Sequence content of oligo(uridylic acid)-containing messenger ribonucleic acid from HeLa cells

Oligo(uridylic acid)-containing [oligo(U+)] RNA was isolated from poly(adenylic acid)-containing [poly(A+)] mRNA from HeLa cells by using either formaldehyde pretreatment or poly(A) removal, both of which resulted in increased accessibility of oligo(U)-rich sequences to a poly(A)-agarose affinity column. In this report, we compared the sequence content of oligo(U+) RNA with that of molecules lacking oligo(U) [oligo(U-) RNA] by their relative hybridization to cDNA reverse-transcribed from poly(A+) mRNA and by comparison of their in vitro translation products synthesized in a rabbit reticulocyte lysate. Formaldehyde-modified poly(A+) RNA, treated to remove the formol adjuncts, was inactive as a template for in vitro protein synthesis; consequently, only depolyadenylated RNA, which retains its translatability, could be used in the translation studies. The hybridization kinetic experiments revealed that oligo(U+) RNA contained most of the sequence information present in oligo(U-) RNA but at a reduced level (ca. 25%), the majority of the oligo(U+) RNA sequences being poorly represented in the cDNA. This result was supported by one- and two-dimensional gel analysis of their in vitro translation products which showed that oligo(U+) RNA, although less effective as a template for translation than oligo(U-) RNA, coded for proteins, the most abundant of which were encoded by rare messages not highly represented in oligo(U-) RNA or the total poly(A+) RNA. Although some minor products were synthesized by both oligo(U+) and oligo(U-) RNA, at least 33 proteins were unique to or highly enriched in the pattern of products directed by oligo(U+) RNA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Multiple oligo(A) tracts associated with inactive sea urchin maternal mRNA sequences

Maternal RNA of sea urchin eggs and embryos was analyzed for short poly(A) sequences by digesting hybrids formed between [³H]poly(U) and poly(A) with RNase at 4°C. When the undigested [³H]poly(U) is precipitated with CTAB, all (A)_n tracts longer than 6 nucleotides are detected. This assay revealed a poly(A) content severalfold higher than is obtained with a similar assay using RNase at higher temperatures. On polyacrylamide gel electrophoresis, most of the previously undetected (A)_n tracts ran as a peak of oligo(A) of less than 20 nucleotides which accumulated at the dye front. The oligo(A) sequences were resolved into a single peak of (A)₁₀ when sized on Sephadex G100. These (A)₁₀ sequences were associated with large mRNA-sized molecules of about 3000 nucloetides average length which comprised 0.5 to 2% of the total maternal RNA. However, the (A)₁₀ sequences were not in mRNA molecules containing 3′-terminal poly(A) of 50–120 nucleotides nor did they remain in RNA that entered polysomes upon fertilization. However, hybridization studies showed that all sequences represented in the maternal poly(A)-containing RNA appeared to be present in the RNA molecules containing only (A)₁₀ sequences. The results suggest that the (A)₁₀-containing RNA might be incompletely processed mRNA precursor-like molecules.     

Oligo(A) and double-stranded segments in polyadenylated and non-polyadenylated RNA from cytoplasm and nuclei of chick embryo

Chick embryonic RNA was fractionated by affinity chromatography on oligo(dT)-cellulose and poly(U)-Sepharose into three classes: poly(A)+RNA containing poly(A) segments of 100 and more residues, poly(A)-oligo(A)+RNA containing oligo(A) segments of about 25 residues, and poly(A)-oligo(A)-RNA which bound to neither of the beds used and which contained double-stranded segments of 300 and more base pairs. These three classes of RNA were found in cytoplasmic as well as in heterogeneous nuclear RNA. Double-stranded segments in hnRNA, unlike those in cytoplasmic RNA, were intermolecular in nature; this may explain the occurrence of "giant" molecules in hnRNA.     

