Changes in the frequency and diversity of messenger RNA populations in the course of myogenic differentiation.

Complementary DNAs (cDNAs) were synthesized from polyadenylated RNAs of myoblasts and myotubes and used to analyze changes in the sequence complexity and frequency distribution of messenger RNAs during myogenesis in vitro. cDNA . polyadenylated-RNA hybridization kinetics show the presence of messenger RNA sequences specific for myotubes in fully differentiated muscle cultures. These sequences are accumulated just prior to fusion, as was shown by hybridizations of myotube cDNA and total cytoplasmic RNAs from cells at different stages of differentiation. The myotube cDNA can be enriched 10-fold in myotube-specific RNA species by a hybridization with cytoplasmic RNAs from myoblasts and subsequent removal of these hybridized sequences by hydroxyapatite.     

Relationship between single-stranded DNA isolated from cultured muscular cells during differentiation and the transcription of messenger RNA.

Single-stranded DNA (ssDNA), equivalent to about 2% of the total nuclear DNA, was isolated by an improved method of hydroxyapatite chromatography from native nuclear DNA of rat myoblast cells and myotubes of the L6 line. Small quantities of 125I-labelled ssDNA were annealed with a large excess of unlabelled DNA, cytoplasmic RNA and mRNA from myoblasts or myotubes. The results indicated that ssDNA belongs to the non-repetitious portion of the cell genome and is formed of two distinct molecular fractions. The major ssDNA fractions (75%) consist of non-self-reassociating DNA sequences and the minor fraction (25%) consists of self-reassociating DNA sequences. About 30--32% and 25--26% of ssDNA from myoblast represent DNA sequences complementary to total cytplasmic RNAs and polyadenylated RNAs respectively. Hybridizations of ssDNA with an excess of RNA from myoblasts and/or myotubes show differences in the abundance and the diversity of mRNA during mascular differentiation. These differences were confirmed by DNA-driven reactions between 125I-labelled polyadenylated RNA and ssDNA in great excess.     

Diversity of sequences in total and polyadenylated nuclear RNA from Drosophila cells.

Complementary DNA was synthesized using polyadenylated nuclear RNA of cultured Drosophila cells as template. The kinetics of hybridization of this cDNA with nuclear RNA indicated that the complexity of this RNA population is five to ten times greater than that of cytoplasmic mRNA. The same difference in the fraction of DNA represented was obtained when nuclear and cytoplasmic RNA were hybridized with labeled unique sequence DNA. The fraction of the DNA sequences represented in total number of polyadenylated nuclear RNA is much higher than that represented in cytoplasmic RNA.     

Small RNA molecules related to the Alu family of repetitive DNA sequences.

A rodent 4.5S RNA molecule with extensive homology to the Alu family of interspersed repetitive DNA sequences has been found physically associated with polyadenylated nuclear and cytoplasmic RNAs (W. Jelinek and L. Leinwand, Cell 15:205-214, 1978; S. Haynes et al., Mol. Cell. Biol. 1:573-583, 1981). In this report, we describe a 4.5S RNA molecule in rat cells whose RNase fingerprints are identical to those of the equivalent mouse molecule. We show that the rat 4.5S RNA is part of a small family of RNA molecules, all sharing sequence homology to the Alu family of DNA sequences. These RNAs are synthesized by RNA polymerase III and are developmentally regulated and short-lived in the cytoplasm. Of this family of small RNAs, only the 4.5S RNA is found associated with polyadenylated RNA.     

Frequency distribution of pre-messenger RNA sequences in polyadenylated and non-polyadenylated nuclear RNA from Friend cells.

Hybridisation of cDNA probes for abundant and rare polysomal polyadenylated RNAs with polyadenylated and non-polyadenylated nuclear RNA from Friend cells indicated that the abundant polysomal polyadenylated RNA sequences were present at a higher concentration in the nucleus than rare polysomal sequences, but at a reduced range of concentrations. The ratio of the concentrations of abundant and rare sequences was about 3 in non-polyadenylated nuclear RNA, 9 in polyadenylated nuclear RNA and 13 in polysomal polyadenylated RNA. This suggests that polyadenylation may play a role in the quantitative selection of sequences for transport to the cytoplasm. Polyadenylation cannot be the only signal for transport, since a highly complex population of nucleus-confined polyadenylated molecules exists, each of which is present on average at less than one copy per cell.     

