Fractionation and characterization of rat liver poly(A)-containing RNA.

Three fractions of poly(A)-containing RNA were separated from total rat liver RNA using poly(U)-Sepharose 4B affinity chromatography. The poly(A)-containing RNA fractions were released by thermal elution. Fraction 1, eluted under the mildest conditions, and had poly(A) tracts of approx. 200 AMP units in length which appeared to be associated with poly(U) sequences of 20-50 UMP in length. Fraction 1 appeared to be present mainly in the nucleus and, its size distribution was similar to that of fractions 2 and 3. Fractions 2 and 3 eluted at higher temperatures and were associated mainly with polysomal and microsomal fractions. Poly(U) sequences were absent in fractions 2 and 3 while their poly(A) sequences had a size distribution characteristic of those reported in the mRNA of other organisms.     

Contribution of polyadenylate sequences to the translational efficiency of globin messenger RNAs.

mRNAs from reticulocyte polysomes were fractionated by chromatography on poly(U)-Sepharose and thermal elution. The molar ratio of alpha- to beta-globin mRNA was found to be 2:1 and 1:1 respectively in short- and long-poly(A) size classes. Translational analyses indicated that the globin mRNAs containing long poly(A) tracts (with a mean length of about 70 nucleotides) directed protein synthesis with higher rates than did mRNA containing short poly(A) tracts (15-35 nucleotides). Experiments performed with sub-saturating mRNA concentrations showed that the digestion with RNAase H induced a decrease in the translational capacity of both globin mRNAs and an increase in the alpha- to beta-globin synthesis ratio. No correlation was observed between the size of the poly(A) tail in mRNA and the optimal K+ requirement for translation.     

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.     

Occurrence of mRNA for storage protein in dry soybean seeds

Poly(A)-containing RNA has been isolated from the cotyledons of soybean seeds by adsorption on a poly(U)-Sepharose column. Approximately 0.15% of the total soybean RNA applied bound to the column. The bound RNA (poly(A)-containing RNA) was shown to be mRNA by its ability to serve as template in a cell-free system derived from wheat germ. Poly(A)-containing RNA was polydisperse, migrating from approximately 50,000 to 700,000 daltons with a mean of 150,000 daltons in polyacrylamide gel electrophoresis. The size of the poly(A) portion of this RNA was in the range of 55 to 290 nucleotides. The adenylic acid content of the presumed poly(A) fragment was about 95%. The radioactive products of translation directed by the poly(A)-containing RNA in the wheat germ cell-free system were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and by immunoprecipitation using antisera against beta-conglycinin and glycinin. The results of this investigation show that mRNAs for the subunit proteins of the major components of a soybean storage protein exist in the poly(A)-containing RNA preparation obtained from the cotyledons of dry soybean seeds.     

Poly(adenylic acid)-containing and -deficient messenger RNA of mouse liver

RNA was isolated and fractionated into poly(A)-containing and -deficient classes by oligo(dT) chromatography. Approximately 99% of the poly(A) material bound to the oligo(dT); that which did not bind contained substantially shorter poly(A) chains. All RNA fractions retained an ability to initiate cell-free translation, with the poly(A)-deficient fraction containing half the total translational activity, i.e., mRNA. Two-dimensional polyacrylamide gel analysis of the cell-free translation products revealed three classes of mRNA: 1, mRNA preferentially containing poly(A), including the abundant liver mRNA species; 2, poly(A)-deficient mRNA, including many mid- and low-abundant mRNAs exhibiting less than 10% contamination in the poly(A)-containing fraction fraction; and 3, bimorphic species of mRNA proportioned between both the poly(A)-containing and -deficient fractions. Poly(A)-containing and bimorphic mRNA classes were further characterized by cDNA hybridizations. The capacity of various RNA fractions to prime cDNA synthesis was determined. Compared to total RNA, the poly(A)-containing RNA retained 70% of the priming capacity, while 20% was found in the poly(A)-deficient fraction. Poly(A)-containing, poly(A)-deficient, and total RNA fractions were hybridized to cDNAs synthesized from (+)poly(A)RNA. Poly(A)-containing RNA hybridized with an average R0t 1/2 approximately 20 times faster than total RNA. Poly(A)-deficient RNA hybridized with an average R0t 1/2 approximately 3-4 times slower than total RNA. These R0t 1/2 shifts indicated that in excess of three-quarters of the total hybridizable RNA was recovered in the poly(A)-containing fraction and that less than one-quarter was recovered in the poly(A)-deficient RNA fraction. Abundancy classes were less distinct in heterologous hybridizations. In all cases the extent of hybridization was similar, indicating that while the amount of various mRNA species varied among the RNA fractions, most hybridizing species of RNA were present in each RNA fraction. cDNA to the abundant class of mRNAs was purified and hybridized to both (+)- and (-)poly(A)RNA. Messenger RNA corresponding to the more abundant species was enriched in the poly(A)-containing fraction at least 2-fold over the less abundant species of mRNA, with less than 10% of the abundant mRNAs appearing inthe poly(A)-deficient fraction.     

