Characteristics of rabbit globin mRNA purification by oligo(dT) cellulose chromatography

We have purified rabbit globin mRNA using oligo(dT)-cellulose and sucrose gradient centrifugation. Both α- and β-globulin mRNA molecules behave heterogeneously with respect to their elution properties during chromatography on oligo(dT)-cellulose. Those fractions eluted at the lowest ionic strength are most active in directing cell-free globin biosynthesis. By making use of hybridization with synthetic [³H]DNA complementary to globin mRNA, we have shown that this technique can be used to quantitate the extent of mRNA purification. Thus, globin mRNA is approximately 90-fold purified from reticulocyte polysomal RNA and originally constituted slightly more than 1% of the polysomal RNA. Since more than 98% of the globin mRNA sequences are bound to oligo(dT)-cellulose, we suggest that most polysomal globin mRNAs contain a poly (A)-rich region and that this region is not of uniform length nor preponderately associated with either the α- or β-globin mRNAs. In addition, we observe that the 9S globin mRNA most resistant to dissociation from oligo (dT)-cellulose is most active in directing globin biosynthesis.     

The poly(A)(+)RNA sequence complexity is also represented in poly(A)(-)RNA in sea-urchin embryos

The extent to which the poly(A)(+)RNA sequence complexity from sea-urchin embryos is also represented in poly(A)(-)RNA was determined by cDNA cross-hybridization. Eighty percent or more of both the cytoplasmic poly(A)(+)RNA and polysomal poly(A)(+)RNA sequences appeared in a poly(A)(-) form. In both cases, the cellular concentrations of the poly(A)(-)RNA molecules that reacted with the cDNA were similar to the concentrations of the homologous poly(A)(+) sequences. Additionally, few, if any, abundant poly(A)(+)mRNA molecules were quantitatively discriminated by polyadenylation, since the abundant poly(A)(+)sequences were also abundant in poly(A)(-)RNA. Neither degradation nor inefficient binding to oligo (dT)-cellulose can account for the observed cross-reactivity. These data indicate that, in sea-urchin embryos, the poly(A) does not regulate the utilization of mRNA by demarcating an mRNA subset that is specifically and completely polyadenylated.     

The metabolism of a poly(A) minus mRNA fraction in HeLa cells

About 30% of HeLa cell mRNA lacks poly(A) when labeled in the presence of different rRNA inhibitors. Our method of RNA fractionation precludes contamination of the poly(A)^? mRNA with large amounts of poly(A)⁺ sequences. The poly(A)^? species is associated with polyribosomes, has an average sedimentation value equal to or greater than poly(A)⁺ mRNA, and behaves like the poly(A)⁺ mRNA in its sensitivity to EDTA and puromycin release from polyribosomes. There is very little, if any, hybridization at Rot values characteristic of abundant RNA sequences between the poly(A)^? RNA fractions from total cytoplasm or from polyribosomes and ³H-cDNA made to poly(A)⁺ RNA. This indicates that poly(A)^? mRNA does not arise from poly(A)⁺ mRNA by nonadenylation, deadenylation, or degradation of random abundant mRNA sequences. The rate of accumulation of poly(A)^? mRNA larger than 9S in the cytoplasm parallels the accumulation of poly(A)^? mRNA. The poly(A)^? mRNA is maintained as approximately 30% of the total labeled mRNA in a short (90 min) and in a long (20 hr) time period. These data indicate that poly(A)^? mRNA is not short-lived nuclear or cytoplasmic heterogeneous RNA contamination, and that the half-life of the poly(A)^? mRNA may parallel that of the poly(A)⁺ mRNA. Cordycepin appears to almost completely (95%) inhibit poly(A)⁺ mRNA while only partially (60%) inhibiting the poly(A)^? mRNA. The origin of the cordycepin-insensitive mRNA has not been ascertained.     

