Structure and function of rat liver polysome populations. II. Characterization of polyadenylate-containing mRNA associated with subpopulations of membrane-bound particles

Poly(A)+RNA fractions prepared from free and loosely and tightly membrane-bound polysome populations (poly(A)+RNAfree, poly(A)+RNAloose, and poly(A)+RNAtight) were used to drive cDNA in homologous and heterologous hybridization reactions. A large fraction by mass of sequences was shared among the three poly(A)+RNA populations, but shared sequences exhibited distinct frequency distributions within the different populations. 13-15 in vitro translation products of poly(A)+RNAfree and poly(A)+RNAloose detected by gel electrophoresis were shared. Most of these were produced in different relative quantities by the two RNA populations. Five or six higher mol wt polypeptides were produced by poly(A)+RNAloose that were not detected as products of either poly(A)+free or poly(A)+RNAtight. We suggest that loosely bound polysomes may not be artifactually derived as reflected in their quantitatively distinct poly(A)+RNA population. Two tightly membrane-bound RNP fractions were prepared from rat liver on the basis of their release from or retention on purified rough microsomes or a crude membrane fraction after in vitro disaggregation of polysomes with high-salt and puromycin. Homologous and heterologous hybridizations involving their poly(A)+RNA fractions revealed that a large portion by mass of sequences was shared but that these sequences exhibited distinct frequency distributions in the two fractions. The RNA fractions produced exhibited distinct frequency distributions in the two fractions. The RNA fractions produced an identical set of in vitro translation products but individual polypeptides were produced in different relative quantities. This indicates that the two RNP fractions do not arise by any random artifactual process and suggests that they may represent functionally distinct populations.     

Complex population of nonpolyadenylated messenger RNA in mouse brain

The complexity of nonadenylated mRNA [poly(A)-mRNA] has been determined by hybridization with single-copy DNA (scDNA) and cDNA. Our results show that poly(A)- and poly(A)+ mRNA are essentially nonoverlapping (nonhomologous) sequence populations of similar complexity. The sum of the complexities of poly(A)+ mRNA and poly(A)- mRNA is equal to that of total polysomal RNA or total mRNA, or the equivalent of approximately 1.7 x 10(5) different sequences 1.5 kb in length. Poly(A)- mRNA, isolated from polysomal RNA by benzoylated cellulose chromatography, hybridized with 3.6% of the scDNA, corresponding to a complexity of 7.8 x 10(4) different 1.5 kb sequences. The equivalent of only one adenosine tract of approximately 20 nucleotides per 100 poly(A)- mRNA molecules 1.5 kb in size was observed by hybridization with poly(U). cDNA was transcribed from poly(A)- mRNA using random oligonucleotides as primers. Only 1-2% of the single-copy fraction of this cDNA was hybridized using poly(A)+ mRNA as a driver. These results show that poly(A)- mRNA shares few sequences with poly(A)+ mRNA and thus constitutes a separate, complex class of messenger RNA. These measurements preclude the presence of a complex class of bimorphic mRNAs [that is, species present in both poly(A)+ and poly(A)- forms] in brain polysomes.     

Physical aspects and cytoplasmic distribution of messenger RNA in mouse kidney.

As a prerequisite to examining mRNA metabolism in compensatory renal hypertrophy, polyadenylated RNA has been purified from normal mouse kidney polysomal RNA by selection on oligo(dT)-cellulose. Poly(A)-containing RNA dissociated from polysomes by treatment with 10 mM EDTA and sedimented heterogeneously in dodecyl sulfate-containing sucrose density gradients with a mean sedimentation coefficient of 20 S. Poly(A) derived from this RNA migrated at the rate of 6-7 S RNA in dodecyl sulfate-containing 10% polyacrylamide gels. Coelectrophoresis of poly(A) labeled for 90 min with poly(A) labeled for 24 h indicated the long-term labeled poly(A) migrated faster than pulse-labeled material. Twenty percent of the cytoplasmic poly(A)-containing mRNA was not associated with the polysomes, but sedimented in the 40-80 S region (post-polysomal). Messenger RNA from the post-polysomal region had sedimentation properties similar to those of mRNA prepared from polysomes indicating post-polysomal mRNA was not degraded polysomal mRNA. Preliminary labeling experiments indicated a rapid equilibration of radioactivity between the polysomal and post-polysomal mRNA populations, suggesting the post-polysomal mRNA may consist of mRNA in transit to the polysomes.     

