Evidence for a role of RNA in eukaryotic chromosome structure. Metabolically stable, small nuclear RNA species are covalently linked to chromosomal DNA in HeLa cells

An investigation of metabolically stable, chromatin-associated RNA in HeLa cells has revealed that three small RNA species, 193, 171 and 127 nucleotides in length, are covalently linked to double-stranded chromosomal DNA through phosphodiester bonds. These DNA-linked RNAs appear to be members of the small nuclear RNA species that have been identified in a wide variety of eukaryotic cells, and they are tentatively identified as species C, D and G′, in the nomenclature system currently employed for HeLa cell small nuclear RNAs. These DNA-linked RNAs do not appear to be involved in priming DNA replication, since they are of relatively high metabolic stability ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{= 19}$ hours in HeLa cells with a 21·5-hour cell generation time) and since their covalently contiguous DNA stretches are not enriched in newly replicated material. They lack saturated pyrimidine bases (level of detection = 0·15 mol %) and are therefore not “chromosomal RNA”, as defined by its proponents. The covalent linkage of these small RNA species with chromosomal DNA was discovered by virtue of the fact that when highly purified HeLa cell chromatin is dissociated by chaotropic solutes, these RNAs are released in association with small pieces of double-stranded DNA (approx. 475 nucleotide pairs). These DNA-RNA complexes can then be purified by removing the bulk, high molecular weight DNA by ultra-centrifugation. The resulting DNA-RNA complexes are shown to be covalently joined by several criteria, including equilibrium density-gradient centrifugation in either Cs₂SO₄/dimethylsulfoxide or aqueous Cs₂SO₄/formaldehyde after thermal denaturation (90 °C in 50% formamide, which is 55 deg. C above the melting temperature of this DNA), by the chromat ographicbehavior of the complexes on hydroxylapatite before and after thermal denaturation, and by the demonstration of alkali-resistant ribonucleotides flanking the 3′ hydroxyl termini of the DNA, the latter criterion providing evidence for 3′ to 5′ DNA-RNA phosphodiester bonds. Reconstruction experiments involving addition of the purified RNAs to nuclei or chromatin demonstrate that the covalent DNA-RNA linkages do not arise by ligation events during cell fractionation. Further experiments indicate the existence of a dynamic equilibrium of these small nuclear RNA species between chromosomal and nucleoplasmic loci in vivo, and other considerations suggest that this equilibrium may be cell cycle-dependent. The DNA adjacent to these covalently linked RNAs has the same melting temperature as total HeLa chromosomal DNA and its reassociation kinetics reveal the presence of both repeated and non-repeated sequences, implying that the DNA-linked RNAs are widely distributed throughout the HeLa cell genome. It is proposed that these DNA-linked RNAs are involved in the tertiary structure of chromatin, particularly in relation to the cell cycle.     

Factors affecting the formation of phytol and its incorporation into chlorophyll by homogenates of the leaves of the french bean Phaseolus vulgaris

The biosynthesis and phosphorylation of histone fractions were measured in synchronized CHO Chinese hamster cells arrested in late G₁ by hydroxyurea treatment. Hydroxyurea was found to inhibit the initiation of both DNA and histone synthesis, thus confirming the conclusion that it arrests cells in G₁ slightly before the $\text{G}{}_1\text{S}$ boundary. However, hydroxyurea did not inhibit the phosphorylation of histone f1 or histone f2a2. The phosphorylation of histone f1, which normally is absent in early G₁, begins 2 hr prior to DNA synthesis. In the presence of hydroxyurea, f1 phosphorylation occurs on schedule at this same time in G₁, resulting in significant G₁-phase f1 phosphorylation. This offers strong evidence that (a) f1 phosphorylation is not restricted to S phase; (b) “old” f1 which was synthesized in previous cell cycles is phosphorylated in G₁ before “new” f1 which is synthesized in S phase; and (c) G₁-phase f1 phosphorylation does not require new histone or new DNA synthesis.Histone f1 phosphorylation was observed to occur at accelerated rates in S phase over phosphorylation rates observed in late G₁-arrest. Data support the proposal that three different levels of f1 phosphorylation occur during the cell cycle: (1) a G₁-related phosphorylation of “old” f1; (2) an S-related phosphorylation of both “old” and “new” f1; and (3) a superphosphorylation of f1 associated with chromosome condensation during the G₂ to M transition. It is also possible that a limited proportion of f1 may be phosphorylated in G₁, perhaps at the initial DNA synthesis sites, and that an increased proportion of f1 is phosphorylated in S as DNA is synthesized. Similarities between the kinetics of histone f1 phosphorylation and the association of DNA with lipoprotein in synchronized control and hydroxyurea-treated cells suggest an involvement of f1 phosphorylation in cell-cycle-dependent chromatin structural changes.     