Complexity and characterization of polyadenylated RNA in the mouse brain

The complexity of nuclear RNA, poly(A)hnRNA, poly(A)mRNA, and total poly(A)RNA from mouse brain has been measured by saturation hybridization with nonrepeated DNA. These DNA populations were complementary, respectively, to 21, 13.5, 3.8, and 13.3% of the DNA. From the RNA Cot required to achieve half-sturation, it was estimated that about 2.5–3% of the mass of total nuclear RNA constituted most of the complexity. Similarly, complexity driver molecules constituted 6–7% of the mass of the poly(A)hnRNA. 75–80% of the poly(A)mRNA diversity is contained in an estimated 4–5% of the mass of this mRNA. Poly(A)hnRNA constituted about 20% of the mass of nuclear RNA and was comprised of molecules which sedimented in DMSO-sucrose gradients largely between 16S and 60S. The number average size of poly(A)hnRNA determined by sedimentation, electron microscopy, or poly(A) content was 4200–4800 nucleotides. Poly(A)mRNA constituted about 2% of the total polysomal RNA, and the number average size was 1100–1400 nucleotides. The complexity of whole cell poly(A)RNA, which contains both poly(A)hnRNA and poly(A)mRNA populations, was the same as poly(A)hnRNA. This implies that cytoplasmic polyadenylation does not occur to any apparent qualitative extent and that poly(A)mRNA is a subset of the poly(A)hnRNA population. The complexity of poly(A)hnRNA and poly(A)mRNA in kilobases was 5 × 10⁵ and 1.4 × 10⁵, respectively. DNA which hybridized with poly(A)mRNA renatures in the presence of excess total DNA at the same rate as nonrepetitive tracer DNA. Hence saturation values are due to hybridization with nonrepeated DNA and are therefore a direct measure of the sequence complexity of poly(A)mRNA. These results indicate that the nonrepeated sequence complexity of the poly(A)mRNA population is equal to about one fourth that observed for poly(A)hnRNA.     

5'-terminal structures of poly(A)+ cytoplasmic messenger RNA and of poly(A)+ and poly(A)- heterogeneous nuclear RNA of cells of the dipteran Drosophila melanogaster.

Structures at the 5′ terminus of poly (A)-containing cytoplasmic RNA and heterogeneous nuclear RNA containing and lacking poly(A) have been examined in RNA extracted from both normal and heat-shocked Drosophila cells. ³²P-labeled RNA was digested with ribonucleases T₂, T₁ and A and the products fractionated by a fingerprinting procedure which separates both unblocked 5′ phosphorylated termini and the blocked, methylated, “capped” termini, known to be present in the messenger RNA of most eukaryotes.Approximately 80% of the 5′-terminal structures recovered from digests of poly(A)-containing Drosophila mRNA are cap structures of the general form m⁷G^5′ppp^5′X(m)pY(m)pZp. With respect to the extent of ribose methylation and the base distribution, the 5′-terminal sequences of Drosophila capped mRNA appear to be intermediate between those of unicellular eukaryotes and those of mammals. Drosophila is the first organism known in which type 0 (no ribose methylations), type 1 (one ribose methylation), and type 2 (two ribose methylations) caps are all present. In contrast to mammalian cells, the caps of Drosophila never contain the doubly methylated nucleoside N⁶,2′-O-dimethyladenosine. Both purines and pyrimidines can be found as the penultimate nucleoside of Drosophila caps and there is a wide variety of X-Y base combinations. The relative frequencies of these different base combinations, and the extent of ribose methylation, vary with the duration of labeling. The large majority of poly(A)-containing cytoplasmic RNA molecules from heat-shocked Drosophila cells are also capped, but these caps are unusual in having almost exclusively purines as the penultimate X base.Greater than 75% of the 5′ termini of heterogeneous nuclear RNA (hnRNA) containing poly(A) and greater than 50% of the termini of hnRNA lacking poly (A) are also capped. Triphosphorylated nucleotides, common as the 5′ nucleotides of mammalian hnRNA, are rare in the poly(A)-containing hnRNA of Drosophila. The frequency of the various type 0 and type 1 cap sequences of cytoplasmic and nuclear poly (A)-containing RNA are almost identical. The caps of hnRNA lacking poly(A) are also quite similar to those of poly-adenylated hnRNA, but are somewhat lower in their content of penultimate pyrimidine nucleosides, suggesting that these two populations of molecules are not identical.     

