Kinetic estimation of the base sequence complexity of poly(A)-containing mRNA in Ehrlich-ascites-tumor cells and its abundance in nuclear RNA.

Poly(A)-containing messenger RNA was isolated from polysomes of Ehrlich ascites tumor cells, and analyzed for sequence complexity by hybridization to its complementary DNA. The results indicate the presence of about 27,000 diverse mRNA species in mouse Ehrlich ascites tumor cells. Total nuclear RNA was also hybridized to cDNA transcribed from polysomal poly(A)-containing mRNA up to an rot of 3,000 M . s. It was found that all classes of the polysomal poly(A)-containing mRNA sequences were also present in the nucleus, although the distribution varied. About 2% of the total nuclear RNA sequences were expressed as total polysomal poly(A)-containing mRNA. We also report that the total percentage of the haploid mouse genome transcribed in Ehrlich cells is significantly higher than that found in other mouse cells previously examined for poly(A)-containing mRNA sequence complexity.     

Utilization of polyadenylate mRNA during growth and starvation in Physarum polycephalum

The effect of growth on the efficiency of utilization of poly(A)-containing mRNA for translation has been investigated in microplasmodia of Physarum polycephalum. Measurement of the relative proportions of poly(A)-rich mRNA in polysomal and post-polysomal fractions isolated by sucrose density gradient centrifugation reveals that newly synthesized poly(A)-rich mRNA is present in increasing proportions in the polysomal region during exponential growth. However, the proportion of long-lived poly(A)-rich mRNA observed in actively-translating polysomes declines as starvation approaches. The ribonuclease content and morphology of the microplasmodia were monitored during growth and starvation in an effort to related this phenomenon to the onset of spherulation.     

Control of tyrosinase gene expression and its relationship to neural crest induction in Rana pipiens. I. Isolation and characterization of amphibian tyrosinase mRNA

Rana pipiens tyrosinase mRNA was isolated from Stage 22 (tailfin circulation) embryos by indirect immunoprecipitation of embryonic polysomes using highly specific rabbit anti-tyrosinase and goat-(anti-rabbit) immunoglobulins. Analysis on sucrose gradients indicated that anti-tyrosinase bound specifically to embryonic polysomes of the 300-350 S class coincident with the location of nascent tyrosinase enzyme activity and tyrosinase mRNA. These same anti-tyrosinase-bound polysomes were fully immunoprecipitated by the addition of goat-(anti-rabbit) IgG. Poly(A+) RNA was obtained from phenol-extracted antibody. polysome complexes by sequential passage over oligo(dT)-cellulose. The final purification of tyrosinase mRNA was achieved by preparative sucrose gradient fractionation. Tyrosinase mRNA sedimented as a single 13 S peak in 5-30% sucrose gradients and tracked on sodium dodecyl sulfate-polyacrylamide gels as a single band of 4.5 X 10(5) Da (1275 nucleotides). When assayed in a cell-free translation system, this mRNA directed the synthesis of a single 35,000-Da protein which co-migrated with native tyrosinase on sodium dodecyl sulfate-polyacrylamide gels and which was greater than 98% immunoprecipitable by anti-tyrosinase immunoglobulin. Final purification was 4103-fold over the starting polysomal RNA.     

Purification and properties of biologically active rainbow trout testis protamine mRNA.

At least two classes of protamine mRNA are present in both trout testis polysomal RNA and RNA from the postribosomal supernatant fraction of trout testis hormogenate both of which direct the synthesis of protamine in a Krebs II ascites S-30. One contains poly(A) tracts and the other is devoid of poly(A). Sucrose gradient analyses showed that the poly(A) containing protamine mRNA (poly(A) (+)) sedimented IN THE 6 S region with a shoulder in the 4 S region while the protamine mRNA devoid of poly(A) (poly(A) (-)) appeared to sediment at about 4 S and could not be resolved from tRNA. Analysis of the poly(A) (+) protamine mRNA by boundary sedimentation in an analytical ultracentrifuge showed a sedimentation coefficient of 5.7 S, a value which gives rise to an estimate of 165 to 170 nucleotides per molecule. The poly(A) (+) protamine mRNA migrated as a single species in formamide-containing polyacrylamide gels and its mobility in relation to markers of tRNA (4 S) and 5 S RNA was consistent with its sedimentation velocity of 6 S. The RNA present in the major band on an aqueous polyacrylamide gel was extracted and shown to code for protamine in a wheat germ cell-free system.     

