Isolation of myosin-synthesizing polysomes from cultures of embryonic chicken myoblasts before fusion.

Mononucleated myoblasts and multinucleated myotubes were obtained by culturing embryonic chicken skeletal muscle cells. Comparison of total polysomes isolated from these mononucleated and multinucleated cell cultures by density gradient centrifugation and electron microscopy revealed that mononucleated myoblasts contain polysomes similar to those contained by multinucleated myotubes and large enough to synthesize the 200,000-dalton subunit of myosin. When placed in an in vitro protein-synthesizing assay containing [³H]leucine, total polysomes from both mononucleated and multinucleated myogenic cultures were active in synthesizing polypeptides indistinguishable from myosin heavy chains as detected by measurement of radioactivity in slices through the myosin band on sodium dodecyl sulfate (SDS)-polyacrylamide gels. Fractionation of total polysomes on sucrose density gradients showed that myosin-synthesizing polysomes from mononucleated myoblasts may be slightly smaller than myosin-synthesizing polysomes from myotubes. Multinucleated myotubes contain approximately two times more myosin-synthesizing polysomes per unit of DNA than mononucleated myoblasts, and the proportion of total polysomes constituted by myosin polysomes is only 1.2 times higher in multinucleated myotubes than it is in mononucleated myoblasts. The results of this study suggest that mononucleated myoblasts contain significant amounts of myosin messenger RNA before the burst of myosin synthesis that accompanies muscle differentiation and that a portion of this messenger RNA is associated with ribosomes to form polysomes that will actively translate myosin heavy chains in an in vitro protein-synthesizing assay.     

Messenger ribonucleoprotein particles in developing sea urchin embryos

Messenger RNA entering polysomes during early development of the sea urchin embryo consists of both oogenetic and newly transcribed sequences. Newly transcribed mRNA enters polysomes rapidly while oogenetic mRNA enters polysomes from a pool of stable, nontranslatable messenger ribonucleoprotein particles (mRNPs) derived from the unfertilized egg. Protein content may relate to differences in the regulation of newly transcribed and oogenetic mRNAs. Oogenetic poly(A)⁺ mRNA was found to be present in both polysomal and subpolysomal fractions of cleavage stage and early blastula stage embryos. This mRNA was found to be present in subpolysomal mRNPs with a density of 1.45 g/cm³ in Cs₂SO₄. Poly(A)⁺ mRNPs released from polysomes of embryos cultured in the presence of actinomycin D sedimented in a broad peak centered at 55 S and contained RNA of 21 S. The density of these particles was sensitive to the method of release; puromycin-released mRNPs had a density of 1.45 g/cm³, while EDTA caused a shift in density to 1.55 g/cm³, indicating a partial loss of protein. The results with newly synthesized mRNAs contrast sharply. Newly transcribed mRNA in subpolysomal mRNPs had a density of 1.55–1.66 g/cm³, a density approaching that of deproteinized RNA. Messenger RNA released from polysomes either by EDTA or puromycin was examined to determine the possible existence of polysomal mRNPs. When [³H]uridine-labeled mRNA was released from late cleavage stage embryo polysomes by either technique, and centrifuged on sucrose gradients, two broad peaks were found. One peak centered at 30 S contained 21 S mRNA while the other at 15 S contained 9 S histone mRNA. When these fractions were fixed with formaldehyde, they banded on Cs₂SO₄ gradients at a density of 1.60–1.66 g/cm³, very similar to that of pure RNA. We conclude that the newly transcribed mRNA may be present in stable mRNPs containing up to 10% protein in either subpolysomal or polysomal fractions. These mRNPs are clearly distinguishable from the protein-rich mRNPs containing oogenetic mRNAs.     

Cytogenetic analysis of oocytes and early preimplantation embryos from XO mice.