Isolation and partial characterization of poly (A)-containing 7.5S messenger RNA from rat liver mitochondria.

Poly(A)-containing low molecular weight (7.5S) messenger RNA was isolated in a highly purified form from both polyribosomes and post-polysomal supernatant of rat liver mitochondria. Both mRNA's contain rather short poly(A) tracts (40-70 mononucleotides) according to a profile of their elution from poly(U)-Sepharose column with a gradient of formamide concentration. Both mRNA's when added to a preincubated mitochondrial lysate programmed the synthesis of a hydrophobic polypeptide of a molecular weight about 9000 daltons which was soluble in the neutral chloroform-methanol mixture.     

Transport of different RNA species from the nucleus to the cytoplasm in Xenopus laevis neurula cells

Isolated cells from Xenopus laevis neurulae were labeled, and the RNAs extracted from their nuclear and soluble cytoplasmic fractions were analyzed on polyacrylamide gels. In the soluble cytoplasm, 4S RNA emerged very rapidly, and this was immediately followed by the emergence of poly(A)-containing RNA and 18S ribosomal RNA. In contrast, the emergence of 28S ribosomal RNA was delayed by about 2 hr. The size distribution of cytoplasmic poly(A)-containing RNA was much smaller as compared to that of nuclear poly(A)-containing RNA. These results indicate that the newly synthesized RNAs in Xenopus neurula cells are transported from the nucleus to the cytoplasm in a characteristic sequence.     

Messenger RNA stability in Saccharomyces cerevisiae: the influence of translation and poly(A) tail length.

A comparison between the half-lives of 10 specific yeast mRNAs and their distribution within polysomes (fractionated on sucrose density gradients) was used to test the relationship between mRNA translation and degradation in the eukaryote Saccharomyces cerevisiae. Although the mRNAs vary in their distribution across the same polysome gradients, there is no obvious correlation between the stability of an mRNA and the number of ribosomes it carries in vivo. This suggests that ribosomal protection against nucleolytic attack is not a major factor in determining the stability of an mRNA in yeast. The relative lengths of the poly(A) tails of 9 yeast mRNAs were analysed using thermal elution from poly(U)-Sepharose. No dramatic differences in poly(A) tail length were observed amongst the mRNAs which could account for their wide ranging half-lives. Minor differences were consistent with shortening of the poly(A) tail as an mRNA ages.     

Regulation of messenger RNA stability in mouse erythroleukemia cells

The decay rates of several messenger RNA species were determined in mouse erythroleukemia cells. The t1/2 values for the actin and tubulin mRNAs were 16 to 26 hours and about seven hours, respectively. The globin mRNA, and two mRNA species subject to translation repression, the P40 and P21 mRNAs, were about as stable as the ribosomal RNA. A stable tubulin mRNA component also appeared to be present in the cells. Exposure of the cells to dimethylsulfoxide for 48 hours led to considerable increases in the rates of decay of all but the globin mRNA. The induction of erythroid differentiation caused by the drug appears to lead to activation of a mRNA-degradation process that affects individual species to different degrees. The newly synthesized actin and tubulin mRNAs lost their poly(A) rather rapidly. This was accompanied by accumulation of poly(A)-deficient mRNA chains, particularly in the case of actin mRNA. The steady-state distribution of mRNA components, determined by Northern blot analysis, also showed that the actin mRNA and one tubulin mRNA species have a high proportion of poly(A)-deficient molecules. The globin, P40 and P21 mRNAs showed little tendency to lose their poly(A) sequence. The steady-state globin and P40 mRNAs also had a low proportion of chains depleted of poly(A). For all five species, the proportions of poly(A)-deficient chains in newly synthesized mRNA were about the same in uninduced and induced cells, in spite of the large decreases in mRNA stability in the induced cells. The lack of correlation between tendency to lose poly(A) and rate of mRNA decay, and the large accumulation of poly(A)-deficient molecules in the cases of the actin and tubulin mRNAs suggest that the stability of mRNA is not determined solely by the presence of poly(A) on the RNA chains. The behavior of the untranslated species in induced and uninduced cells also fails to support the notion of a relationship between translation and mRNA decay.     