Isolation and cell-free translation of chick lens crystallin mRNA during normal development and transdifferentiation of neural retina

Messenger RNA has been isolated from day-old chick lens. Size characterization and heterologous cell-free translation demonstrate that the predominant species of mRNA present code for α-, β- and δ-crystallins. Total polysomal RNA and polysomal RNA which did not bind to oligo (dT)-cellulose translate in the cell-free system to give a crystallin profile qualitatively similar to that of poly(A)⁺ mRNA. RNA from postribosomal supernatant which binds to oligo(dT)-cellulose also translates to give crystallins, but the products are enriched for β-crystallins. Messenger RNAs isolated from 15-day embryo lens fiber and lens epithelium cells give products on translation which reflect the different protein compositions of these two cell types, as do mRNAs isolated from chick lenses at various developmental stages. Messenger RNAs were isolated from freshly excised 8-day embryo neural retina and from this tissue undergoing transdifferentiation into lens cells in cell culture. Cell-free translation demonstrates no detectable crystallin mRNAs in the freshly excised material, but by 42 days in cell culture, crystallin mRNAs are the most prominent species.     

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.     

Kinetic study of protein unfolding and refolding using urea gradient electrophoresis

When total cytoplasmic RNA from mouse Friend cells is fractionated using oligo(dT)-cellulose or poly(U)-Sepharose chromatography, approximately 20% of the messenger RNA activity (as measured in the reticulocyte lysate cell-free system) remains in the unbound fraction, even though this contains < 0.5% of the poly(A) (as measured by titration with poly(U)). This RNA, operationally defined as poly(A)^?, is found almost entirely in polysome structures in vivo. Its major translation products, as shown by one-dimensional sodium dodecyl sulphate-containing gels, are the histones and actin. Two-dimensional gels (isoelectric focusing: sodium dodecyl sulphate/gel electrophoresis) show that, with the exception of the mRNAs coding for histones, poly(A)^? mRNA encodes similar proteins to poly(A)⁺ mRNA, though in very different abundances. This is directly confirmed by the arrest of the translation of the abundant poly(A)^? mRNAs after hybridization with a complementary DNA transcribed from poly(A)⁺ RNA.RNA sequences which are rare in the poly(A)⁺ RNA are also found in poly(A)^? RNA, as shown by hybridizing a cDNA transcribed from poly(A)⁺ RNA to total and poly(A)^? polysomal RNA. That this does not simply represent a flow-through of poly(A)⁺ RNA is indicated by (i) the lack of poly(A) by hybridizing to poly(U) in this fraction, (ii) the fact that further passage through poly(U)-Sepharose does not remove the hybridizing sequences, (iii) the very different quantitative distribution of proteins encoded by poly(A)⁺ and poly(A)^? RNAs. We also think that it does not result from removal of poly(A) from polyadenylated RNAs during extraction because RNAs prepared using the minimum of manipulations give similar results. The distribution of both total mRNA and α and β globin mRNAs between poly(A)⁺ and poly(A)^? RNA does not change significantly during the dimethyl sulphoxide-induced differentiation of Friend cells.     

Half-lives and relative amounts of stored and polysomal ribosomes and poly(A)+ RNA in mouse oocytes

Growing mouse oocytes were labeled in vitro with [³H]uridine and chased for 2 or for 7 days to estimate the relative amounts of RNA appearing in different fractions and to follow their turnover. Oocytes were lysed and thoroughly dispersed in the presence of 1% DOC, and centrifuged on sucrose gradients to separate polysomes from smaller components not engaged in translation. After the short chase, one-third of the labeled ribosomes appeared in EDTA-sensitive polysomes. The proportion of ribosomes in both fractions remained stable during the long chase, demonstrating no net flow from one fraction to the other. When gradient fractions were analyzed by poly(U) Sepharose chromatography, it was found that about 20% of the labeled poly(A)+ RNA appeared in polysomes after the short chase. The half-lives of stored and translated mRNA were followed relative to stable rRNA during the long chase. Stored mRNA was completely stable, but translated mRNA turned over with a $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ of about 6 days. Other methods for separating stored from translated components were not successful, including sedimentation of putative large complexes (fibrillar lattices) containing stored components, or chromatography of lysates on oligo(dT)-cellulose. Results presented here combined with our previous results demonstrate that, during meiotic maturation, the percent of labeled stable RNA which is polyadenylated declines from 19 to 10%, suggesting deadenylation or degradation of half of the accumulated maternal mRNA.     

