunoglobulin heavy (Ig H) and light (IG L) chain mRNA sequences, of MOPC 21 (P3K) mouse myeloma cells has been examined by translating the mRNA of various subcellular fractions in a messenger-dependent reticulocyte lysate (MDL) and by identifying Ig products with the use of a specific antiserum. Analyses of the distribution of the mRNA template activity and the translation products by SDS polyacrylamide gel electrophoresis reveal that approximately 85% of the mRNA present in the free ribosomal fraction is incorporated into polysomes and that the remainder is present as mRNP particles. On the endoplasmic reticulum (ER) the mRNA is found entirely in polysomes. In general, the size class of free (F) and membrane-bound (MB) polysomes corresponds to the size of their translation products. Thus, mRNAs coding Ig H (5.0 x 10(5) daltons in size) and Ig L (2.5 x 10(5) daltons in size) are incorporated into polysomes formed of 12 and 6 ribosomes, respectively. About 10% of the Ig mRNAs are not bound to membranes. A third of these are associated with mRNPs and the remainder incorporated into F polysomes of the same size as the Ig-synthesizing MB polysomes.     

Translation of an mRNA in rat L6 muscle cells is regulated within the cell cycle

In muscle cells two populations of mRNA are present in the cytoplasm. The majority of mRNA is associated with ribosomes and active in protein synthesis. A small population of cytoplasmic mRNA occur as free mRNA-protein complex and is not associated with ribosomes. This apparently repressed population of mRNA from rat L6 myoblast cells was used to construct a cDNA library. Radioactively labeled cDNA preparations of polysomal and free (or repressed) mRNA populations showed that at least ten recombinant clones preferentially annealed to the cDNA from repressed mRNA. One of these clones was extensively studied. The DNA from a recombinant plasmid D12 hybridized to a 1.3-kb poly(A)-rich mRNA. In proliferating myoblast cells, the 1.3-kb mRNA was more abundant in the polysomal fraction and mostly free in the non-dividing myotubes. In contrast to this mRNA, 90% of alpha and beta actin mRNAs were translated in both myoblasts and myotubes. Further analysis of distribution of the 1.3-kb RNA in the polysomal (active) and free (repressed) fractions in fusion-arrested postmitotic myotubes suggested that fusion of myoblasts was not necessary for the control of translation of this mRNA. Withdrawal of muscle cells from the cell cycle appeared to be involved in regulating translation of this mRNA. The presence of this mRNA was not, however, limited to muscle cells. This mRNA was also present in the repressed state in rat liver and kidney cells. These results, therefore, suggest that the 1.3-kb mRNA is probably translated during a particular phase of the cell cycle and is not translated in terminally differentiated non-dividing cells. Messenger RNA homologous to the 600-base-pair insert of the recombinant plasmid D12 was isolated by hybrid selection procedure from both polysomal mRNA of myoblasts and free mRNA of myotubes. Translation of the hybrid selected mRNAs from both myoblasts and myotubes in rabbit reticulocyte lysate cell-free system synthesized a 40-kDa polypeptide. These results suggest that the repressed population of 1.3-kb mRNA can be translated in vitro. The hybridization pattern of DNA from the recombinant plasmid D12 with rat genomic DNA suggested that the 1.3-kb mRNA is derived from moderately repetitive rat DNA with a repetition frequency of approximately 100 copies per haploid genome.     

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)     

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.     

Characterization of 20-S and 40-S non-polysomal cytoplasmic messenger ribonucleoprotein particles from rat liver

Two populations of free messenger ribonucleoprotein (mRNP) particles, sedimenting at 20 S and 40 S respectively, were isolated from a rat liver postpolysomal supernatant. After treatment with 0.5 M KCl and recentrifugation through a sucrose layer, the mRNP particles were characterized with respect to their low-molecular-weight RNA and protein components. 40-S and 20-S particles show very different RNA patterns. Four distinct low-molecular-weight RNA species of approximately 105, 139, 187 and 256 nucleotides were found as components of the 40-S mRNPs. The 20-S mRNP particles contain one major low-Mr RNA species of approximately 243 nucleotides and a characteristic pattern of low-Mr RNAs similar to the one found in nuclear ribonucleoprotein particles. In contrast to the low-Mr RNAs found in nuclear RNP particles most of the low-Mr RNA species present in 20-S and 40-S mRNP particles are rapidly labeled after [3H]orotate administration. Whereas the low-Mr RNA composition of 20-S and 40-S mRNP particles is very different, the protein patterns of both mRNP complexes are very similar. Six major polypeptides with the following molecular weights of 117000, 79800, 76700, 53800, 43900, 36300 and several minor ones were found in both 20-S and 40-S mRNPs. In a cell-free system from wheat germs neither 20-S nor 40-S mRNP particles stimulated the incorporation of [3H]leucine into proteins. However, phenol-extracted RNA from 20-S and 40-S mRNPs stimulated total protein synthesis 16-fold and 3-fold, respectively. Furthermore, the RNA from both mRNP pools directed the synthesis of albumin in vitro.     

