Changes in the composition of double-stranded sequences of poly(A)-containing RNA in cell cytoplasm during hormonal induction

Double-stranded segments (c-ds) have been studied in the poly(A)+ cytoplasmic rat liver RNA. Duplexes about 40 base pairs long have been shown to be of intermolecular character and originate from the interaction between ss-RNA and complementary regions of the poly(A)-containing RNA molecules. Shorter ds-sequences are, mainly, of intramolecular nature. Double-stranded sequences of different length differ also in their oligonucleotide composition, according to fingerprint analysis data. Under the action of cortisone, only several kinds of double-stranded sequences have been demonstrated to increase in the population of cytoplasmic poly(A)+RNA. The function of ds-regions in the hormonal regulation of gene expression is suggested.     

Photosynthesis as a prototype of solar energetics of new type. I. Chlorophyll apparatus of photosynthesis

The hybridization of double-stranded regions of pre-mRNA from mouse Ehrlich ascites carcinoma cells, rabbit bone marrow cells and primary culture of rabbit kidney cells with an excess of total poly(A)+-mRNA of mouse or rabbit globin mRNA respectively was studied. The hybrids were detected as RNAase-stable acid precipitable material or by adsorbtion of the hybrid complexes of poly(U)-sepharose. The sizes of the hybrid complementary sequences and their thermal stability were estimated.     

Structure of nuclear pre-mRNA. IX. Hybridization of double-stranded portions of pre-mRNA with excess mRNA

The hybridization of double-stranded regions of pre-mRNA from mouse Ehrlich ascites carcinoma cells, rabbit bone marrow cells and primary culture of rabbit kidney cells with an excess of total poly(A)+-mRNA of mouse or rabbit globin mRNA respectively was studied. The hybrids were detected as RNAase-stable acid precipitable material or by adsorbtion of the hybrid complexes of poly(U)-sepharose. The sizes of the hybrid complementary sequences and their thermal stability were estimated.     

Comparison of cytoplasmic and nuclear poly(A)-containing RNA sequences in Xenopus liver cells.

Poly(A)-containing RNAs from cytoplasm and nuclei of adult Xenopus liver cells are compared. After denaturation of the RNA by dimethysulfoxide the average molecule of nuclear poly(A)-containing RNA has a sedimentation value of 28 S whereas the cytoplasmic poly(A)-containing RNA sediments slightly ahead of 18 S. To compare the complexity of cytoplasmic and nuclear poly(A)-containing RNA, complementary DNA (cDNA) transcribed on either cytoplasmic or nuclear RNA is hybridized to the RNA used as a template. The hybridization kinetics suggest a higher complexity of the nuclear RNA compared to the cytoplasmic fraction. Direct evidence of a higher complexity of nuclear poly(A)-containing RNA is shown by the fact that 30% of the nuclear cDNA fails to hybridize with cytoplasmic poly(A)-containing RNA. An attempt to isolate a specific probe for this nucleus-restricted poly(A)-containing RNA reveals that more than 10(4) different nuclear RNA sequences adjacent to the poly(A) do not get into the cytoplasm. We conclude that a poly(A) on a nuclear RNA does not ensure the transport of the adjacent sequence to the cytoplasm.     

Poly(A) polymerase activity in ethionine-intoxicated rats: the relative effectiveness of disaggregated and intact polyribosomes as primers for poly(A) polymerase

Ethionine intoxication causes a change in the metabolism of poly(A) sequences on the 3' OH terminus of mRNA in rat liver in vivo. In an attempt to determine the factors responsible for these changes, nuclear and cytoplasmic poly(A) polymerase activities and the state of the primer were examined in vitro. Requirements for optimal enzyme activities were determined. The nuclear and cytoplasmic enzymes had different K+, Mn2+, and poly(A) primer optima. The levels of nuclear and cytoplasmic poly(A) polymerase activity were shown to decrease following ethionine intoxication. Poly(A)+ RNA isolated from the livers of saline- and ethionine-treated rats served equally well as primers for the cytoplasmic poly(A) polymerase.Disaggregated polysomes were seven times more effective as primers than were intact polysomes. The results suggest that the mRNP particle which is released from polysomes as a result of ethionine intoxication functions better as a poly(A) polymerase primer than does the intact polysome.     

Differential accumulation of poly(A)+ RNA between virulent and double-stranded RNA-induced hypovirulent strains of Cryphonectria (Endothia) parasitica.

The double-stranded RNA responsible for transmissible hypovirulence in Cryphonectria (Endothia) parasitica was found to affect the accumulation of specific poly(A)+ RNA. Using differential hybridization techniques, two genes were isolated, Vir1 and Vir2, which were specifically expressed as poly(A)+ RNAs in the virulent cells. The highly expressed RNA sequences from these genes were not found in total RNA isolated from either American or European hypovirulent strains, although the genes were present in their genomes. Other virulence- and hypovirulence-specific RNA sequences were also detected. One isolated hypovirulence-specific RNA sequence was expressed in both virulent and hypovirulent cells, but in a two- to fourfold-higher concentration in the hypovirulent cells. The results show that hypovirulence is associated with concurrent changes in a few highly expressed poly(A)+ RNAs, which suggests a specific effect of the double-stranded RNA on fungal gene expression.     

Polyadenylic acid on poliovirus RNA. III. In vitro addition of polyadenylic acid to poliovirus RNAs.