Purification of messenger RNA coding for glycine methyltransferase from rat liver

Rat liver messenger RNA coding for glycine methyltransferase was associated preferentially with free polysomes. The mRNA was purified about 1000-fold over the total poly(A)-containing RNA by specific immunoadsorption of polysomes to protein A-Sepharose followed by oligo(dT)-cellulose column chromatography. Sodium dodecyl sulfate-gel electrophoresis of the in vitro translation products in a rabbit reticulocyte lysate system revealed only one major band which migrated to the position of the purified glycine methyltransferase subunit. The result shows that the mRNA isolated is nearly homogeneous and suggests that no precursor form of the enzyme existed. The mRNA sedimented at the position slightly smaller than 18 S rRNA in a sucrose density-gradient centrifugation and was shown to contain about 1,300 nucleotides by the Northern blot hybridization analysis with a cDNA probe.     

Isolation of rat liver albumin messenger RNA.

Rat liver albumin messenger RNA has been purified to apparent homogeneity by means of polysome immunoprecipitation and poly(U)-Sepharose affinity chromatography. Specific polysomes synthesizing albumin were separated from total liver polysomes through a double antibody technique which allowed isolation of a specific immunoprecipitate. The albumin-polysome immunoprecipitate was dissolved in detergent and the polysomal RNA was separated from protein by sucrose gradient centrifugation. Albumin mRNA was then separated from ribosomal RNA by affinity chromatography through the binding of poly(U)-Sepharose to the polyadenylate 3' terminus of the mRNA. Pure albumin mRNA migrated as an 18 S peak on 85% formamide-containing linear sucrose gradients and as a 22 S peak on 2.5% polyacrylamide gels in sodium dodecyl sulfate. It coded for the translation of authentic liver albumin when added to a heterologous protein-synthesizing cell-free system derived from either rabbit reticulocyte lysates or wheat germ extracts. Translation analysis in reticulocyte lysates indicated that albumin polysomes were purified approximately 9-fold from total liver polysomes, and that albumin mRNA was purified approximately 74-fold from albumin polysomal RNA. The total translation product in the mRNA-dependent wheat germ system, upon addition of the pure mRNA, was identified as authentic albumin by means of gel electrophoresis and tryptic peptide chromatography.     

Isolation and characterization of poly(adenylic acid)-containing messenger ribonucleic acid from rat liver polysomes

Undegraded rat liver polysomes were obtained after homogenizing the tissue in a medium containing NH4Cl, heparine, and yeast tRNA. Purification of poly(A)-containing RNA from polysomal RNA was accomplished by affinity chromatography on oligo(dT)-cellulose columns. Poly(A)-containing RNA molecules were monitored by the formation of ribonuclease-resistant hybrids with [3H]poly(U). To improve the separation of messenger RNA and ribosomal RNA by oligo(dT)-cellulose it was found essential to dissociate the aggregates formed between both molecular species by heat treatment in the presence of dimethylsulfoxide (Me2SO) prior to chromatography. Sucrose gradient analysis under denaturing conditions showed that the preparations obtained were virtually free of ribosomal RNA. Poly(A)-containing RNA constituted approx. 2.2% of the total polysomal RNA and the number average size was 1500--1800 nucleotides, as judged by sedimentation analysis on sucrose density gradients containing Me2SO. Approximately 8.2% of the purified preparation obtained was able to anneal with [3H]poly(U); the number average nucleotide length of the poly(A) segment of the RNA population was calculated to be 133 adenylate residues. Based on these values, our preparations appear to be greater than 90% pure. The RNA fractions obtained after oligo(dT)-cellulose chromatography were used to direct the synthesis of liver polypeptides in a heterologous cell-free system derived from wheat-germ. The system was optimized with respect to monovalent and divalent cations, and presence of polyamines (spermine). More than 65% of the translational activity present in the unfractionated polysomal RNA was recovered in the final poly(A)-containing RNA fraction. However, about 25% of the activity was found to be associated with the unbound fraction which was essentially free of poly(A)-containing RNA. Immunoprecipitation analysis with a specific antiserum to rat serum albumin demonstrated that about 6--8% of the labeled synthetic products translated from the poly(A)-containing RNA sample corresponded to serum albumin. Analysis of the translation products by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed a heterogeneous distribution of molecular sizes ranging from 15 000 to greater than 70 000 daltons. Spermine not only increased the overall yield and extent of protein synthesis, but also resulted in higher yields of large protein products. Under optimal translation conditions a discrete peak representing about 7% of the total radioactivity was observed to migrate with rat serum albumin.     