Poly(A) and synthesis of polyadenylated RNA in the preimplantation mouse embryo

Investigations were conducted to quantitate polyadenylic acid and estimate the synthesis of polyadenylated RNA in mouse embryos at several stages of preimplantation development. Poly(A) was assayed by molecular hybridization of total embryonic RNA with [³H]polyuridylic acid. The mean values of poly(A) in the ovulated oocytes and in the one-cell, two-cell, and blastocyst stages of the embryo were 1.9, 1.6, 0.68, and 3.8 pg, respectively. Synthesis of polyadenylated RNA was estimated by affinity chromatography of [³H]uridine-labeled embryo RNA on oligo(dT)-cellulose. The proportions of newly synthesized RNA bound by oligo(dT)-cellulose at the 2-cell, 8- to 16-cell, and blastocyst stages were 6.7, 3.5, and 3.3%, respectively. These results suggest that significant quantities of maternal mRNA are present during early development of the mouse, but that polyadenylation of RNA transcribed from the embryonic genome occurs as early as the two-cell stage.     

Isolation and characterization of poly(A)-containing polyoma "early" and "late" messenger RNAs.

During late lytic infection of mouse kidney cell cultures polyoma 16S and 19S (late 19S RNA) were isolated by oligo(dT)-cellulose chromatography. Approximately 60-80% of total cytoplasmic polyoma RNA contained tracts of poly(A) which were retained by oligo(dT)-cellulose. Early in lytic infection when viral DNA synthesis and the production of capsid protein are blocked by the addition of 5-fluorodeoxyuridine, approximately 100% of polyoma "early" 19S RNA was quantitatively retained by oligo(dT)-cellulose indicating the presence of poly(A) tracts on most 19S mRNA molecules. In addition, 2 classes polyoma RNA, synthesized after the onset of cellular RNA synthesis under conditions where DNA synthesis is inhibited with 5-fluorodeoxyuridine, were found to contain tracts of poly(A). These species sedimenting at 16S and 19S in aqueous sucrose density gradients were also quantitatively retained by oligo (dT)-cellulose.     

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.     

Effective solvent systems for separation and an improved detection method for amino acids by paper chromatoghraphy

Binding of poly(A)-containing RNP to oligo(dT)-cellulose has been investigated as a function of mono- and divalent ion concentration. 80–90% binding was obtained either in high (500 mM) or in moderate NaCl concentrations in the presence of 5 mM MgCl₂. At 40 mM NaCl and 5 mM MgCl₂ poly(A)⁺-RNP exhibit approximately t he same stability as poly(A)⁺-RNA in binding to oligo(dT)-cellulose with a melting temperature of 41 and 45°C, respectively, indicating that the protein moeity has no effect on the ribonucleoprotein binding in these conditions. Differences were observed int he elution of poly(A)⁺-RNA and poly(A)⁺-RNP from oligo(dT)-cellulose in buffer without salts. Poly(A)⁺-RNA was completely removed at 4°C whereas the melting temperature of poly(A)⁺-RNP was only decreased to 34°C. The isolation of poly(A)⁺-RNP by thermal elution from oligo(dT)-cellulose is described.     

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.     