Translational regulation of ferritin synthesis in rat spleen: effects of iron and inflammation

Translational control of ferritin synthesis was studied in rat spleen, and compared with that for liver, heart and brain, in response to iron and inflammation. Spleen concentrations of total RNA in the ribonucleoprotein (mRNP) fraction was comparable to that for liver, while polyribosomal RNA was less. Both fractions were ten-fold lower in heart and brain. In untreated animals, the mRNP fraction of all tissues had the largest portion of the ferritin mRNA, as determined by slot blot hybridization with 32P-labeled cDNA for the L subunit. Acute treatment with ferric ammonium citrate shifted the spleen ferritin mRNA to the polyribosome fraction. This was also so in liver but not in the heart and brain which took up much less iron. The findings were confirmed by hybridization studies of mRNPs and polyribosomes separated in sucrose gradients. Turpentine-induced inflammation also caused a shift in ferritin mRNA from the mRNP to the polyribosome fraction of spleen and liver, over 12 h. We conclude that as in liver, spleen ferritin synthesis is under translational control by iron, and that both tissues also respond to inflammation by shifting of ferritin mRNA to the polyribosomes.     

A special repressor/activator system controls distribution of mRNA between translationally active and inactive mRNPs in rabbit reticulocytes

Translation of free mRNPs and polyribosomal mRNPs from rabbit reticulocytes was studied in a rabbit reticulocyte and wheat germ cell-free systems. It has been shown that translation efficiency of polyribosomal mRNPs and the mRNA isolated from the particles is nearly the same in both systems. At the same time, mRNP's translatability, which is high in the homologous cell-free system, is very low in the system from wheat germs. Translation efficiency of free mRNPs in the wheat germ system can be restored by addition of 0.5 M K CI-wash of rabbit reticulocyte ribosomes. The results testify to the existence of some special repressor repressor/activator system which controls the distribution of mRNA between free mRNPs and polyribosomes in rabbit reticulocytes.     

Biosynthesis of aldolase B by free ribosomes in rat liver

Free ribosomes and membrane-bound ribosomes were prepared from rat livers, and the contributions of these two types of ribosomes to the synthesis of aldolase B were studied by the immunoprecipitation of [3H]puromycin-labeled nascent peptides with a rabbit antibody to this enzyme. Although rat liver aldolase was recovered in both cytosolic and microsomal fractions by the fractionation of liver homogenate, the microsomal aldolase was immunologically identical with its cytosolic counterpart as confirmed by Ouchterlony immunodiffusion test. We examined the nascent peptide fractions prepared from free and bound ribosomes, and found that the nascent peptides of aldolase were mainly localized in free ribosomes. About 0.5% of the total nascent peptides of free ribosomes and 0.08% of those of bound ribosomes was aldolase. The site of synthesis of serum albumin was also examined as a reference standard by the immunoprecipitation of labeled nascent peptides, and the nascent peptides of this secretory protein were mainly associated with bound ribosomes, as reported by other workers. These observations confirm that aldolase B is mainly synthesized by free ribosomes in rat liver cells.     

Cytoskeleton-bound mRNA for a 40-kDa polypeptide in rat L6 cells is not always translated

The relationship between attachment of mRNA to the cytoskeletal framework and its translation was examined using the mRNA for a polypeptide of 40 kDa (P-40) which is translated in rat L6 myoblasts but not in the myotubes. In both myoblasts and myotubes this mRNA was found to be associated with the cytoskeletal framework. Furthermore, the stability of the association between P-40 mRNA and the cytoskeletal framework in absence of RNA and protein synthesis was examined by using actinomycin D and NaF to block RNA and protein synthesis, respectively. In absence of RNA synthesis portions of both nontranslated P-40 mRNA and translated actin mRNA of myotubes were released into the soluble fraction. In myoblasts, however, both mRNAs remained associated with the cytoskeletal framework following inhibition of RNA synthesis. Inhibition of protein synthesis, on the other hand, had a more dramatic effect on the association between the cytoskeletal framework and P-40 mRNA in myoblasts but not in myotubes. In contrast, the association between actin mRNA and cytoskeletal framework was unaffected by inhibition of protein synthesis in both myoblasts and myotubes. The results of these studies show that the molecular nature of association between cytoskeletal framework and mRNA may differ among mRNAs and may also depend on whether the cells are dividing or are terminally differentiated. Furthermore, no direct relationship between the translation of mRNA and its attachment to the cytoskeletal framework was observed.     