Association of poly(adenylate)-deficient messenger ribonucleic acid with membranes in mouse kidney

To describe further the metabolism of messenger ribonucleic acid (mRNA) in mouse kidney, we examined newly synthesized mRNA deficient in poly(adenylate) [poly(A)]. Approximately 50% of renal polysomal mRNA that labeled selectively in the presence of the pyrimidine analogue 5-fluoroorotic acid lacks or is deficient in poly(A) as defined by its ability to bind to poly(A) affinity columns. Nearly one-half of this poly(A)-deficient mRNA is associated uniquely with a cellular membrane fraction detected by sedimentation of renal cytoplasm in sucrose density gradients containing EDTA and nonionic detergents. Poly(A+) mRNA and poly(A)-deficient mRNA [poly(A-) mRNA] have similar modal sedimentation coefficients (20-22 S) and similar cytoplasmic distribution. Although 95% of newly synthesized poly(A+) mRNA is released in 10 mM EDTA as 20-90 S ribonucleoproteins from polysomes greater than 80 S, only 55% of poly(A)-deficient mRNA is released under the same conditions. Poly(A)-deficient mRNA recovered from greater than 80 S ribonucleoproteins resistant to EDTA treatment lacks ribosomal RNA, is similar in size to poly(A+) mRNA, and is associated with membranous structures, since 70% of poly(A)-deficient mRNA in EDTA-resistant ribonucleoproteins is released into the 20-80 S region by solubilizing membranes with 1% Triton X-100. These membrane-associated renal poly(A-) mRNAs could have unique coding or regulatory functions.     

The effect of age on the properties of poly(A)-containing messenger RNA in Physarum polycephalum

The effect of ageing on the properties of polysomal poly(A)-containing messenger RNA [poly(A)+ mRNA] of Physarum polycephalum has been investigated. Using poly(U)--Sepharose affinity chromatography it was shown that shortening of the poly(A) tract occurred as the age of the mRNA population increased. Analysis of the poly(A) segments by use of polyacrylamide gel electrophoresis, after digestion of polysomal poly(A)+ mRNA molecules with RNAase A and RNAase T1, revealed that their lengths ranged from 140 to 220 nucleotide residues. A reduction in the efficiency of utilization of mRNA for translation as the age of the mRNA population increased was demonstrated by measuring the proportion of poly(A)+ mRNA present in the polysomal fraction as compared with post-polysomal material.     

A simple procedure for the isolation and purification of protamine messenger ribonucleic acid from trout testis.

Preparation of milligram quantities of purified poly(A)+ (polyadenylated) protamine mRNA from trout testis tissue was accomplished by a simple procedure using gentle conditions. This involves chromatography of the total nucleic acids isolated by dissociation of polyribosomes with 25 mM-EDTA to release messenger ribonucleoprotein particles and deproteinization of the total postmitochondrial supernatant with 0.5% sodium dodecyl sulphate in 0.25 M-NaCl by binding it to a DEAE-cellulose column. Total RNA was bound under these conditions, and low-molecular-weight RNA, lacking 18S and 28S RNA, could be eluted with 0.5 M-NaCl and chromatographed on oligo(dT)-cellulose columns to select for poly(A)+ RNA. Further purification of both the unbound poly(A)- RNA and the bound poly(A)+ mRNA on sucrose density gradients showed that both 18S and 28S rRNA were absent, being removed during the DEAE-cellulose chromatography step. Poly(A)- RNA sedimented in the 4S region whereas the bound poly(A)+ RNA fraction showed a main peak at 6S [poly(A+) protamine mRNA] and a shoulder in the 3-4S region. Analysis of the main peak and the shoulder on a second gradient showed that most of the main peak sedimented at 6S, whereas the shoulder sedimented slower than 4S. The identity of the poly(A)+ protamine mRNA was established by the following criteria: (1) purified protamine mRNA migrated as a set of four bands on urea/polyacrylamide-gel electrophoresis; (2) analysis of the polypeptides synthesized in the wheat-germ extract by starch-gel electrophoresis showed a single band of radioactivity which co-migrated exactly with the carrier trout testis protamine standard; and (3) chromatography of the polypeptide products on CM-cellulose (CM-52) showed the presence of three or four radioactively labelled protamine components that were co-eluted with the unlabelled trout testis protamine components added as carrier. The availability of large quantities of purified protamine mRNA should now permit a more thorough analysis of its physical and chemical properties.     

Translation and identification of the viral mRNA species isolated from subcellular fractions of vesicular stomatitis virus-infected cells.