Polyadenylate-deficient analogues of poly(A)-containing mRNA sequences in cultured AKR mouse embryo cells

Five to six percent (by mass) of AKR-2B mouse embryo cell polysomal RNA consists of messenger RNA sequences which may exist in polyadenylated form. In the steady state, however, only 30–40% of these molecules are retained by extensive passage over oligo(dT)-cellulose, the remainder being present in the form of poly(A)-deficient analogues. Within experimental limits, these poly(A)-deficient analogues contain representatives of all poly(A)-containing mRNA sequences in these cells. An analysis of the kinetics of hybridization of cDNA probes enriched for either abundant or rare poly(A)-containing mRNA sequences suggests that the frequency distributions of poly(A)-containing and poly(A)-deficient analogues are dissimilar, and that a relationship exists between the intracellular frequency of a given mRNA sequence and the number of poly(A)-deficient analogues of that sequence. High frequency sequences appear to be enriched in the poly(A)-containing fraction, while low frequency sequences are predominately associated with the poly(A)-deficient fraction, thus, poly(A) may play a role in the regulation of mRNA frequency in the cytoplasm.     

Comparison of proteins bound to heterogeneous nuclear RNA and messenger RNA in HeLa cells.

Ribonucleoprotein particles containing either heterogeneous nuclear RNA or polyribosomal messenger RNA were isolated from growing HeLa cells in order to compare their respective protein components. The major obstacle to analysing the proteins bound to HeLa cell mRNA proved to be the cosedimentation of a large fraction of the mRNP² particles with ribosomal subunits following puromycin or EDTA disassembly of polyribosomes. This was circumvented by oligo(dT)-cellulose chromatography, in which essentially all of the ribosomal subunits passed through the column without retention, while approximately 80% of the pulse-labeled, poly(A)-containing mRNP became bound and could be eluted with formamide. Polyacrylamide gel electrophoresis of the non-bound fraction (ribosomal subunits) revealed polypeptides between 15,000 and 55,000 molecular weight, with no detectable components greater than 55,000. The oligo-(dT)-bound mRNP contained a much simpler protein complement, consisting of three major components having molecular weights of 120,000, 76,000 and 52,000.In the case of the nuclear ribonucleoprotein particles that contain heterogeneous nuclear RNA, oligo(dT)-cellulose chromatography revealed two classes of particles. The first contained 10 to 20% of the hnRNA, did not bind to oligo(dT)-cellulose in 0.25 m-NaCl, 10 mm-sodium phosphate buffer, pH 7.0 (4 °C), and contained primarily a single polypeptide component having an estimated molecular weight of 40,000 (“informofers”). A second population of hnRNP particles comprised approximately 80% of the hnRNA, displayed strong binding to oligo(dT)-cellulose at 0.25 m-NaCl, and contained a very complex population of proteins, having molecular weights between 40,000 and 180,000, the same as unfractionated hnRNP. The results indicate that, at the resolution of gel electrophoresis and at the sensitivity of Coomassie blue dye, the proteins bound to HeLa cell hnRNA are qualitatively distinct from those bound to polyribosomal mRNA and, in addition, that the hnRNP proteins are the more complex of the two. These results are discussed in relation to the possible nucleotide sequence elements in hnRNA and mRNA to which these specific proteins are bound.     

