Active DNA transcription sites released from the genome of normal embryonic chicken cells.

Single-stranded DNA (ssDNA) isolated from (and amounting to 1.5-2% of) native nuclear DNA of cultured embryonic chicken cells labelled 1-2 days with 3H-thymidine was analyzed by self-hybridization, hydroxyapatite chromatography (HAC) partial digestion with S1 nuclease, isopycnic centrifugation. Two main fractions were rehybridized to excess amounts of bulk nuclear DNA or total cytoplasmic RNAs. The major fraction, equivalent to 75% of total ssDNA, consists of unique DNA sequences, apparently derived from multiple coding regions of the cell genome, since they are not self-reassociating but are hybridizable to the non repetitious portion of bulk nuclear DNA and 40-45% of them are complementary to cell RNAs. About half of these ssDNA sequences hybridizable to cell RNAs seem to be closely connected with molecules belonging to the minor ssDNA fraction. The latter fraction consists of self-reassociating, moderately repeated DNA sequences, mainly derived from non coding regions of the cell genome. These findings are discussed in the light of others, showing interspersion of coding and non coding DNA sequences and susceptibility of active genes to certain nucleasic attacks.     

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.     

Single-strandedness of the majority of DNA sequences complementary to mRNA-coding sites isolated from rat hepatoma tissue cultured cells

Single-stranded DNA (ssDNA), separated from bulk double-stranded DNA (dsDNA) of HTC by an improved method of hydroxyapatite chromatography, exhibited the same characteristics as ssDNA previously found in various cell species. It amounted to 1.5–2% of the total nuclear DNA. Only 24–26% could be self-reassociated, but the greatest part hybridized to non-repetitious DNA fraction and about 30% hybridized to homologous mRNA.Other results tend to prove that the complementary sequences of HTC-ssDNA probably consist of non-base-paired segments attached to double helical regions of dsDNA. In effect, after hydroxyapatite chromatography, a small portion of HTC-dsDNA (2–3%) was found to be rapidly digestible by S1 nuclease and this limited digestion was sufficient to reduce markedly the hybridization rates of dsDNA with both DNA and cell-free synthesised cDNA copies of polyadenylated RNAs. Furthermore, these ³H-cDNA copies could not be annealed to ssDNA under conditions that allowed their reassociation with total nuclear DNA. These findings complete the demonstration that the greatest part of ssDNA appears to be formed via selective nicks, probably enzymatic, in the coding strand of actively transcribed DNA regions.     

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.     

Properties of dispersed, highly repeated DNA within and near the hamster CAD gene.

Dispersed, highly repeated DNA sequences were found within and near the Syrian hamster gene coding for the multifunctional protein CAD. Most of the repeated sequences were homologous to each other and had similar properties. They hybridized to many cytoplasmic polyadenylated RNAs and to 7S and 4.5S cytoplasmic non-polyadenylated RNAs. Cloned DNA fragments containing repeated sequences were transcribed in vitro by RNA polymerase III. The repeated sequences from Syrian hamsters share many properties with the Alu family of repetitive DNA from humans. The hamster sequences were homologous to total repetitive human DNA but only very weakly homologous to two cloned members of the human Alu family.     

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.     

Cytoskeleton involvement in the distribution of mRNP complexes and small cytoplasmic RNAs

These studies were designed to determine whether small cytoplasmic RNAs and two different mRNAs (actin mRNA and histone H4 mRNA) were uniformly distributed among various subcellular compartments. The cytoplasm of HeLa S3 cells was fractionated into four RNA-containing compartments. The RNAs bound to the cytoskeleton were separated from those in the soluble cytoplasmic phase and each RNA fraction was further separated into those bound and those not bound to polyribosomes. The four cytoplasmic RNA fractions were analysed to determine which RNA species were present in each. The 7 S RNAs were found in all cytoplasmic fractions, as were the 5 S and 5.8 S ribosomal RNAs, while transfer RNA was found largely in the soluble fraction devoid of polysomes. On the other hand a group of prominent small cytoplasmic RNAs (scRNAs of 105-348 nucleotides) was isolated from the fraction devoid of polysomes but bound to the cytoskeleton. Actin mRNA was found only in polyribosomes bound to the cytoskeleton. This mRNA was released into the soluble phase by cytochalasin B treatment, suggesting a dependence upon actin filament integrity for cytoskeletal binding. A significant portion of several scRNAs was also released from the cytoskeleton by cytochalasin B treatment. Analysis of the spatial distribution of histone H4 mRNAs, however, revealed a more widely dispersed message. Although most (60%) of the H4 mRNA was associated with polyribosomes in the soluble phase, a significant amount was also recovered in both of the cytoskeleton bound fractions either associated or free of polyribosome interaction. Treatment with cytochalasin B suggested that only cytoskeleton bound, untranslated H4 mRNA was dependent upon the integrity of actin filaments for cytoskeletal binding.     

Epstein-Barr virus RNA in Burkitt tumor tissue.