Histone phosphorylation in late interphase and mitosis

Histone phosphorylation in late interphase has been investigated employing cells synchronized by the isoleucine-deprivation method, followed by resynchronization at the $\text{G}{}_1\text{S}$ boundary using hydroxyurea. Phosphorylation occurred in both f1 and f2a2 as cells synchronously entered S phase following removal of hydroxyurea. The relative rates of phosphorylation of both species of histone increased in G₂-rich and metaphase-rich cultures. A small amount of histone f3 phosphorylation was also observed in M-rich cultures which was not seen in G₁, S, or G₂-rich cultures. It is concluded that f1 phosphorylation is not dependent on continous DNA replication. These experiments suggest consideration of the concept that f1 phosphorylation is initiated as a preparation for impending cell division.     

Ionophore A23187 raises cyclic AMP levels in macrophages by stimulating prostaglandin E formation.

A class of non-histone chromatin proteins that were bound tightly to DNA and could not be dissociated from the chromatin by high salt and urea was isolated from HeLa cell nuclei and separated from DNA by DNase digestion. These ‘tight’ proteins retained their ability to bind to single- and double-stranded DNA as assayed by nitrocellulose filter binding. Polyacrylamide gel electrophoresis showed that the most prominent proteins possessed molecular weights of about 60 000 D. In asynchronously growing HeLa cell cultures about $\text{1}\text{3}$ of the cell nuclei were immunoreactive to fluorescein-labeled antinucleoside antibodies. The immunoreactive cells were the fraction in S phase. Cycloheximide treatment of the cultures raised the fraction of immunoreactive nuclei to over $\text{sol2}\text{3}$. Exposure of the fixed cycloheximide-treated cell to tight proteins prior to staining with the antibody reduced the fraction of immunoreactive cells to the normal S phase level. Immuno-reactivity induced by X-irradiation or by the intercalating mutagen hycanthone was also suppressed by tight proteins. Cycloheximide treatment preferentially reduced the cellular content of tight proteins, suggesting that these proteins undergo a metabolic turnover with a half-life of about 5 h.     

Histone mRNA in eggs and embryos of Strongylocentrotus purpuratus

Histone messenger RNA is detectable in both the maternal RNA which is stored in the unfertilized sea urchin egg and in the RNA species which are synthesized $\text{de}$$\text{novo}$ after fertilization. Hybridization competition experiments show that sequences similar to pulse-labeled 912S RNA from morulae are present in total RNA from unfertilized eggs as well as that from later stages. The proportion of histone mRNA in cellular RNA increases after fertilization, reaching a maximum at the morula stage. Although these messengers are still present in hatched blastulae and gastrulae, they represent a smaller proportion of total RNA compared with earlier stages.     

Evidence for distinct mRNAs for ferritin subunits

Poly A enriched RNA from iron loaded HeLa cells and rat liver were translated separately and together in wheat germ lysates to investigate the origins of the H and L subunits of ferritin. Most of the ferritin translated from the HeLa RNA was of the H type, while that from the liver RNA was mostly L type. Mixtures of these RNAs gave $\text{H}\text{L}$ ratios which correlated with the relative amounts of added HeLa and rat RNAs. These results indicate that the H and L subunits of ferritin are not derived by post-translational modification but from distinct mRNA species.     

