DNA synthesis in HeLa cell nuclei isolated in a non-aqueous medium.

Nuclei were isolated from synchronized HeLa cells in the S-phase by a modification of the non-aqueous method described by Kirsch et al. (Science (1970) 168, 1592-1595). The method involved lyophilization of the cells, homogenization in non-aqueous glycerol and centrifugation in a gradient of 0-35% (w/w) 3-chloro-1,2-propanediol in glycerol. Such nucleic incorporated deoxyribonucleotides into DNA when incubated in an aqueous buffer containing Mg2+, ATP, dATP, dGTP, dCTP and dTTP. The product was sensitive to DNAase and banded with bulk DNA in isopycnic centrifugation. Sedimentation of the product in alkaline sucrose gradients after labelling of the nuclei for 2 min revealed labelled material in the 5 S peak and in the 18 S area. The material in the 5 S peak moved into the 12 S area after a 13 min chase.     

RNA metabolism in nuclei isolated from HeLa cells.

Nuclei with low cytoplasmic contamination, capable of synthesizing RNA for an extended period of time, were prepared from HeLa cells. Besides elongating RNA chains already initiated in vivo, the nuclear preparation initiates the synthesis of new RNA chains. This was shown by labelling the newly synthesized RNA with [gamma-32P]GTP and by detecting the presence of labelled guanosine tetraphosphate among the alkaline hydrolysis products of synthesized RNA. By synthesizing RNA in the presence of each of the four gamma-32P-labelled nucleoside triphosphates, it was possible to conclude that RNA chain synthesis starts predominantly with a purine base. Both nucleolar and nucleoplasmic RNAs are made. The nuclear preparation methylates the nucleolar RNA by utilizing S-adenosyl-L-methionine as a methyl-group donor.     

The effect of aphidicolin on DNA synthesis in isolated HeLa cell nuclei.

The effect of the inhibitor aphidicolin on DNA synthesis in isolated nuclei from HeLa cells and on the activities of partially purified DNA polymerases has been tested. Aphidicolin inhibited DNA synthesis and DNA polymerase alpha very efficiently whereas DNA polymerases beta and gamma were insensitive to the drug. The results indicate that DNA polymerase alpha is the polymerase active during elongation as well as in the gapfilling process of discontinuous DNA synthesis.     

Effect of cytosol on DNA synthesis in isolated HeLa cell nuclei

Cytosol obtained by centrifugation of cytoplasm from synchronized S-phase HeLa cells at 200 000 × g for 30 min had a stimulatory effect on the rate and extent of DNA synthesis in isolated nuclei. The cytosol preserved the ability of isolated nuclei to initiate early nascent intermediates (primary DNA pieces). The stimulatory activity was partially separated from the DNA polymerase activity present in the cytosol.     

Reinitiation of synthesis of small cytoplasmic RNA species K and L in isolated HeLa cell nuclei in vitro.

Isolated HeLa cell nuclei were used to synthesize low molecular weight RNA species in-vitro. The labelled RNA released from the nuclei during the incubation mainly consists of 5S RNA, pre-tRNA and small cytoplasmic RNA species K and L. All these low molecular weight RNA species are synthesized by RNA polymerase C (or III). The polyanion heparin was applied to study the reinitiation of these RNA molecules in-vitro. A comparison of the kinetics of RNA synthesis in the absence and in the presence of this inhibitor demonstrates a highly efficient in-vitro reinitiation of scRNA species K and L as well as 5S and pre-tRNA by RNA polymerase C. These results indicate a general competence of this enzyme to catalyze the de-novo formation of specific gene products in-vitro.     

DNA replication in isolated HeLa cell nuclei

DNA replication was investigated in HeLa cell nuclei isolated from different phases of the cell cycle. DNA synthesis occurred only in S-phase nuclei and was dependent on the presence of the four deoxynucleoside triphosphates, Mg⁺⁺, ATP and S-phase cytoplasm. G₁-phase cytoplasm was unable to support such DNA synthesis. A purified preparation of calf thymus DNA polymerase, however, was able to replace S-phase cytoplasm in supporting ATP dependent DNA synthesis, which suggests that the S-phase cytoplasmic factor is a DNA polymerase. G₁-phase nuclei could under no conditions be stimulated to initiate DNA replication prematurely.     