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.     

Ribosomal protein, histone and calmodulin mRNAs are differently regulated at the translational level during oogenesis of Xenopus laevis

The localization of r-protein mRNA in subcellular compartments has been analysed. It was observed that the mRNA for a representative r-protein (L1) is diffuse in the cytoplasm, as shown by in situ hybridization experiments and that the distribution of rp-mRNA between polysomes and light mRNPs changes during oogenesis. In early oogenesis this mRNA is found mostly in subpolysomal fractions, whereas at the beginning of vitellogenesis (stage II) it becomes associated with polysomes where it remains in a constant amount at later stages. Histone and calmodulin mRNA, on the contrary, are mostly associated with non-polysomal fast-sedimenting particles throughout oogenesis. This suggests that the partition of different classes of mRNA between polysomes, light mRNP and heavy particles depends on their nature and might be determined by different requirements for these mRNAs during oogenesis.     

Microtubule-dependent distribution of mRNA in adult cardiocytes

Synthesis of myofibrillar proteins in the diffusion-restricted adult cardiocyte requires microtubule-based active transport of mRNAs as part of messenger ribonucleoprotein particles (mRNPs) to translation sites adjacent to nascent myofibrils. This is especially important for compensatory hypertrophy in response to hemodynamic overloading. The hypothesis tested here is that excessive microtubule decoration by microtubule-associated protein 4 (MAP4) after cardiac pressure overloading could disrupt mRNP transport and thus hypertrophic growth. MAP4-overexpressing and pressure-overload hypertrophied adult feline cardiocytes were infected with an adenovirus encoding zipcode-binding protein 1-enhanced yellow fluorescent protein fusion protein, which is incorporated into mRNPs, to allow imaging of these particles. Speed and distance of particle movement were measured via time-lapse microscopy. Microtubule depolymerization was used to study microtubule-based transport and distribution of mRNPs. Protein synthesis was assessed as radioautographic incorporation of [3H]phenylalanine. After microtubule depolymerization, mRNPs persist only perinuclearly and apparent mRNP production and protein synthesis decrease. Reestablishing microtubules restores mRNP production and transport as well as protein synthesis. MAP4 overdecoration of microtubules via adenovirus infection in vitro or following pressure overloading in vivo reduces the speed and average distance of mRNP movement. Thus cardiocyte microtubules are required for mRNP transport and structural protein synthesis, and MAP4 decoration of microtubules, whether directly imposed or accompanying pressure-overload hypertrophy, causes disruption of mRNP transport and protein synthesis. The dense, highly MAP4-decorated microtubule network seen in severe pressure-overload hypertrophy both may cause contractile dysfunction and, perhaps even more importantly, may prevent a fully compensatory growth response to hemodynamic overloading.     

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.     

Statistical modeling of mRNP transport in dendrites: A comparative analysis of β-actin and Arc mRNP dynamics

Localization of messenger RNA (mRNA) in dendrites is crucial for regulating gene expression during long-term memory formation. mRNA binds to RNA-binding proteins (RBPs) to form messenger ribonucleoprotein (mRNP) complexes that are transported by motor proteins along microtubules to their target synapses. However, the dynamics by which mRNPs find their target locations in the dendrite have not been well understood. Here, we investigated the motion of endogenous β-actin and Arc mRNPs in dissociated mouse hippocampal neurons using the MS2 and PP7 stem-loop systems, respectively. By evaluating the statistical properties of mRNP movement, we found that the aging Lévy walk model effectively describes both β-actin and Arc mRNP transport in proximal dendrites. A critical difference between β-actin and Arc mRNPs was the aging time, the time lag between transport initiation and measurement initiation. The longer mean aging time of β-actin mRNP (~100 s) compared with that of Arc mRNP (~30 s) reflects the longer half-life of constitutively expressed β-actin mRNP. Furthermore, our model also permitted us to estimate the ratio of newly generated and pre-existing β-actin mRNPs in the dendrites. This study offers a robust theoretical framework for mRNP transport, which provides insight into how mRNPs locate their targets in neurons.