Differential accumulation of two size classes of poly(A) associated with messenger RNA during oogenesis in Xenopus laevis

The RNA of full-grown oocytes of Xenopus laevis contains two distinct size classes of poly(A), designated poly(A)_S and poly(A)_L, which contain 15–30 (mean = 20) and 40–80 (mean = 61) A residues, respectively. Both poly(A)_L and poly(A)_S are associated with RNA which is heterogeneous in size. The two classes of poly(A)⁺ RNA can be separated by affinity chromatography: Only poly(A)_L⁺ RNA binds to oligo(dT)-cellulose under appropriate conditions, but up to 50% of the poly(A)_S⁺ RNA can be isolated from the void fraction by binding to poly(U)-Sepharose. Both classes of poly(A)⁺ RNA are active as messenger RNA in an in vitro system and yield identical patterns of in vitro protein products. Previtellogenic oocytes contain almost exclusively poly(A)_L, which accumulates up to vitellogenesis but remains almost constant in amount (molecules/oocyte) during vitellogenesis and in the full-grown oocyte. Poly(A)_S accumulates (molecules/oocyte) from early vitellogenesis up to the full-grown oocyte. The total number of poly(A)⁺ RNA molecules per oocyte increases throughout oogenesis from 2 × 10¹⁰/previtellogenic oocyte [80–90% poly(A)_L] to 20 × 10¹⁰/full-grown oocyte (25–40% poly(A)_L). It is argued that poly(A)_S is protected from degradation in the oocyte, thus stabilizing the “maternal” poly(A)⁺ mRNA.     

Isolation of messenger RNA from polysomes by chromatography on oligo(dT)-cellulose.

A method for the isolation of messenger RNA (mRNA) from polysomes is described. Polysomes are dissolved in a solution containing 0.5 m NaCl and Na dodecyl sulphate and applied to an oligo(dT)-cellulose column. RNA species containing poly(A) sequences are retained by the column, whereas ribosomal proteins and other RNA species are washed off. The column is then eluted with a buffer not containing NaCl. mRNA from HeLa cells and from duck reticulocytes has been fractionated in this way. When fractionated on sucrose gradients, 10 s globin mRNA is obtained in addition to a 20 s component, which can be translated in a cell free system into duck globin. This 20 s RNA is an aggregate of mRNA, which can be disaggregated. Experiments with HeLa cells have shown that the only mRNA species which is not retained by oligo(dT)-cellulose is histone mRNA; this mRNA does not contain a poly(A) sequence.     

POLYADENYLIC ACID-CONTAINING RNA FROM RAT BRAIN

A portion of rat brain RNA contains poly(A) sequences and binds to oligo(dT)-cellulose. Young rats have a greater amount of brain RNA which contains poly(A) than do adult animals. The length of the poly(A) sequence from the brain RNA of young animals was shown to be somewhat longer than that from the RNA of adults. The RNA which bound to the oligo(dT)-cellulose was found to be large and heterogeneous, and to be almost free of ribosomal or of small mol. wt. RNAs. When the polysomal RNA which bound to the oligo(dT)-cellulose columns and that which did not were used to prime a cell-free protein synthesizing system there was a noticeable difference in their‘messenger’activity; the RNA which bound to the oligo(dT)-cellulose was much more active than the unbound material. However, in the case of the nuclear RNA there was not as great a difference between the material which was bound and that which was not bound.     

Differences in the synthesis of total and poly(A)+RNA in the Kennebec potato and its dihaploid

RNA synthesis as measured by the incorporation of tritiated uridine into trichloroacetic acid insoluble material was studied in the leaf protoplasts of cv. Kennebec and its parthenogenically derived dihaploid. Protoplasts of cv. Kennebec incorporated tritiated uridine at a greater rate and accumulated more than twice the amount of radioactive materials than did the dihaploid over a 6-h incubation period. Poly(A)⁺RNA, isolated from the total RNA of the tetraploid and of the dihaploid, by oligo(dT)-cellulose column chromatography, was present in amounts of 11.3 and 5.2 % respectively. The tetraploid synthesized 4.8 times the amount of poly(A)⁺RNA that was synthesized by the dihaploid.     