The cytoplasm of vesicular stomatitis virus (VSV)-infected BHK cells has been separated into a fraction containing the membrane-bound polysomes and the remaining supernatant fraction. Total poly(A)-containing RNA was isolated from each fraction and purified. A 17S class of VSV mRNA was found associated almost exclusively with the membrane-bound polysomes, whereas 14,5S and 12S RNAs were found mostly in the postmembrane cytoplasmic supernatant. Poly(A)-containing VSV RNA synthesized in vitro by purified virus was resolved into the same size classes. The individual RNA fractions isolated from VSV-infected cells or synthesized in vitro were translated in cell-free extracts of wheat germ, and their polypeptide products were compared by sodium dodecyl sulfate-polyacrylamide slab gel electrophoresis. The corresponding in vivo and in vitro RNA fractions qualitatively direct the synthesis of the same viral polypeptides and therefore appear to contain the same mRNA species. By tryptic peptide analysis of their translation products, the in vivo VSV mRNA species have been identified. The 17S RNA, which is compartmentalized on membrane-bound polysomes, codes for a protein of molecular weight 63,000 (P-63) which is most probably a nonglycosylated form of the viral glycoprotein, G. Of the viral RNA species present in the remaining cytoplasmic supernatant, the 14.5S RNA codes almost exclusively for the N protein, whereas the 12S RNA codes predominantly for both the NS and M proteins of the virion.     

Polyadenylic acid-containing RNA and its polyadenylic acid sequences newly synthesized in isolated embryonic cells of Xenopus laevis.

Newly synthesized polyriboadenylic acid [poly(A)]-containing RNA and its poly(A) sequences were isolated and characterized in Xenopus embryonic cells. Upon sedimentation analysis, the poly(A)-containing RNA labeled for 30 min showed a very heterogeneous size distribution ranging from 9 to >40 S. After 5 hr of labeling, the profile became much less heterogeneous and the main component was distributed in the 9–28 S region. The average molecular weight of 6.5–7.0 × 10⁵ daltons was calculated for the 5-hr labeled RNA. This poly(A)-containing RNA, comprising about 10% of the total labeled RNA, was metabolically stable and accumulated linearly for 5 hr. Gel electrophoresis of the RNA revealed the presence of little or no free poly(A) sequences. Most of the poly(A) sequences, which were isolated from 30-min labeled poly(A)-containing RNA migrated as a single discrete component approximately 150 nucleotides long. In contrast, they were slightly smaller (130 nucleotides long) and more heterogeneous, when obtained from the poly(A)-containing RNA labeled for 5 hr. From these results, it may be likely that the embryonic poly(A)-containing RNA is similar in size to the steady-state population of the poly(A)-containing RNA reported to occur in vitellogenic oocytes and cultured kidney cells of the same species.     

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.     

The synthesis of polyadenylic acid-containing ribonucleic acid by isolated mitochondria from Ehrlich ascites cells.

The synthesis of poly(A)-containing RNA by isolated mitochondria from Ehrlich ascites cells was studied. Isolated mitochondria incorporate [3H]AMP or [3H]UTP into an RNA species that adsorbs on oligo (dT)-cellulose columns or Millipore filters. Hydrolysis of the poly(A)-containing RNA with pancreatic and T1 ribonucleases released a poly(A) sequence that had an electrophoretic mobility slightly faster than 4SE. In comparison, ascites-cell cytosolic poly(A)-containing RNA had a poly(A) tail that had an electrophoretic mobility of about 7SE. Sensitivity of the incorporation of [3H]AMP into poly(A)-containing RNA to ethidium bromide and to atractyloside and lack of sensitivity to immobilized ribonuclease added to the mitochondria after incubation indicated that the site of incorporation was mitochondrial. The poly(A)-containing RNA sedimented with a peak of about 18S, with much material of higher s value. After denaturation at 70 degrees C for 5 min the poly(A)-containing RNA separated into two components of 12S and 16S on a 5-20% (w/v) sucrose density gradient at 4 degrees C, or at 4 degrees and 25 degrees C in the presence of formaldehyde. Poly(A)-containing RNA synthesized in the presence of ethidium bromide sedimented at 5-10S in a 15-33% (w/v) sucrose density gradient at 24 degrees C. The poly(A) tail of this RNA was smaller than that synthesized in the absence of ethidium bromide. The size of the poly(A)-containing RNA (approx. 1300 nucleotides) is about the length necessary for that of mRNA species for the products of mitochondrial protein synthesis observed by ourselves and others.     