Changes in polyadenylation of lactate dehydrogenase-X mRNA during spermatogenesis in mice

The expression of the mRNA for mouse testicular lactate dehydrogenase (LDH-X) was examined by RNA:cDNA hybridization in situ in the testis and by Northern analyses of meiotic and postmeiotic spermatogenic cell populations. Silver grains accumulated in cells inside the second layer from the periphery of the seminiferous tubule, confirming previous findings that LDH-X mRNA first appears in the spermatocyte and continues to accumulate until the late spermatid stage. Northern analyses showed that meiotic and postmeiotic cells contained 1.2 and 1.3 kb classes of hybridizing mRNA, respectively. RNase H digestion of oligo (dT)-hybridized RNA and poly(U)-Sepharose column chromatography with differential elution by formamide revealed that the difference in size of the two classes of mRNAs was due to the poly(A) tail length of the LDH-X mRNA. When the distribution of the LDH-X mRNA was examined across polysome gradients, both mRNAs were partially associated with polysomes. These results suggest that the changes in the polyadenylation of LDH-X mRNA were associated with the meiotic division during spermatogenesis in the mouse. They raise the possibility that the stable accumulation of the LDH-X mRNAs in the postmeiotic cells is enhanced by poly(A) tails of increased length.     

Translational properties of a non-polyadenylated oligo(U)-containing RNA fraction from wheat embryos

A non-polyadenylated oligo(U)-containing RNA (poly(A)- . oligo(U)+ RNA) fraction was isolated from wheat embryo cytoplasm and its properties were compared with those of polyadenylated RNA (poly(A)+ RNA) from the same source. Both RNA preparations were highly heterogeneous and effectively stimulated [14C]leucine incorporation in a wheat germ cell-free translation system. Electrophoretic patterns of the translation products appearing in the non-polyadenylated RNA- and polyadenylated RNA-supplemented translation assays, respectively, differed from each other. The non-polyadenylated RNA-specific translation products included, in particular, a series of high molecular weight polypeptides. It is concluded that a specific class of non-polyadenylated oligo(U)-containing mRNA species (other than histone mRNAs) occurs in the wheat embryo cells.     

HeLa cell cytoplasmic mRNA contains three classes of sequences: predominantly poly(A)-free, predominantly poly(A)-containing and bimorphic

The mRNA species which exist in the HeLa cell polyribisomes in a form devoid of A sequences longer than 8 nucleotides constitute the poly(A)-free class of mRNA. The rapidly labelled component of this mRNA class shares no measurable sequence homology with poly(A)-containing RNA. If poly(A)-free mRNA larger than 12 S labelled for 2 h in vivo is hybridized with total cellular DNA, it hybridizes primarily with single-copy DNA. When a large excess of steady poly(A)-containing RNA is added before hybridization of labelled poly(A)-free RNA, no inhibition of hybridization occurs. This indicates the existence of a class of poly(A)-free mRNA with no poly(A)-containing counterpart. Some mRNA species can exist solely as poly(A)-containing mRNAs. These mRNAs in HeLa cells are found almost exclusively in the mRNA species present only a few times per cell (scarce sequences). Some mRNA species can exist in two forms, poly(A)containing and lacking, as evidenced by the translation data in vitro of Kaufmann et al. [Proc. Natl Acad. Sci. U.S.A. 74, 4801--4805 (1977)]. In addition, if cDNA to total poly(A)-containing mRNA is fractionated into abundant and scarce classes, 47% of the scarce class cDNA can be readily hybridized with poly(A)-free mRNA. 10% of the abundant cDNA to poly(A)-containing mRNA will hybridize with poly(A)-free sequences very rapidly while the other 90% hybridize 160 times more slowly, indicating two very different frequency distributions. The cytoplasmic metabolism of these three distinct mRNA classes is discussed.     

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.     

Direct demonstration of a complementarity between mRNA and double-stranded sequences of pre-mRNA

The total poly(A)-containing mRNA from mouse liver or Ehrlich ascites carcinoma cells was annealed with denatured ds RNA prepared from heavy nuclear ³H-labeled pre-mRNA of the same tissue. The hybrids formed were detected by binding of complexes to poly(U)-Sepharose columns through the poly(A) of mRNA. With this technique, about 30% of labeled ds RNA was bound to poly(U)-Sepharose after annealing it with an mRNA excess. The proportion of hybrid material detected by RNase treatment was two to three times lower than that obtained by poly(U)-Sepharose binding. The length of the RNase-stable acid precipitable hybrid material consisted of heterogeneous sequences of 10–100 nucleotides long when cytoplasmic, and 10–60 nucleotides long when polysomal mRNA was used in the hybridization reaction. The results obtained show that at least some of the mRNA molecules contain sequences complementary to one of the branches of the pre-mRNA hairpins. These results are compatible with the idea that the hairpin-like sequences in pre-mRNA are localized between mRNA and the non-informative part of the precursor molecule.