Location of oligo(uridylic acid) sequences within messenger ribonucleic acid molecules of HeLa cells

A significant fraction of the polyadenylated mRNAs of HeLa cells contain an oligo(uridylic acid) [oligo(U)] sequence of 15-30 nucleotides. Several different experimental approaches were used to determine if these oligo(U)'s occupied similar sites within all mRNAs. In one approach, poly(adenylic acid)-containing mRNAs [poly(A+) mRNAs] averaging 2800 nucleotides in length were reduced to an average size of 500 nucleotides by controlled alkaline hydrolysis. Over 20% of the oligo(U)-containing fragments isolated from the hydrolysate retained a poly(A) sequence, showing that oligo(U)'s were not exclusively located near 5' ends of mRNA although 20% were apparently close to 3' ends. To confirm these observations, oligo(U)-containing mRNA [oligo(U+) mRNA] was exposed to the 3'-exonucleolytic activity of polynucleotide phosphorylase to produce fragments containing the 5' regions of mRNA. Each of a set of fragments of decreasing length generated by increased times of exposure of the mRNAs to the enzyme was found to have about the same oligo(U) content, including the shortest that averaged 550 nucleotides. These data not only eliminated an exclusive location for oligo(U) in either 3' or 5' ends of mRNA but also suggested that oligo(U)'s might be close to the 5' ends of some mRNAs. To verify this last observation, periodate-oxidized poly(A+) mRNA was labeled at the 5' caps and at 3'-adenosine residues by sodium [3H]borohydride reduction before it was nicked 3-5 times with alkali to produce 5' and 3' end-labeled pieces that could be separated with oligo(thymidylic acid)-cellulose.(ABSTRACT TRUNCATED AT 250 WORDS)     

Composition and in vitro cytotoxicity of cellular infiltrates in rejecting human kidney allografts.

Xenogeneic immune RNA (I-RNA) extracted from the spleens and lymph nodes of guinea pigs previously immunized with a murine fibrosarcoma was able to convert normal mouse lymphocytes to effector cells specifically cytolytic to the same murine tumor in vitro. This effect of I-RNA was dose-dependent, and destroyed by treatment with RNase, but not with DNase or pronase. I-RNA was fractionated by ultracentrifugation on a 5–20% sucrose density gradient and the fraction capable of transferring cell-mediated cytotoxicity (CMC) was shown to have a sedimentation coefficient of 8–16 S. I-RNA was also fractionated by oligo(dT)-cellulose affinity chromatography and the active fraction was found to possess polyadenylic acid (poly(A)) sequences thus resembling messenger RNA. The immunological activity of the poly (A)-containing RNA fraction was tumor-specific and RNase-sensitive. In further experiments, I-RNA fractionated by sucrose density gradient ultracentrifugation was subsequently chromatographed. on an oligo(dT)-cellulose column. CMC was transferred only by the fraction which sedimented at 8–16 S and also contained poly (A).     

Analysis of the message-sequence content of the pulse-labeled poly(A)+ heterogeneous nuclear RNA from HeLa cells by cDNA-excess hybridizations.

The message-sequence content of pulse-labeled poly(A)+ HeLa heterogenous nuclear RNA (hnRNA) has been examined by hybridizations to an excess of message cDNA. Control experiments show that the message cDNA accurately reflects the sequence distribution of the complex mixture of poly(A)+ messages present in the HeLa cytoplasm. Pulse-labeled poly(A)+ molecules in both the lamina-associated and shnRNA fractions contain message sequences, and approximately 65% of the poly(A)-adjacent hnRNA sequences are homologous to the 3' ends of mRNA. The majority of the pulse-labeled hnRNA molecules contain abundant message sequences. By use of these techniques it is also shown that some pulse-labeled polyadenylated message sequences are still synthesized in the presence of the adenosine analogue 5,6-dichloro-beta-D-ribofuranosylbenzimidazole under conditions where little or no new cytoplasmic mRNA is produced.     

Ribonucleoprotein organization of polyadenylate sequences in HeLa cell heterogeneous nuclear RNA.