The cytoplasm of early sea urchin embryos contains nonribosomal, high molecular weight RNA both associated with ribosomes in polysomes and free of ribosomes in particles termed free RNP. In a 1-hr labeling period, 50% of the newly synthesized RNA enters the pool of ribosome-free RNP particles during the cleavage stages, and this percentage decreases until less than 20% of the new RNA in the mesenchyme blastula stage is found in the free RNP. mRNA from both polysomes and free RNP contain poly(A)(+) and poly(A)(?) species. During the cleavage stages only 8–10% of the RNA from each fraction is polyadenylated; however, in the blastula, 40–50% of the nonhistone polysomal RNA is polyadenylated while only 22–30% of the free RNP RNA is polyadenylated. At any developmental stage, the poly(A)(+)RNA from the free RNA and polysomes have identical sedimentation profiles; this is also the case for the poly(A)(?)RNA except for the absence of the 9 S histone mRNA from the free RNP. Changes in poly(A)(+)RNA content and sedimentation profiles during development occur simultaneously in the free RNP and the polysomes. Kinetic studies of these two RNP populations as well as nuclear RNP show that the bulk of the free RNP are not unusually stable cytoplasmic components. The free RNP decay with a half-life of about 40 min while nuclear RNA and polysomal RNA display half-lives of about 12 and 65 min, respectively. Further, the rate of synthesis of the free RNP is not consistent with their being the only precursors for polysomes. Our estimates of the rates of synthesis for nuclear RNA, polysomes, and free RNP are, respectively, 1.1 × 10^?15, 2.2 × 10^?16, and 5.0 × 15^?17 g/min/nucleus. The data on free RNP is discussed in terms of translational regulation of protein synthesis in the developing sea urchin.     

Polyribosomes and messenger RNA from RAT liver mitochondria

Summary Rat liver mitochondrial polyribosomes were isolated free from cytoplasmic ribonucleoprotein contaminations in a number of criteria (sedimentation and buoyant density patterns, ribosomal RNA composition). Heterogeneous poly A containing RNA from mitochondrial polysomes was purified by two-stage cellulose chromatography. This RNA was in vitro labelled with¹²⁵I up to specific activity ~10⁶–10⁷ cts.min^–1.µg ^–1 and used for hybridization experiments with separate complementary strands of mitochondrial DNA and nuclear DNA fragments. The proportions of mitochondrial poly A containing RNA that is complementary to heavy and light strands of mtDNA were respectively 31.5% and 8.3%. Besides, a significant RNA fraction was complementary to unique sequences of nuclear DNA (2–3 copies per haploid genome). The hybrids that were formed possessed a high T_m indicative of a perfect base pairing. A dual intracellular origin of mitochondrial messenger RNA is discussed.     

Polysomes, Ribonucleic Acid, and Protein Synthesis During Germination of Neurospora crassa Conidia

The level of polysomes in ungerminated conidia of Neurospora crassa depends on the method used to collect spores. Spores harvested and exposed to hydration contain 30% of their ribosomes as polysomes, whereas those not exposed to hydration contain only 3% of their ribosomes as polysomes. During the germination process, the percentage of the ribosomes which sediment as polysomes increases rapidly to a level of approximately 75% during the first 15 to 30 min of germination. This rapid increase has been shown to require a carbon source. During the first 30 min of germination, spores synthesize ribosomal ribonucleic acid (RNA) and heterogeneously sedimenting RNA, i.e., presumptive messenger RNA.     

Newly Synthesized mRNA Is Translated during the Initial Imbibition Phase of Germinating Maize Embryo

RNA synthesis is activated in the cells of the plant embryo very soon after the start of seed imbibition. We previously reported that mainly heterogeneous nuclear RNA is synthesized in the radicle of Zea mays embryo during the first hours of germination. The present study was undertaken in order to detect the time of appearance of the newly synthesized messenger RNA in the polysomes of germinating maize axes.

Free polysomes were prepared from embryonic axes rehydrated for 2 hours in the presence of radioactively labeled uridine. These polysomes were shown to be labeled and to contain labeled particles sedimenting, after dissociation with EDTA, in the 10S to 40S region of a sucrose gradient. The labeled polysomal RNA migrates heterogeneously in a gel with a mean size corresponding to about 16S, and 60% of these molecules are polyadenylated.

The data indicate that the newly synthesized RNA associated with the polysomes after 2 h of germination consists of messenger RNA molecules. Analysis of the polysomes prepared 0.5 and 1 h after the start of imbibition suggests that translation of the newly synthesized messenger RNA probably occurs within the 1st hour of imbibition of the isolated axis, thus well before the completion of the initial water uptake.

     

Reverse transcription of thyroglobulin 33-S mRNA.

Bovine thyroglobulin 33-S mRNA has been used as a template for the synthesis of a complementary DNA, using RNA-directed DNA polymerase from the avian myeloblastosis virus. The yield of the reaction was relatively poor and the size of the cDNA did not exceed 10 S. Nevertheless, a copy of high specific radioactivity (approximately 10(7) counts. min-1 microgram-1) could be obtained which hybridized specifically back to its template with an rot1/2 value about 5 times higher than that observed in hybridizations between hemoglobin mRNA (alpha + beta chain) and hemoglobin cDNA. This suggests that thyroglobulin mRNA does not contain extensive internal repetitive sequences. Quantification of thyroglobulin mRNA sequences among various RNA preparations from the beef thyroid was performed using cDNA/RNA hybridizations in RNA excess. The results confirmed that thyroglobulin mRNA represents the large majority of mRNA in membrane-bound polysomes and indicated the virtual absence of thyroglobulin sequences on free polyosomes. The cDNA transcribed from mRNA of bovine origin hybridized efficiently with thyroid RNA from goats, dogs and humans. Although the heterologuous hybrids exhibited the expected decrease in thermal stability, the bovine cDNA provides an appropriate probe for studies dealing with the expression of the thyroglobulin gene in various mammals including man.     