Stored Messenger Ribonucleoprotein Particles in Differentiated Sclerotia of Physarum polycephalum

Starvation induces vegetative microplasmodia of Physarum polycephalum to differentiate into translationally-dormant sclerotia. The existence and the biochemical nature of stored mRNA in sclerotia is examined in this report. The sclerotia contain about 50% of the poly(A)-containing RNA [poly(A)+RNA] complement of microplasmodia as determined by [³H]-poly(U) hybridization. The sclerotial poly(A)+RNA sequences are associated with proteins in a ribonucleoprotein complex [poly(A)+mRNP] which sediments more slowly than the polysomes. Sclerotial poly(A)+RNP sediments more rapidly than poly(A)+RNP derived from the polysomes of microplasmodia despite the occurrence of poly(A)+RNA molecules of a similar size in both particles suggesting the existence of differences in protein composition. Isolation of poly(A)+RNP by oligo (dT)-cellulose chromatography and the analysis of its associated proteins by polyacrylamide gel electrophoresis show that sclerotial poly(A)+RNP contains at least 14 major polypeptides, 11 of which are different in electrophoretic mobility from the polypeptides found in polysomal poly(A)+RNP. Three of the sclerotial poly(A)+RNP polypeptides are associated with the poly(A) sequence (18, 46, and 52 × 10³ mol. wt. components), while the remaining eight are presumably bound to non-poly(A) portions of the poly(A)+RNA. Although distinct from polysomal poly(A)+RNP, the sclerotial poly(A)+RNP is similar in sedimentation behavior and protein composition (with two exceptions) to the microplasmodial free cytoplasmic poly(A)+RNP. The results suggest that dormant sclerotia store mRNA sequences in association with a distinct set of proteins and that these proteins are similar to those associated with the free cytoplasmic poly(A)+RNP of vegetative plasmodia.     

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.     

Comparison of polysomal and nuclear poly(A)-containing RNA populations from normal rat liver and Novikoff hepatoma.

Polysomal and nuclear poly(A)-containing RNA of normal rat liver and Novikoff hepatoma cells have been compared by cDNA.RNA hybridization kinetics. Homologous hybridization reactions revealed at total kinetic complexity of about 1.6 X 10(10) and 1.38 X 10(10) daltons for liver and Novikoff mRNA respectively. The high abundance component present in liver cannot be detected in Novikoff. It was found from heterologous reactions that about 30% by weight of mRNA sequences are specific to liver. Determination of the nuclear poly(A)-containing RNA complexities revealed that about 5.5% and 4% of the haploid genome is expressed in the liver and Novikoff respectively. In a heterologous reaction, up to 30% of the liver cDNA failed to form hybrids with Novikoff nuclear RNA. Cross hybridizations have further revealed abundance shifts in both nuclear and polysomal RNA populations. Some sequences abundant in liver are less abundant in Novikoff and some rare liver sequences are relatively abundant in Novikoff.     

CHARACTERIZATION OF POLY(A) SEQUENCES IN BRAIN RNA

—Nuclear and polysomal brain RNA from the rabbit bind to Millipore filters and oligo(dT)-cellulose suggesting the presence of poly(A) sequences. The residual polynucleotide produced after RNase digestion of ³²P pulse-labelled brain RNA is 95% adenylic acid and 200-250 nucleotides in length. After longer isotope pulses the polysomal poly(A) sequence appears heterodisperse in size and shorter than the nuclear poly (A). Poly(A) sequences of brain RNA are located at the 3′-OH termini as determined by the periodate-[³H]NaBH₄ labelling technique. Cordycepin interferes with the processing of brain mRNA as it inhibits in vivo poly(A) synthesis by about 80% and decreases the appearance of rapidly labelled RNA in polysomes by about 45%. A small poly(A) molecule 10-30 nucleotides in length is present in rapidly labelled RNA. It appears to be less sensitive to cordycepin than the larger poly(A) and is not found in polysomal RNA.     