Identification of a high molecular weight presumptive precursor to albumin mRNA in the nucleus of rat liver and hepatoma cell line H4AZC2.

Nuclear RNAs prepared from rat liver and rat hepatoma cell line H4AZC2 have been fractionated and examined for albumin mRNA sequences by annealing to specific albumin [3H]cDNA. In both instances, sucrose gradient analysis revealed nuclear RNA molecules containing albumin RNA sequences which sedimented at 26 S (26 S albumin RNA). In contrast, cytoplasmic albumin messenger RNA sediments exclusively at 17 S. 26 S albumin RNA is resistant to both heat denaturation (65 degrees C X 5 min) and denaturation in 85% formamide (v/v), and 75% of these molecules are polyadenylated. These results provide evidence for the existence of an intact, high molecular weight, polyadenylated nuclear RNA which contains albumin mRNA sequences.     

Adenovirus proteins associated with mRNA and hnRNA in infected HeLa cells.

The proteins that interact with cytoplasmic and nuclear polyadenylated RNA in adenovirus type 5 (Ad5) infection of HeLa cells were examined by UV-induced RNA-protein cross-linking in intact cells. The Ad5 100-kilodalton late nonvirion protein (100K protein) was cross-linked to both host and viral polyadenylated cytoplasmic RNA (mRNA). The cross-linking of the 100K protein to mRNA appears to correlate with productive infection, because the protein is not cross-linked to mRNA in abortive infection of wild-type Ad5 in monkey cells (CV-1) even though normal amounts of it are produced. However, when CV-1 cells are infected with Ad5 hr404, and Ad5 mutant which overcomes the host restriction to wild-type Ad5 infection in these cells, the 100K protein is cross-linked to mRNA. To identify and obtain antibodies to RNA-contacting proteins, a mouse was immunized with oligo(dT)-selected cross-linked RNA-protein complexes from Ad5-infected cells and the serum was used for immunoblotting experiments. It was found that in addition to the 100K protein, the Ad5 72K DNA-binding protein is also associated with RNA in the infected cells. The 72K DNA-binding protein is cross-linked to polyadenylated nuclear RNA sequences. These findings indicate that adenovirus proteins interact with RNAs in the infected cell and suggest possible mechanisms for the effects of the virus on mRNA metabolism.     

Stability of polyadenylated RNA in differentiating myogenic cells

Three independent methods of measurement showed that cytoplasmic polyadenylated RNA from the differentiating myogenic cell line L8 consists of two main populations with regard to stability, one with a half-life of less than 4 h and the other with a half-life of 17--54 h. Similar results were obtained in the presence and absence of actinomycin D. During the fusion of mononucleated myoblasts into multinucleated fibers, there was an increase in both the steady-state pool of the more stable polyadenylated RNA and the proportion of stable polyadenylated RNA synthesized in pulse labelling.     

Early RNA of adenovirus type 3 in permissive and abortive infections.

Early adenovirus type 3 cytoplasmic polyadenylated RNAs from HeLa and BHK-21 cells were detected and mapped on the viral genome by gel blotting and hybridization techniques. The sizes and locations of the 16 adenovirus type 3 RNAs were identical in the two cell types, although relative molarities of the various RNA species differed. Each of the early adenovirus type 3 RNAs was associated with polysomes in both cell types, suggesting that the abortive infection of hamster cells does not result from a defect in early adenovirus type 3 mRNA biosynthesis. No RNAs from regions transcribed late in infection of permissive cells were detected in BHK-21 cells.     

Epstein-barr virus-specific RNA. II. Analysis of polyadenylated viral RNA in restringent, abortive, and prooductive infections.