Polysomal and non-polysomal messenger RNA in neuroblastoma cells: Lack of correlation between polyadenylation or initiation efficiency and messenger RNA location

Neuroblastoma cytoplasm was fractionated on sucrose gradients into polysomes (>90 S) and non-polysomal particles (<90 S). Purified RNA from these fractions was translated using a wheat germ lysate and translation products were compared by two-dimensional gel electrophoresis. Non-polysomal messenger RNA directed the synthesis of a specific subset of polysomal mRNA translation products. Careful comparison of individual translation products demonstrated that specific mRNAs were not randomly distributed between polysomes and the non-polysomal fraction.Fractionation of both RNA populations into polyadenylated (poly(A)⁺) and non-adenylated (poly(A)^?) species indicated that specific, abundant non-polysomal mRNAs were not less adenylated than their polysomal counterparts. Furthermore, comparison of translation products from assays of subsaturating and supersaturating RNA concentrations demonstrated that no simple correlation could be made between the relative initiation efficiency of a specific mRNA and its distribution between polysomes and non-polysomal particles.     

Cytoplasmic distribution of pulse-labelled poly(A)-containing RNA,particularly 26 S RNA,during myoblast growth and differentiation

Total poly(A)-containing RNA in different polysomal and supernatant cytoplasmic fractions was analysed after pulse-labelling in dividing myoblasts and fused myotubes. In particular, the peak of 26 S RNA (putative messenger for the large subunit of myosin) is located in a light region of the gradient coinciding with the monosome-trisome fractions prior to fusion, and is found in the heavy polysomes only after fusion. These heavy polysomes are free (i.e. not membrane bound). Treatment of the light part of the polysome gradient with EDTA shows that the 26 S RNA found here does not exist as part of a polysomal complex, but is present as a ribonucleoprotein particle cosedimenting in this region. Previous experiments had indicated that in actively dividing myoblasts 26 S RNA has a relatively short half-life but that it becomes “stable” after the cessation of mitosis just prior to fusion. RNA chase experiments performed in the present study show that the “short-lived” 26 S RNA from dividing myoblasts, which is present as a ribonucleoprotein particle, does not enter the heavy polysomes. In contrast, the more stable 26 S RNA also initially present as a ribonucleoprotein, just prior to and in the early stages of fusion, can be shown by chase experiments to enter the heavy polysomes later in fusion. Hence accumulation of 26 S RNA seems to precede its activation as a messenger.     

Metabolism of Poly(A) in Plant Cells: Discrete Classes Associated with Free and Membrane-bound Polysomes

In the subapical region of dark-grown pea epicotyls about 40% of the total polysomes are associated with membranes. The presence of poly(A) in polysomal mRNA was detected by hybridization of unlabeled RNA with (3)H-poly(U). Both free mRNA and messenger ribonucleoprotein particles in polysomes hybridize with (3)H-poly(U) quantitatively. The binding of (3)H-poly(U) to polysomes is increased by treatment with the detergent sodium dodecyl sulfate. Since detergent influenced the (3)H-poly(U) binding more in membrane-bound polysomes than in free, there may be more protein(s) associated with the poly(A) portion of the mRNA in membrane-bound polysomes. Analysis of the poly(A) segments isolated from the mRNA of these two classes of polysomes indicates that there are discrete classes of poly(A) and they appear to be differentially associated with free and membrane-bound polysomes. Mean size distribution of poly(A) in free polysomes is larger than in membrane-bound polysomes.Following treatment (2 days) with the plant growth hormone indoleacetic acid, there is a gradual decrease in the mean length of total poly(A), which appears to correspond to a decrease in the size of the polysomes and their associated mRNA.     

Purification of the mRNAs for Ewe alphaS-casein and beta-casein by immunoprecipitation of polysomes.

Specific polysomes synthesizing alphas-casein and beta-casein were immunoprecipitated from total polysomes of the lactating ewe mammary gland. The polysome - anti-casein complex was immunoprecipitated by anti-immunoglobulins. 22%, 32% and 10% of polysomes were immunoprecipitated with saturating amounts of anti-alphas-casein, anti-beta-casein and anti-chi-casein respectively. Poly(U)-Sepharose chromatography of the immunoprecipitated RNAs permitted the isolation of the corresponding poly(A)-containing RNA which migrated as one major band in polyacrylamide gel electrophoresis. As judged by the contamination with the messenger activity for one of the other caseins, the purity of the mRNA for alphas-casein as well as for beta-casein was estimated to be between 75% and 80%.