Polypeptide composition of the globin poly(A)-protein complex from rabbit reticulocytes

Polypeptides associated with the rabbit reticulocyte poly(A)-protein complex, isolated by oligo (dT)-cellulose chromatography, were analyzed by SDS-polyacrylamide gel electrophoresis. The complex derived from EDTA released total polysomal mRNP and 20S globin mRNP by RNase treatment contained four polypeptides of molecular weight 58000, 67000, 71000 and 79000. A 79000 molecular weight polypeptide, which was also a major component of the reticulocyte low molecular weight cytoplasmic fraction, was shown to form tenacious associations with poly(A) in vitro.     

Poly(A)+ RNA metabolism during oogenesis in Xenopus laevis.

In this study, we have measured the synthesis and turnover of oligo(dT)cellulose-bound RNA [poly(A)⁺ RNA] in Xenopus laevis oocytes at the maximal lampbrush chromosome stage (stage 3) and at the completion of oocyte growth (stage 6). Oocytes at both stages are shown to be active in the synthesis of poly(A)⁺ RNA. In stage 6 oocytes, the mean rate of synthesis of stable poly(A)⁺ RNA is 15% the instantaneous rate of synthesis, while the mean half-life of the unstable component is 1.6 hr. In contrast, the instantaneous rate of synthesis in stage 3 oocytes is about one-third that seen in stage 6, and most of it is devoted to the production of unstable species with an average half-life of 5 hr. Studies on the nuclear versus the cytoplasmic distribution of the newly synthesized poly(A)⁺ RNA demonstrated that by the end of a 12-hr labeling period for stage 3 oocytes and a 24-hr labeling period for stage 6 oocytes, approximately half of the material was cytoplasmic. This cytoplasmic material had the same electrophoretic mobility as bulk poly(A)⁺ RNA. Similarly, as with bulk poly(A)⁺ RNA, little, if any, of the newly synthesized material was found to be polysomal. Also, poly(A) labeling studies indicated that the newly synthesized poly(A)⁺ RNA was associated with the synthesis of poly(A) of the same length as that appearing on bulk poly(A)⁺ RNA. Studies on the content of bulk oligo(dT)cellulose-bound RNA indicated that about 86 ng is present in both stage 3 and stage 6 oocytes. The continual synthesis of poly(A)⁺ RNA throughout oogenesis in the absence of its accumulation led to the conclusion that it must be turning over. These data are discussed in relation to the hypothesis that bulk levels of poly(A)⁺ RNA are maintained by continually changing rates of synthesis and degradation.     

Translation and characterization of poly(A)-lacking RNA from lupin root nodules

Total polysomal RNA from yellow lupin root nodules was fractionated by double oligo(dT)-cellulose chromatography. Poly(A)-containing and poly(A)-lacking RNA fractions showed considerable messenger activity in wheat germ and rabbit reticulocyte cell-free systems. The sizing of poly(A)-lacking RNA on sucrose-density gradient gives rise to separation of 14S mRNA from 22-24S mRNA species. A single polypeptide with molecular weight of 22,000 was coded for by 14S mRNA, while two polypeptides with an apparent mol. wt. of 90,000 and 87,000 were the main products of 22-24S mRNA fraction. High concentrations of unfractionated poly(A)-lacking RNA as well as the addition of poly(A) led to preferential synthesis of the 22,000 product. Preliminary results suggest the presence of m7GpppX cap structure at 5' terminus of the separated 14S and 22-24S mRNA species. This comes from the competition experiments with m7GMP and m7GTP as well as from the fact that the poly(A)-lacking RNA preparation was susceptible to methylation by methyl-transferase from vaccinia virus (methylated is the 2'-O-nucleotide adjacent to 7-methylguanosine). Digestion by T1 RNAase of methylated poly(A)-lacking RNA produced two short 5'-terminal oligonucleotides 10 and 17 nucleotides in length.     

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.