RNA-protein interactions in the ribosome. II. Binding of ribosomal proteins to isolated fragments of the 16 S RNA

Specific fragments of the 16 S ribosomal RNA of Escherichia coli have been isolated and tested for their ability to interact with proteins of the 30 S ribosomal subunit. The 12 S RNA, a 900-nucleotide fragment derived from the 5′-terminal portion of the 16 S RNA, was shown to form specific complexes with proteins S4, S8, S15, and S20. The stoichiometry of binding at saturation was determined in each case. Interaction between the 12 S RNA and protein fraction $\text{S}\text{16}\text{S}\text{17}$ was detected in the presence of S4, S8, S15 and S20; only these proteins were able to bind to this fragment, even when all 21 proteins of the 30 S subunit were added to the reaction mixture. Protein S4 also interacted specifically with the 9 S RNA, a fragment of 500 nucleotides that corresponds to the 5′-terminal third of the 16 S RNA, and protein S15 bound independently to the 4 S RNA, a fragment containing 140 nucleotides situated toward the middle of the RNA molecule. None of the proteins interacted with the 600-nucleotide 8 S fragment that arose from the 3′-end of the 16 S RNA.When the 16 S RNA was incubated with an unfractionated mixture of 30 S subunit proteins at 0 °C, 10 to 12 of the proteins interacted with the ribosomal RNA to form the reconstitution intermediate (RI) particle. Limited hydrolysis of this particle with T₁ ribonuclease yielded 14 S and 8 S subparticles whose RNA components were indistinguishable from the 12 S and 8 S RNAs isolated from digests of free 16 S RNA. The 14 S subparticle contained proteins S6 and S18 in addition to the RNA-binding proteins S4, S8, S15, S20 and $\text{S}\text{16}\text{S}\text{17}$. The 8 S subparticle contained proteins S7, S9, S13 and S19. These findings serve to localize the sites at which proteins incapable of independent interaction with 16 S RNA are fixed during the early stages of 30 S subunit assembly.     

Dynamics of association of origins of DNA replication with the nuclear matrix during the cell cycle

DNA of replication foci attached to the nuclear matrix was isolated from Chinese hamster ovary cells and human HeLa cells synchronized at different stages of the G₁ and S phases of the cell cycle. The abundance of sequences from dihydrofolate reductase ori-β and the β-globin replicator was determined in matrix-attached DNA. The results show that matrix-attached DNA isolated from cells in late G₁ phase was enriched in origin sequences in comparison with matrix-attached DNA from early G₁ phase cells. The concentration of the early firing ori-β in DNA attached to the matrix decreased in early S phase, while the late firing β-globin origin remained attached until late S phase. We conclude that replication origins associate with the nuclear matrix in late G₁ phase and dissociate after initiation of DNA replication in S phase.     

Histone gene expression during the cell cycle studied by in situ hybridisation

Cloned sea urchin histone gene DNA sequences have been in situ hybridized to histone RNA sequences in the cytoplasm of unsynchronized populations of Friend erythroleukemic cells, HeLa S3 and Chinese Hamster Ovary cells. S phase cells were detected by [³H]thymidine labelling of cell cultures prior to preparation for in situ hybridization. Autoradiography of the hybridized preparations has shown that in unsynchronized cells histone sequences are present in abundance in the cytoplasm of S phase cells only.     

Human histone genes are interspersed with members of the Alu family and with other transcribed sequences

We have isolated a series of recombinant λCh4A phages containing human histone genes. Histone H2A, H2B, H3 and H4 genes have been found to be clustered, but are not present in any simple repeat pattern. Hybridization of a blot containing phage DNA with S phase polysomal cDNA indicates the presence of additional sequences complementary to HeLa polysomal RNA sequences. Northern blot analysis using these clones as probes has also shown the presence of sequences complementary to non-histone-coding RNAs, some of which accumulate differentially in different stages of the cell cycle. We have also found, by hybridization with appropriate probes, that histone genes are interspersed with several copies of the Alu DNA family; however, not all of the histone genes are associated with an Alu DNA sequence.