Ribonucleoprotein particles containing heterogeneous nuclear RNA (Pederson, 1974) were isolated from HeLa cells and digested with ribonucleases A and T₁ at high ionic strength. The nuclease-resistant material, comprising 9.4% of the initial acid-insoluble [³H]adenosine radioactivity, was further fractionated by poly(U)-Sepharose chromatography. The bound fraction eluted from the column with 50% formamide and banded in cesium sulfate gradients (without aldehyde fixation) at a buoyant density characteristic of ribonucleoprotein (1.45 g/cm³). Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of this material revealed two Coomassie blue-stained bands. The major polypeptide had a molecular weight of 74,000 a less prominent band had a molecular weight of 86,000. The RNA components contained 74.4 mol % AMP and 17.7 mol % UMP. Polyacrylamide gel electrophoresis of the RNA, labeled with [³H]adenosine, demonstrated the presence of molecules 150 to 200 nucleotides in length (poly(A)), as well as molecules 20 to 30 nucleotides long (oligo(A)). Both poly(A) and oligo(A) sequences have previously been identified in HeLa heterogeneous nuclear RNA. These data demonstrate that both the poly (A) and oligo(A) sequences in HeLa heterogeneous nuclear RNA exist in vivo tightly complexed with specific proteins.     

A method for isolation of oligo(uridylic acid)-containing messenger ribonucleic acid from HeLa cells

When cytoplasmic polyadenylated ribonucleic acid [poly(A+)RNA] from HeLa cells was treated with ribonuclease H (RNase H) and oligodeoxythymidylate [oligo(dT)] to remove its 3'-poly(A) tail, an increased binding to poly(A)-agarose was observed. The bound material, which comprised 4-6% of the initial RNA, contained 65-80% of the oligo(uridylic acid) [oligo(U)] sequences generated by RNase T1 digestion. Oligo(U) isolated from the bound fraction was shown to be 83% U and to have a U/G ratio of 33. In contrast, oligo(U) from the unbound material was 77% U and had a U/G ratio of 13, suggesting that it is shorter and less U rich than the oligo(U) in the bound fraction. On sucrose gradients, oligo(U+)RNA consistently sedimented with a larger s value than oligo(U-) RNA. The oligo(U) content of oligo(U+) RNA suggests one oligo(U) tract of 33 nucleotides per RNA molecule of 2000-3000 residues.     

The stability, polyadenylic acid content and ribonucleoprotein form of nulcear ribonucleic acid in artichoke.

A nuclear preparation, containing 60-80% of the total tissue DNA and less than 0.5% of the total rRNA, was used to characterize the nuclear RNA species synthesized in cultured artichoke explants. The half-lives of the nuclear RNA species were estimated from first-order-decay analyses to be: hnRNA (heterogeneous nuclear RNA) containing poly(A), 38 min; hnRNA lacking poly(A), 37 min; 2.5 X 10(6)-mol. wt. precursor rRNA, 24 min; 1.4 X 10(6)-mol.wt. precursor rRNA, 58 min; 1.0 X 10(6)-mol.wt. precursor rRNA, 52 min. The shorter half-lives are probably overestimates, owing to the time required for equilibration of the nucleotide-precursor pools. The pathway of rRNA synthesis is considered in terms of these kinetic measurements. The rate of accumulation of cytoplasmic polydisperse RNA suggested that as much as 40% of the hnRNA may be transported to the cytoplasm. The 14-25% of the hnRNA that contained a poly(A) tract had an average molecular size of 0.7 X 10(6) daltons. The poly(A) segment was 40-200 nucleotides long, consisted of at least 95% AMP and accounted for 8-10% of the [32P]orthophosphate incorporated into the poly(A)-containing hnRNA. Ribonucleoprotein particles released from nuclei by sonication, lysis in EDTA or incubation in buffer were analysed by sedimentation through sucrose gradients and by isopycnic centrifugation in gradients of metrizamide and CsCl. More than 50% of the hnRNA remained bound to the chromatin after each treatment. The hnRNA was always associated with protein but the densities of isolated particles suggested that the ratio of protein to RNA was lower than that reported for mammalian cells, The particles separated from chromatin were not enriched for poly(A)-containing hnRNA.