Protein synthesis directed by polyadenylated and non-polyadenylated RNA isolated from membrane-bound and free polysomes of Tetrahymena pyriformis

Free and membrane-bound polysomes were prepared from the protozoa Tetrahymena pyriformis using a procedure which gives good recovery and practically no cross-contamination. Polysomes are intact as analysed by sedimentation analysis. Poly(A)-rich RNA and poly(A)-free RNA, isolated from both populations of polysomes, show similar electrophoretic patterns. These RNAs were translated in the rabbit reticulocyte lysate cell-free system and the translation products were analysed by one-dimensional and two-dimensional gel electrophoresis. The most striking differences were found in the two-dimensional electrophoretic analysis namely: (a) a group of polypeptides (10) is synthesized mainly on membrane-bound polysomes, (b) a second abundant group is synthesized mainly in free polysomes (c) and a third class of polypeptides is synthesized on both kinds of polysomes. Poly(A)-free RNAs, isolated from free polysomes, are also able to promote synthesis of some polypeptides. The results are discussed taking into account the fact that T. pyriformis is a non-secretory cell.     

The preparation and characterization of locust vitellogenin messenger RNA and the synthesis of its complementary DNA.

Poly(A)+ (polyadenylated) RNA was isolated from vitellogenic female-locus fat-body by LiCl/urea extraction and poly(U)-Sepharose 4B affinity chromatography. Agarose-gel electrophoresis of this poly(A)+ RNA under denaturing conditions shows the presence of a high-molecular-weight species (greater than 31 S, 7100 nucleotides) as the major species, which is absent from the RNA prepared from male-locust fat-body. Inclusion of this poly(A)+ RNA in a mRNA-dependent reticulocyte-lysate system directs the synthesis of polypeptides that could be immunoprecipitated with monospecific antibodies against locust egg vitellin. DNA complementary (cDNA) to the poly(A)+ RNA was synthesized, and back-hybridization of the cDNA to its template reveals a major abundant species comprising about 45% of the total poly(A)+ RNA hybridizing with R0t 1/2 of 2 x 10(-2) mol . litre-1 . s. Abundant cDNA isolated from the total cDNA hybridizes to poly(A)+ RNA with a R0t 1/2 of 9 x 10(-3) mol . litre-1 . s. There are 9.1 x 10(3) copies of vitellogenin mRNA per cell of vitellogenic female-locust fat-body, comprising 55% of the poly(A)+ RNA and equivalent to 0.7% of total cellular RNA.     

Synthesis of RNA containing polyadenylic acid sequences in preimplantation rabbit embryos

Messenger RNA synthesis has been estimated by assaying polyadenylic acid (poly A)-rich sequences in heterogeneous RNA from preimplantation rabbit embryos. Poly A containing RNAs are synthesized at least as early as the 16-cell stage and continue to be made through blastocyst formation and maturation. Sixty to 78% of the heterogeneous polysomal RNA in blastocysts contain poly A sequences. The portion of the heterogeneous RNA containing poly A sequences does not appear to change markedly between cleavage and blastocyst stages of development. Poly Arich sequences are greater than 4 S and consist of at least 84% adenine residues. RNA molecules ranging from 6 S to greater than 28 S contain poly A sequences.     

Translated and sequestered untranslated message sequences in Drosophila oocytes and embryos.

Poly(A)-containing RNA sequences on polysomes were compared to poly(A)-containing sequences in sequestered nonpolysomal particles by cDNA hybridization. The results reported here show that the two fractions contain substantially the same sequences.     