Analysis of the viral RNA in four Burkitt tumor biopsies indicates that tumor tissue contains RNA homologous to at least 3–6% of the DNA of Epstein-Barr virus (EBV). Most of these RNA species accumulate in the polyadenylated RNA fraction of Burkitt tumor tissue. Two approaches have been used to determine the location within the EBV genome of the DNA sequences which encode stable RNA in two Burkitt tumor biopsies, F and S, which contain 6–10 copies per cell of at least 80% of the EBV genome. With the first approach, ³²P-EBV DNA homologous to polyadenylated or nonpolyadenylated RNAs from the F, S or R tumors was hybridized to blots of fragments of EBV DNA. With the second approach, polyadenylated or nonpolyadenylated RNAs from the F or S tumors were hybridized to separated, labeled fragments of EBV DNA in solution. The results indicate that first, most of the viral RNA in Burkitt tumor tissue is encoded by approximately 20% of the Hsu I D fragment, 20% of the Eco RI A/Hsu I A double-cut fragment and 3% of the Hsu I B fragment of EBV DNA; second, an abundant RNA species in tumor tissue is homologous to the “additional DNA” present in the W91 and Jijoye/HR-I Burkitt tumor isolates of EBV and absent in the B95-8 virus, an isolate of EBV from outside the Burkitt endemic region; and third, there is little or no homology to other regions of the EBV genome.     

Polyribosome Profiles and Polyribosome-Associated RNA of Friend Leukaemia Cells Following DMSO-induced Differentiation

Differentiation along erythroid lines is greatly increased when Friend leukaemia cells (FLC) are grown in the presence of dimethylsulfoxide (DMSO). Maturation is accompanied by alterations in the polyribosome profiles of the DMSO-treated cells as compared to that of control cells grown for the same periods of time. The ribosomes of the differentiating cells are present primarily as trimers, tetramers and pentamers, with a low proportion of larger polysomes. Polyribosomes consisting of more than five ribosomes are much more common in the control untreated FLC.
Agarose-acrylamide gel electrophoresis of radioactive uridine-labelled polysome-associated RNA from control and DMSO-treated cells demonstrates 4, 5, 5.5, 7, 9, 18 and 28S RNA species, as well as a series of RNAs which range from approximately 10S to 18S. The 5, 5.5, 18 and 28S RNAs have been tentatively identified as ribosomal RNAs, and the 4S and 7S RNAs may be transfer RNA and viral RNA respectively. The 9S RNA is probably the mRNA for histone, since its synthesis is inhibited in cells incubated with hydroxyurea. RNA which co-electrophoreses with the presumptive globin mRNA has been identified both in control, and in DMSO-treated cells. Although alterations in polyribosome patterns of DMSO-treated cells, as compared to control cells, have been readily demonstrable, no differences in the polyribosome-associated RNAs have been detected so far.     

New U1 RNA species found in Friend SFFV (spleen focus forming virus)-transformed mouse cells

The U1 RNA species in 10 mouse cell lines were examined by two-dimensional polyacrylamide gel electrophoresis. Seven cell lines that were not infected by Friend spleen focus forming virus gave only one (I) or two (I and II) U1 RNA-containing spots. However, two Friend cell lines (FVTCT and Friend 745a cells) gave three spots (I, II, and III) and another Friend cell line, K-1 cells, gave four spots (I, II, III, and IV). As a result of further separation and fingerprinting analysis of each spot, FVTCT and Friend 745a cells were found to contain U1a-1, U1b-1, -2, and -6 RNAs whereas K-1 cells were found to contain several U1 RNAs, which we call U1a-1 and -2, U1b-4, -5, and -6 RNAs. We determined the sequences of these seven U1 RNAs and found that mouse U1 RNAs had two basic sequences (U1a and -b). The nucleotide sequence of U1a-1 RNA was identical to that of rat U1a RNA, while U1a-2 RNA was one base different from U1a-1 RNA. Relative to U1a-1 RNA all of the U1b RNAs had five base substitutions and one additional base and were under-methylated in the center. U1b-6 RNA contained two base substitutions and one base addition in the 3'-terminal portion of U1b-1 RNA. U1b-2, -4, and -5 RNAs, which were observed only in Friend cells, each had an additional base substitution in the 5'-half of U1b-1 RNA.     

Cloned complementary deoxyribonucleic acid of Drosophila cells. Relationship of genome copy number to messenger ribonucleic acid abundance

Recombinant DNA plasmids containing DNA sequence complementary to poly(adenylic acid) [(poly(A)] containing RNA from the cytoplasm of Drosophila Kc tissue culture cells were constructed. The reiteration frequency in the genome of the RNA homologous to the 20 randomly selected clones was determined by two rapid methods. Of the 20, 17 were determined to be single copy, 2 were repeated several (2-4) times, and 1 was repeated approximately 10 times. The steady-state level of mRNAs homologous to the 20 cDNAs was quantitated and varied more than 160-fold. The RNAs ranged from 0.16% to less than 0.001% of the poly(A)-containing RNA.     

Characterization of Novikoff hepatoma small RNAs homologous to repetitive DNAs

Three minor small RNA species from Novikoff hepatoma cells, with homology to repetitive DNA sequences, have been identified and characterized. These small RNAs, designated 5.1S, 6S and T3 RNAs, show homology to Alu 1, Alu 2, and Alu 3 sequences, respectively. 6S and T3 RNAs were found both in the nucleus and cytoplasm, whereas 5.1S RNA was not found in the nucleus. Neural tissues were found to contain a 6S-sized BC1 RNA with homology to I.D. sequences [19]; in contrast, the current study shows that Novikoff hepatoma cells contain a 75–80 nucleotide long (T3) RNA, homologous to I.D. sequences. These data suggest that BCl and T3 small RNAs, homologous to I.D. sequences, are expressed in a tissue-specific manner. These results also show that in addition to the abundant 7SL, 4.5S and 4.5S1 RNAs having homology to repetitive DNA, Novikoff hepatoma cells also contain several minor small RNAs with homology to repetitive sequences.