The complexity and abundance of Epstein-Barr (EBV)-specific RNA in cell cultures restringently, abortively, and productively infected with EBV has been analyed by hybridization of the infected cell RNA with purified viral DNA. The data indicate the following. (i) Cultures containing productively infected cells contain viral RNA encoded by at least 45% of EBV DNA, and almost all of the species of viral RNA are present in the polyadenylated and polyribosomal RNA fractions. (ii) Restringently infected Namalwa and Raji cultures, which contain only intranuclear antigen, EBNA, and enhanced capacity for growth in vitro, contain EBV RNA encoded by at least 16 and 30% of the EBV DNA, respectively. The polyadenylated and polyribosomal RNA fractions of Raji and Namalwa cells are enriched for a class of EBV RNA encoded by approximately 5% of EBV DNA. The same EBV DNA sequences encode the polyadenylated and polyribosomal RNA of both Raji and Namalwa cells. (iii) After superinfection of Raji cultures with EBV (HR-1), the abortively infected cells contain RNA encoded by at least 41% of EBV DNA. The polyadenylated RNA of superinfected Raji cells is enriched for a class of EBV RNA encoded by approximately 20% of EBV HR-1 DNA. Summation hybridization experiments suggest that the polyadenylated RNA in superinfected Raji cells is encoded by the same DNA sequences as encode RNA present in Raji cells before superinfection, most of which is not polyadenylated. That the same EBV RNA sequences are present in the polyadenylated and polyribosomal fractions of two independently derived, restringently infected cell lines suggests that these RNAs may specify functions related to maintenance of the transformed state. The complexity of this class of RNA is adequate to specify a sequence of a least 5,000 amino acids. That only some RNA species are polyadenylated in restringent and abortive infection suggests that polyadenylation or whatever determines polyadenylation may play a role in the restricted expression of the EVB genome.     

New gene expression in dimethylsulfoxide-treated friend erythroleukemia cells

Our previous studies had shown that a small amount of single-stranded DNA (ssDNA) separated from the bulk nuclear DNA of different animal cells by an improved method of hydroxylapatite chromatography (HAC) contains two distinct molecular fractions. The major fraction consists of non self-reassociating sequences that are reassociable to the unique component of bulk DNA and in great part hybridizable to homologous RNA. The minor fraction consists of self-reassociable sequences also reassociable to moderately repetitious bulk DNA. In the present work ssDNA from Friend leukemia cells induced to differentiate (ind FLC) by DMSO was compared with ssDNA from untreated control Friend cells (cont FLC). It was shown that the relative amount of ssDNA is greater in ind FLC than in cont FLC (1.5 – 1.6% and 1.2 – 1.3% of the total cell DNA respectively after a second step of HAC purification). The ind FLC-ssDNA contained a greater proportion of self-reassociable sequences (33–35%) as compared with cont FLC-ssDNA (18–20%). Also the relative amounts of ssDNA hybridizable to cytoplasmic RNA from homologous cells was slightly but constantly higher in ind FLC-ssDNA (33–34%) than in cont FLC-ssDNA (29–30%). Cross hybridizations were carried out between highly radioactive ssDNA and cellular RNAs in great excess, whether total cytoplasmic RNAs or polyadenylated mRNAs. At saturation levels, the hybridized ssDNA fraction was separated from the non-hybridized fraction, and both fractions were rehybridized to RNA from ind FLC or cont FLC. The results indicated that about 10% of ind FLC-ssDNA appeared to be specific for DMSO-treated cells. This may correspond to the expression of 1000–2000 different cytoplasmic mRNAs mostly belonging to the low abundance class.     

Relationship between nuclear and cytoplasmic RNA in Drosophilia cells.

Polyadenylated RNA was isolated from nuclei of cultured Drosophila cells, Schneider's line 2, and used as a template to synthesize a complementary DNA probe. Hybridization experiments were performed to study the relationship between nuclear and cytoplasmic RNA. About two-thirds of the nuclear polyadenylated RNA sequences exist in the cytoplasm. Experiments with fractionated cDNA probes demonstrated that RNA sequences that are frequent in the nucleus are also abundant in the cytoplasm. These findings are consistent with a precursor-product relationship in which some polyadenylated molecules in the nucleus are destined for the cytoplasm while other sequences are polyadenylated but not transferred.