A crude RNA polymerase preparation was made from HeLa cells infected for 3 h with poliovirus. All virus-specific RNA species labeled in vitro (35S RNA, replicative intermediate RNA [RI], and double-stranded RNA [dsRNA]) would bind to poly(U) filters and contained RNase-resistant stretches of poly(A) which could be analyzed by electrophoresis in polyacrylamide gels. After incubation for 45 min with [3-H]ATP in the presence of the other three nucleoside triphosphates, the labeled poly(A) on the RI and dsRNA migrated on gels as relatively homogenous peaks approximately 200 nucleotides in length. In contrast, the poly(A) from the 35S RNA had a heterogeneous size distribution ranging from 50 to 250 nucleotides. In the absence of UTP, CTP, and GTP, the size of the newly labeled poly(A) on the dsRNA and RI RNA was the same as it was in the presence of all four nucleoside triphosphates. However the poly(A) on the 35S RNA lacked the larger sequences seen when the other three nucleoside triphosphates were present. When [3-H]ATP was used as the label in infected and uninfected extracts, heterogeneous single-stranded RNA sedimenting at less than 28S was also labeled. This heterogeneous RNA probably represents HeLa cytoplasmic RNA to which small lengths of poly(A) (approximately 15 nucleotides) had been added. These results indicate that in the in vitro system poly(A) can be added to both newly synthesized and preexisting RNA molecules. Furthermore, an enzyme capable of terminal addition of poly(A) exists in both infected and uninfected extracts.     

Melting and reassociation of double-stranded RNA of the encephalomyocarditis virus]

The processes of melting and reassociation of double-stranded RNA in dimethylsulfoxide were studied. The addition of a small amount of LiCl results in great results in great reduction of Tm (temperature of melting), whereas the NaCl produces the opposite effect. It is suggested, that LiCl coordinates the molecules of H2O, reducing their activity, and consequently destabilises dsRNA. Mild conditions for melting and reassociation of RNA can be created. It was found that under optimal conditions for dsRNA melting, the degree of strand separation depends on the overall concentration of RNA, irrespective of the type of RNA added to the dsRNA preparation. Reassociation of dsRNA of EMC virus proceeds much faster than that of dsRNA of a related poliovirus. Addition of poly(C) to an annealing mixture slows down the rate of reassociation of EMC dsRNA, producing no effect on the poliovirus dsRNA reassociation. It is suggested that the presence of large poly(C) and poly(G) tracts in the complementary strands of the RNA determines its anomalous fast reassociation. Upon incubation of completely separated strands of EMC dsRNA in a water solution with high ionic strength partially double-stranded aggregates are formed. The formation of aggregates is prevented by addition of poly(A), which indicates that they are produced by "zippening" of a molecule starting with poly(A):poly(U) region. The significance of homopolymeric regions for stability of dsRNA of the EMC virus as well as their role in viral multiplication are discussed.     

Control of breakdown of the polyadenylate sequence in mammalian polyribosomes: role of poly(adenylic acid)-protein interactions

The poly(adenylic acid) [poly (A)] segment in mouse sarcoma polysomes in not hydrolyzed by snake venom exonuclease under conditions which cause extensive degradation of the poly(A) in deproteinized polysomal RNA. The protecting effect of polysomes is presumably caused by the interaction between the poly(A) sequence and the protein known to be associated with it. This protection is reduced at low KCl concentration, but addition of exogenous RNA restores the protecting effect. The poly(A) segment also becomes susceptible to exonuclease after fragmentation of the polysomes by mild ribonuclease treatment. The latter treatment releases the poly(A) in association with protein. The poly(A) sequence in polysomes in readily degraded by a cytoplasmic extract of S-180 cells. Partial purification leads to a preparation active against the poly(A) in polysomes under conditions where no fragmentation of the messenger RNA is observed. Snake venom exonuclease increases the activity of the cytoplasmic preparation against poly(A) in polysomes. The active cytoplasmic factor appears to interfere with the poly(A)-protein interaction, thus rendering the polynucleotide susceptible to degradation by exonuclease. The poly(A) sequences in polysomes and in free cytoplasmic nucleoprotein particles are hydrolyzed to the same extent. The results suggest that the poly(A) sequence is normally protected from nucleases by virtue of its association with protein. The slow reduction in poly(A) size in cytoplasmic mRNA can be accounted for by a factor capable of interfering with the poly(A)-protein interaction. The latter interaction seems also dependent on the structural integrity of the polysomes or messenger ribonucleoproteins. It is suggested that a polynucleotide segment adjacent to the poly(A) can modulate the affinity of the protein for the latter sequence, thus permitting control of poly(A) stability in individual messenger RNAs.     

Oligo(A) and double-stranded segments in polyadenylated and non-polyadenylated RNA from cytoplasm and nuclei of chick embryo

Chick embryonic RNA was fractionated by affinity chromatography on oligo(dT)-cellulose and poly(U)-Sepharose into three classes: poly(A)+RNA containing poly(A) segments of 100 and more residues, poly(A)-oligo(A)+RNA containing oligo(A) segments of about 25 residues, and poly(A)-oligo(A)-RNA which bound to neither of the beds used and which contained double-stranded segments of 300 and more base pairs. These three classes of RNA were found in cytoplasmic as well as in heterogeneous nuclear RNA. Double-stranded segments in hnRNA, unlike those in cytoplasmic RNA, were intermolecular in nature; this may explain the occurrence of "giant" molecules in hnRNA.