Co-localization of polysomes,cytoskeleton, and membranes with protein bodies from corn endosperm

Summary Frozen corn endosperm was homogenized in a cytoskeleton-stabilizing buffer and stained directly (without pelleting) with rhodamine-phalloidin for actin and either thiazole orange to stain RNA or DiOC₆ to stain membranes prior to examination under the fluorescence microscope. Other samples were treated with a non-ionic detergent alone or in conjunction with a ionic detergent prior to staining and fluorescence microscopy. Very gentle homogenization in unsupplemented buffer yielded a massive aggregate containing protein bodies that fluoresced after treatment with the ER stain DiOC₆. This aggregate was capped by an aggregate of unstained starch grains. More vigorous homogenization yielded more disperse patterns showing almost identical co-localization of ER, actin and RNA (polysomes). Homogenization in buffer plus non-ionic detergent removed most of the membrane yet maintained co-localization of actin and polysomes, while homogenization in double detergent removed the last traces of membrane and actin, and released over 70% of the polysomes. We interpret these results to suggest that protein bodies are surrounded by membranes, cytoskeleton and RNA (polysomes) and that the majority of the polysomes are attached more firmly to the cytoskeleton than to the membrane. This provides evidence from fluorescence microscopy to supplement that from biochemical analyses for the existence of cytomatrix-bound polysomes in plants.Abbreviations CBP cytoskeleton-bound polysomes - CMBP cyto-matrix-bound polysomes - CSB cytoskeleton-stabilizing buffer - DOC sodium deoxycholate - DiOC₆ 3,3-dihexyloxacarbocyanine iodide - DTE dithioerythritol - MBP membrane-bound polysomes - FP free polysomes - PMSF phenylmethyl-sulfonyl fluoride - PTE polyoxy-ethylene-10-tridecyl ether - Rh-Ph rhodamine-phalloidin - TO thiazole orange - Tris tris-(hydroxymethyl) aminomethane     

Structure and function of rat liver polysome populations. I. Complexity, frequency distribution, and degree of uniqueness of free and membrane-bound polysomal polyadenylate-containing RNA populations

Free and membrane-bound polysomes were isolated from rat liver in high yields with minimal degradation, cross-contamination, or contamination by nuclear or nonpolysomal cytoplasmic ribonucleoprotein. Poly(A)+ RNA fractions isolated from free and bound polysomal RNA (poly(A)+ RNAfree and poly(A)+ RNAbound) by oligo(dT) cellulose chromatography exhibited number-average lengths of 1,600 and 1,200 nucleotides, respectively, on formamide sucrose gradients. Poly(A)+ RNAfree and poly(A)+ RNAbound contain 9.1 +/- 0.55 and 10.7 +/- 0.50% poly(A) as measured by hybridization to [3H]poly(U) and comprise 2.37 and 1.22% of their respective polysomal RNA populations. Homologous poly(A)+ RNA-cDNA hybridizations revealed that greater than 95% of the mass of poly(A)+ RNAfree and poly(A)+ RNAbound contain nucleotide complexities of about 3.4 x 10(7) and 6.0 x 10(6), respectively. This represents about 20,000 and 5,000 poly(A)+ RNA species of average sizes. Heterologous hybridizations suggested that considerable overlap exists between poly(A)+ RNAfree and poly(A)+ RNAbound sequences that cannot be attributed to cross-contamination. This was confirmed by conducting heterologous reactions using kinetically enriched cDNA populations. Heterologous hybridizations involving poly(A)+ RNA derived from tightly bound polysomes and cDNAfree indicated tha most of the overlapping sequences are not contributed by loosely bound (high-salt releasable) polysomes. The ramifications of these findings are discussed.     

Identification of mouse mammary tumor virus-specific mRNA.

Complementary DNA corresponding to the RNA genome of mouse mammary tumor virus was used to identify viral RNA contained in polysomes of a virus-producing mammary tumor cell line. Separation of polysomal mRNA by agarose gel electrophoresis, transfer of the RNA to diazobenzyloxymethyl paper, and hybridization with 32P-labeled mouse mammary tumor virus complementary DNA revealed three viral RNA size classes of 10, 8.8, and 4.4 kilobases in length, respectively.     