Mouse ubiquitous B2 repeat in polysomal and cytoplasmic poly(A)+RNAs: uniderectional orientation and 3''-end localization.

A cDNA library in pBR322 was prepared with cytoplasmic poly(A)+RNA from mouse liver cells. From 1 to 1.5% of clones hybridized to either B1 or B2 ubiquitous repetitive sequences. Several clones hybridizing to a B2 repeat were partially sequenced. The full-length B2 sequence was found at the 3'-end of abundant 20S poly(A)+RNA (designated as B2+mRNAx) within the non-coding part of it. B2+mRNAx is concentrated in mouse liver polysomes and absent from cytoplasm of Ehrlich carcinoma cells. The B2 sequence seems to be located at the 3'-end of some other mRNAs as well. To determine the orientation of the B2 sequence in different RNAs, its two strands were labeled, electrophoretically separated, and used for hybridization with Northern blotts containing nuclear, cytoplasmic and polysomal RNAs. In nuclear RNA, the B2 sequence is present in both orientations; in polysomal and cytoplasmic poly(A)+RNAs, only one ("canonical") strand of it can be detected. Low molecular weight poly(A)+B2+RNA [1] also contains the same strand of the B2 element. The conclusion has been drawn that only one its strand can survive the processing. This strand contains promoter-like sequences and AATAAA blocks. The latter can be used in some cases by the cell as mRNA polyadenylation signals.     

Cellular titers and subcellular distributions of abundant polyadenylate-containing ribonucleic acid species during early development in the frog Xenopus laevis.

The distribution of cytoplasmic messenger ribonucleic acids (RNAs) in translationally active polysomes and inactive ribonucleoprotein particles changes during early development. Cellular levels and subcellular distributions have been determined for most messenger RNAs, but little is known about how individual sequences change. In this study, we used hybridization techniques with cloned sequences to measure the titers of 23 mitochondrial and non-mitochondrial polyadenylate-containing [poly(A)+]RNA species during early development in the frog Xenopus laevis. These RNA species were some of the most abundant cellular poly(A)+ RNA species in early embryos. The concentrations of most of the non-mitochondrial (cytoplasmic) RNAs remained constant in embryos during the first 10 h of development, although the concentrations of a few species increased. During neurulation, we detected several new poly(A)+ RNA sequences in polysomes, and with one possible exception the accumulation of these sequences was largely the result of new synthesis or de novo polyadenylation and not due to the recruitment of nonpolysomal (free ribonucleoprotein) poly(A)+ RNA. We measured the subcellular distributions of these RNA species in polysomes and free ribonucleoproteins during early development. In gastrulae, non-mitochondrial RNAs were distributed differentially between the two cell fractions; some RNA species were represented more in free ribonucleoproteins, and others were represented less. By the neurula stage this differential distribution in polysomes and free ribonucleoproteins was less pronounced, and we found species almost entirely in polysomes. Some poly(A)+ RNA species transcribed from the mitochondrial genome were localized within the mitochondria and were mapped to discrete fragments of the mitochondrial genome. Much of this poly(A)+ RNA was transcribed from the ribosomal locus. Nonribosomal mitochondrial poly(A)+ RNA species became enriched in polysome-like structures after fertilization, with time courses similar to the time course of mobilization of cytoplasmic poly(A)+ RNA.     

Isolation and translation in vitro of poly(A)+RNA from the free-living nematode Panagrellus silusiae.

Polysomal RNA was isolated from the free-living nematode Panagrellus silusiae. Passage of this RNA through a cellulose column resulted in the fractionation of the input RNA into poly(A)-RNA (ca. 97.5% of the total) and poly(A)+ RNA (ca. 2.5% of the total). RNase digestion, followed by polyacrylamide gel electrophoresis, revealed that the poly(A)+ RNA contained poly(A) tracts that ranged from 75 to 104 nucleotides in length with a mean value of about 90 residues. There was no evidence of poly(A) sequences in the poly(A)- RNA fraction. Poly(A)+ RNA gave a 25- to 50-fold stimulation (over background) of amino acid incorporation in the wheat germ cell-free protein-synthesizing system. At least 26 proteins were evident after electrophoresis in cylindrical sodium dodecyl sulfate-polyacrylamide gels. Poly(A)-RNA was capable of stimulating protein synthesis in vitro with about five discrete proteins being produced. In summary, the properties of mRNA from a simple organism such as P. silusiae are very similar to those of more complex eukaryotes.     

