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.     

Sequences coding for proteins expressed in liver and for globin in poly(A)+ and poly(A)− RNA fractions from nuclei and cytoplasm of chicken immature red blood cells

By hybridization with [³H]labeled globin cDNA the contents of globin coding sequences in total nuclear RNA, poly(A)⁺nuclear RNA, poly(A)^--nuclear RNA and polysomal RNA of chicken immature red blood cells was determined to be 0.86%, 20%, 0.42% and 1% respectively. As the poly(A)⁺-fraction comprises only about 2% of total nuclear RNA, globin coding sequences are distributed with 49% in the poly(A)⁺-fraction and with 51% in the poly(A)^--fraction.Part of the mRNA sequences which are found in liver are also transcribed in immature red blood cells. These sequences are enriched in poly(A)⁺-nuclear RNA as the globin coding sequences but their total amount in the poly(A)⁺-fraction is much smaller than in the poly(A)^--fraction.When nuclear RNA from immature red blood cells was translated in an ascites tumor cell-free system, 20% of the newly synthesized proteins were globin chains. The percentage of globin chains in the newly synthesized proteins increased to over 70% when poly(A)⁺-nuclear RNA was translated. Only about 7.5% of globin chains were found in proteins coded by poly(A)^--nuclear RNA.     

Comparison of polysomal polyadenylated RNA from embryonal carcinoma and committed myogenic and erythropoietic cell lines

Using the technique of mRNA-cDNA hybridization, we have examined the polysomal poly(A)⁺ mRNA base-sequence complexity in three different mouse cell lines: mouse embryonal carcinoma cells, myoblast cells and Friend erythroleukemic cells. These cells express 7700, 13,200 and 6200 mRNA sequences, respectively, distributed in three frequency classes. Reciprocal heterologous hybridization experiments revealed that there is a large degree of homology, a subset of 6000 common sequences being present on the polysomes of all three cell types. Myoblast mRNA is capable of hybridizing all reactive embryonal carcinoma cell cDNA, with kinetics close to the homologous embryonal carcinoma cell curve, thus indicating that all embryonal carcinoma cell sequences are present on myoblast polysomes, the majority at similar abundance. Conversely, embryonal carcinoma cell mRNA fails to hybridize 12% of myoblast cDNA, apparently arising primarily from the complex frequency class. This was confirmed by using myoblast fractions partially enriched in abundant and rare sequences. As a proportion of the rare class, this 12% fraction represents about 4500 sequences close to the difference in base-sequence complexity between myoblast and embryonal carcinoma cells.Homologous and heterologous hybridization with total and fractionated Friend cell cDNA probes revealed that all Friend cell polysomal poly(A)⁺ RNA sequences are common to embryonal carcinoma cell polysomes—apart from a small group of sequences drawn from the abundant class, corresponding to about 10% of Friend cell cDNA. This represents about 12 sequences from the abundant class. In addition, certain common sequences in the abundant Friend cell frequency class are present at lower frequency in embryonal carcinoma cell polysomes. Friend cell polysomal poly(A)⁺ RNA fails to hybridize 7–10% embryonal carcinoma cell cDNA apparently derived from the rare frequency class. As a fraction of the rare class, this corresponds approximately to the difference (about 1500 sequences) in complexity between the Friend and embryonal carcinoma cell lines.     

Induction by ouabain of hemoglobin synthesis in cultured friend erythroleukemic cells

Induction of erythroid differentiation in ouabain-resistant murine erythroleukemia cells by ouabain is reported. Ouabain induction results in the appearance of hemoglobin-containing cells 12–24 hr earlier than induction of the same clone by dimethyl sulfoxide. The levels of globin mRNA after ouabain induction are similar in amount to the globin mRNA levels observed after induction by dimethyl sulfoxide. The concentration of ouabain required to induce hemoglobin synthesis depends upon the K⁺ ion levels in the culture medium. Lowering the extracellular K⁺ ion concentration 2–4 fold reduced by 10–40 fold the ouabain concentration necessary for the induction of hemoglobin synthesis. In low K⁺ medium (1.8 mM), ouabain is an effective inducer of hemoglobin synthesis at a concentration of 0.02 mM. This K⁺ effect is specific for ouabain induction, since induction by other inducers, such as dimethyl sulfoxide and dimethyl acetamide, does not exhibit this marked sensitivity to the levels of K⁺ ions in the culture medium. These results suggest that the binding of ouabain to the plasma membrane enzyme, $\text{Na}\text{K}$ ATPase, is required for the induction of erythroid differentiation by ouabain. A small but significant proportion of wild-type, ouabain-sensitive cells also can be induced by ouabain, below ouabain concentrations that are toxic to these cells. The observation that the binding of ouabain to the $\text{Na}\text{K}$ ATPase induces hemoglobin synthesis suggests that changes in the intracellular concentration of K⁺ ions may be involved in the control of erythroid differentiation in Friend erythroleukemic cells.     

The expression of a plant genome in hnRNA and mRNA.