Influence of growth rate on protein synthesis and distribution of ribosomes in HeLa cells.

HeLa cells have been grown at different rates in steady-state continuous and semi-continuous culture. Slowly growing cells contain more protein and less RNA than rapidly growing cells, but appear to synthesize protein by less efficient use of the available RNA. The rate of RNA accumulation increases rapidly with increasing growth rate and rapidly growing cells contain more ribosomal subunits, and more and larger polysomes, but have fewer monoribosomes than slowly growing cells.     

Polyribosomes of Escherichia coli. I. Isolation of polysomes from a complex of DNA and membrane

Summary The distribution of pulse labeled RNA, pulse labeled protein, soluble enzyme (-galactosidase) and polyribosomes between low speed (10 min 20000xg) supernatant and pellet of E. coli lysates was examined. This distribution was greatly changed by addition of deoxyribonuclease to the lysing medium. Large amounts of polysomes sedimented with DNA at low centrifugal forces. A complex of membrane, DNA, polyribosomes and RNA polymerase could be separated from unlysed cells by surcrose gradient centrifugation. The polysomes present in this complex (Polysomes II) were separated from the polysomes which were found in the cytoplasma (Polysomes I). Polysomes II contain very few ribosomal subunits and 70S ribosomes.     

Undegraded vitellogenin polysomes from female insect fat bodies

Fat body cells of vitellogenic females of the cockroach $\text{Leucophaea maderae}$ contain a prominent population of large polysomes of approximately 35–40 ribosomes whereas fat bodies of non-vitellogenic females or males of any age do not have these polysomes. Anti-vitellogenin recognizes newly synthesized nascent vitellogenin associated with these large polysomes. Adenosine labelled RNA is likewise precipitated by anti-vitellogenin primarily in the region of this class of polysomes. It is concluded that the class of large polysomes represents the vitellogenin polysomes.     

Characterization of polysome-associated RNA from influenza virus-infected cells.

Virus-specific polysome-associated RNA (psRNA) and RNA after dissociation of polysomes were analyzed by direct hybridization with unlabeled viral RNA (vRNA) and complementary RNA (cRNA). psRNA after a 30-min pulse with [3H]uridine contained 28% labeled cRNA, 70% host RNA, and no vRNA. After dissociation, psRNA sedimented heterogeneously. Heavy RNA (greater than 60S), ribosomal subunit RNA (rsuRNA, 30-60S), free mRNA (fmRNA, 10-30S), and light RNA (less than 10S) contained 16%, 54%, 70% and 28% cRNA, respectively, but no vRNA. When actinomycin D (AcD) was added at 2 h postinfection, the nature of the psRNA depended on the concentration of AcD and the condition of the labeling. At AcD concentrations of 1 mug or more per ml, no detectable vRNA or cRNA was associated with polysomes. At 0.2 mug of AcD per ml (a concentration that partially inhibited cRNA synthesis) and 2 h of labeling at 2.5 h postinfection, psRNA contained 40% viral-specific RNA, which included both vRNA and cRNA in almost equal amounts. When polysomes were dissociated, however, viral-specific fm RNA from AcD-treated cells contained exclusively cRNA and no detectable vRNA. Increasing amounts of labeled vRNA were present in the heavy region of the gradient (and in the pellet), which also contained varying amounts of cRNA. The labeled vRNA appears to be associated with polysomes in a cesium chloride density gradient (rho = 1.525 g/ml). Although we have ruled out the trivial explanation of viral ribonucleoprotein contamination,the nature of the complex containing both polysomes and vRNA is unknown.     

Stored and polysomal ribosomes of mouse ova

RNP particles of ovulated mouse ova, labeled by exposure of growing oocytes to [³H]uridine, were displayed on sucrose gradients. Under standard salt conditions, radioactivity was observed coinciding with liver ribosomal subunits, monomers, and polysomes. The RNA from each region of the gradient was isolated and was found to contain the expected species of labeled 18S and/or 28S ribosomal RNA. Heterogeneous RNP particles were widely distributed in the gradient. From data on RNase sensitivity and resistance to dissociation in high salt, it was estimated that 20–25% of the total ribosomes were in polysomes. No difference in the distribution was observed when ribosomes were labeled in the early or late growth phase of the oocyte. The evidence suggested that the nonpolysomal subunits and monomers were unable to form a high salt-stable complex in the presence of poly(U) and factors for protein synthesis. Thus, the bulk of the ribosomes are inactive in protein synthesis in ovulated ova and are apparently stored for use in embryonic development.