The isolation of cloned cDNA sequences which are differentially expressed in human lymphocytes and fibroblasts.

Poly(A)+ RNA populations derived from normal lymphocytes and fibroblasts have been compared by hybridising each RNA to cDNA derived from the other RNA population. This indicated that approximately 75% of the sequences were common to both, and that these were present at different concentrations in the two cell types. The two RNA populations were further compared by hybridising them to a cDNA recombinant library derived from lymphocyte poly(A)+ RNA. This allowed the identification of clones containing sequences which are abundant in lymphocyte poly(A)+ RNA but absent or rare in fibroblast poly(A)+ RNA. A direct estimation of the abundance of five of these sequences in lymphocyte cDNA demonstrated that clones can be detected by such a procedure if they represent 0.2% or greater of the original cDNA population.     

Frequency distribution of messenger sequences within polysomal mRNA and nuclear RNA from rat liver.

DNA complementary to polysomal poly(A)-containing mRNA (cDNA) of male rat liver was used to study the diversity of messenger sequences in the nucleus and in polysomes. 1. Hybridization of cDNA against an excess of its own polysomal mRNA template revealed that about 10,000 different mRNA species are expressed in the liver tissue. They are distributed in a wide frequency range derived from approximately 0.5% of the total genome. 2. Hybridization of the cDNA against total nuclear RNA shows that messenger sequences comprise less than 1% of the mass of total nuclear RNA. Messenger sequences have a different frequency distribution in nucleus and cytoplasm. 3. In hybridizations using cDNA, which had been fractionated into sequences representing abundant and scarce polysomal mRNA molecules, it was found that although abundant cytoplasmic messenger sequences are also abundant in the nucleus, they exist in a significantly lower frequency range in the nuclear compartment.     

Messenger RNA during early embryogenesis in Artemia salina: altered translatability and sequence complexity

RNA from developing embryos of Artemia salina (5, 10, and 20 h after re-initiation of development) was translated 3-10 times more efficiently in a rabbit reticulocyte lysate cell-free protein synthesizing system than RNA from dormant gastrulae. The latter did not appear to contain any significant amount of translation inhibitor activity. Ninety percent of the translatable activity in dormant gastrulae was recovered as poly(A)--RNA, whereas 80% of that in post-gastrular developing embryos was present as poly(A)+-RNA. The size of most polypeptides coded for by dormant gastrular RNA was less than 130,000 daltons whereas the size of those coded for by developing embryonic RNA was up to 200,000 daltons, which correlated with a corresponding shift to poly A-containing RNA of higher molecular weight. Two major polypeptides of about 37,000 daltons coded for by dormant gastrular RNA disappeared at 20 h after resumption of development. Hybridization of complementary DNA (cDNA) to a 1000-fold excess of the homologous poly(A)+-RNA revealed the presence of three complexity classes of mRNA. Forty-five percent, 30%, and 25% of RNA in dormant gastrulae were present as high, middle, and low abundance classes comprising about 10, 80, and 9700 species, respectively whereas in the nauplii there were 10, 150, and 7900 species of high, middle, and low abundancy sequences, respectively. Heterologous hybridizations using cDNA complementary to highly abundant messenger population of nauplii (isolated by chromatography on hydroxyapatite) to poly(A)+-RNA from dormant cysts showed considerably divergence in this class of messengers from the two developmental stages. Re-initiation of development of dormant Artemia gastrulae is thus characterized by a "re-programming" seen as a simultaneous and rapid increase in the polyadenylation and translatability of poly(A)+-RNA accompanied by a qualitative change in its sequence complexity.