Representation of genomic kinetic sequence classes and sequence complexities were investigated in nuclear and polysomal RNA of the higher plant Petroselinum sativum (parsley). Two different methods indicated that most if not all polysomal poly(A) -RNA is transcribed from unique sequences. As measured by saturation hybridization in root callus and young leaves 8.7% and 6.2%, respectively, of unique DNA were transcribed in mRNA corresponding to 13.700 and 10.000 average sized genes. Unique nuclear DNA hybridized with an excess of polysomal poly(A)mRNA to the same extent as with total polysomal RNA. 3H-cDNA - poly(A)mRNA hybridization kinetics revealed the presence of two abundance classes with 9.200 and about 30 different mRNAs in leaves and two abundance classes with 10.500 and 960 different mRNAs in callus cells. The existence of plant poly(A)hnRNA was proven both by its fast kinetics of appearance, its length distribution larger than mRNA, and its sequence complexity a few times that of polysomal RNA.     

alpha-Fetoprotein biosynthesis and hepatocellular differentiation

In anemia of the Belgrade rat ($\text{b}\text{b}$) reticulocytes contain less than half of the normal amount of mRNA for seven adult rat globin chains. cDNA hybridization measurements of the relative sizes of polysomal and nonpolysomal pools of globin mRNAs in these cells show that 45% of all globin mRNA molecules are not used at any given time in protein synthesis. This implies a translational control which ensures a production of globin chains in a correct ratio despite a severe mRNA unbalance.     

IN SITU LOCALIZATION OF GLOBIN MESSENGER RNA FORMATION : I. During Mouse Fetal Liver Development

Globin mRNA levels in 11–15-day mouse fetal liver cells have been estimated by in situ hybridization of a highly labeled DNA copy (cDNA) of adult globin messenger RNAs (mRNAs) (globin cDNA) to fixed preparations of cells. Under the conditions employed, no significant in situ hybridization occurred to lymphoma cells (L 51787), mouse L cells, or hepatocytes; whereas reticulocytes from phenyl hydrazine-treated mice showed extensive in situ hybridization. The proportion of fetal liver cells showing predominantly cytoplasmic in situ hybridization increased from about 30% at the 11th day of development to 80–85% by days 13–15. Unlike more mature cells, proerythroblasts did not show in situ hybridization, except to a slight extent at later stages of development. These studies therefore indicate that globin mRNAs begin to accumulate during or shortly after the proerythroblastbasophilic erythroblast transition. The fact that certain immature erythroid cells from 14-day fetal liver contain substantial amounts of globin mRNAs has been confirmed by comparing the hybridization in solution of globin cDNA to cytoplasmic RNA extracted from total fetal liver cells or from immature erythroid cells obtained by treatment of fetal liver cells with an antiserum raised against erythrocytes.     

Measurement of the complexity and diversity of poly(adenylic acid) containing messenger RNA from rat liver.

The complexity of rat liver poly (A)+ messenger RNA (mRNA) has been measured by analysis of the kinetics of hydridization with both complementary DNA (cDNA) and single copy DNA. The complementary DNA-poly(A)+ mRNA hybridization reaction demonstrates the existence of three abundance classes representing 18, 37, and 45% of the cDNA and 4, 290, and 24 000 different 1800-nucleotide sequences respectively. The poly(A)+ mRNA driven single copy DNA hybridization reaction reveals a single major transition accounting for 1.9% of the haploid rat genome. The kinetics of the poly(A)+ mRNA driven single copy DNA reaction suggest that approximately 45% of the mass of the mRNA population contains over 95% of the complexity. Although higher than previous estimates, the base sequence complexities of rat liver poly(A)+ mRNA measured in these two ways are in good agreement, suggesting that the technique of poly(A)+ mRNA-cDNA hybridization may be used in approximating the complexity as well as abundance of a messenger RNA population. DNA-driven cDNA reactions reveal that about 10% of rat liver poly(A)+ mRNA is transcribed from repetitive sequences in the rat genome.     

Characterization and Complexity of Wheat Developing Endosperm mRNAs

Free and membrane-bound (MB) polysomes and the corresponding polyadenylated RNAs (polyA⁺ RNAs) have been isolated from developing wheat endosperm (Triticum aestivum L.) Free and MB poly(A)⁺ RNAs, analyzed on isokinetic sucrose gradient with [³H]polyuridylic acid [poly(U)] hybridization detection, appear to be 11S to 12S in size with a 7% poly(A) tail for MB RNAs. cDNAs synthesized using both of these mRNA populations in presence of a potent RNase inhibitor (RNasin), have been used for hybridization kinetics experiments. The mean square fitting analysis of the hybridization kinetics between MB cDNA and its template reveals the presence of two abundance classes representing roughly ⅔ and ⅓ of the MB poly(A)⁺ RNAs and containing the information for approximately 75 superabundant species (21,000 copies per cell) and 750 intermediate species (530 copies per cell), respectively. The mRNA population extracted from free polysomes is divided into three abundance classes. The first one is composed of superabundant sequences which would correspond to the MB superabundant mRNAs. The free mRNAs consist of about 11,000 diverse sequences, most of them being rare sequences. Heterologous hybridizations of MB cDNAs to free mRNAs have shown that some mRNAs are common to both populations. This could be explained either by a partial contamination or by free polysomes en route to their membrane destination. Contrary to the low number of diverse mRNAs corresponding to the legume seed storage proteins, the wheat endosperm superabundant mRNAs consist of about 75 different sequences which would encode most of the seed storage proteins, especially gliadins.     

Concentrations of individual RNA sequences in polyadenylated nuclear and cytoplasmic RNA populations of Drosophila cells.

Steady state concentrations of individual RNA sequences in poly(A) nuclear and cytoplasmic RNA populations of Drosophila Kc cells were determined using cloned cDNA fragments. These cDNAs represent poly(A) RNA sequences of different abundance in the cytoplasm of Kc cells, but their steady state concentrations in poly(A) hnRNA was always lower. Of ten different sequences analysed, eight showed some four-fold lower concentration in hnRNA mRNA, two were underrepresented in hnRNA relative to the others. The obvious clustering of mRNA/hnRNA ratios is discussed in relation to sequence complexity and turnover rates of these RNA populations.