RNA annealing activities in HeLa nuclei.

RNA-RNA base pairing plays a critical role in the interactions between pre-mRNAs and trans-acting factors during the processing of pre-mRNAs (hnRNAs) into mRNAs, and it is likely that specific factors are required to promote the annealing of RNAs. To identify particular nuclear components that have such activity, we fractionated HeLa nucleoplasm and assayed for activity which promoted the hybridization of a pre-mRNA with an antisense RNA probe complementary to 60 nucleotides (nt) encompassing the 3' splice site. At least nine major RNA annealing activities were identified and, surprisingly, eight of these copurified partially or to homogeneity with known hnRNP proteins. The activities of three of these proteins, hnRNP A1, C1 and U, were confirmed using purified recombinant proteins. Moreover, we found that the RNA binding domain alone of hnRNP C1/C2 had significant activity, indicating that this RNA annealing may result, at least partly, from chaperone activity: a direct modulation of RNA conformation by hnRNP proteins. The finding that hnRNP proteins have strong RNA annealing activity indicates that they can profoundly affect the interactions of pre-mRNAs with trans-acting factors and suggests this to be an important function of hnRNP proteins in the processing of pre-mRNAs.     

Poly adenylic acid synthesis in vitro in isolated HeLa cell nuclei and whole cell homogenates,

Homogenates of HeLa cells and purified HeLa cell nuclei were found to synthesize poly(A) in vitro. The poly(A) is the normal adenylate-rich species seen in growing cells and is contained in large RNA molecules, which themselves have been synthesized at least in part in vitro. Poly(A) synthesis in purified nuclei shows a dependence on ATP concentration that is about 75–200 times higher than the concentration for total RNA synthesis.     

No stimulatory effect of added histones on DNA synthesis in isolated HeLa cell nuclei

Summary Contrary to some recent reports DNA synthesis in isolated HeLa cell nuclei wasnot stimulated by the addition of low amounts of histones neither in the presence nor in the absence of cytosol. The individual histone fractions H₁, H₂A, H₂B and H₃ also failed to stimulated DNA synthesis.     

Protein synthesis in isolated cell nuclei

1. Nuclei prepared from calf thymus tissue in a sucrose medium actively incorporate labelled amino acids into their proteins. This is an aerobic process which is dependent on nuclear oxidative phosphorylation. 2. Evidence is presented to show that the uptake of amino acids represents nuclear protein synthesis. 3. The deoxyribonucleic acid of the nucleus plays a role in amino acid incorporation. Protein synthesis virtually ceases when the DNA is removed from the nucleus, and uptake resumes when the DNA is restored. 4. In the essential mechanism of amino acid incorporation, the role of the DNA can be filled by denatured or partially degraded DNA, by DNAs from other tissues, and even by RNA. Purine and pyrimidine bases, monoribonucleotides, and certain dinucleotides are unable to substitute for DNA in this system. 5. When the proteins of the nucleus are fractionated and classified according to their specific activities, one finds the histones to be relatively inert. The protein fraction most closely associated with the DNA has a very high activity. A readily extractable ribonucleoprotein complex is also extremely active, and it is tempting to speculate that this may be an intermediary in nucleocytoplasmic interaction. 6. The isolated nucleus can incorporate glycine into nucleic acid purines, and orotic acid into the pyrimidines of its RNA. Orotic acid uptake into nuclear RNA requires the presence of the DNA. 7. The synthesis of ribonucleic acid can be inhibited at any time by a benzimidazole riboside (DRB) (which also retards influenza virus multiplication (11)). 8. The incorporation of amino acids into nuclear proteins seems to require a preliminary activation of the nucleus. This can be inhibited by the same benzimidazole derivative (DRB) which interferes with RNA synthesis, provided that the inhibitor is present at the outset of the incubation. DRB added 30 minutes later has no effect on nuclear protein synthesis. These results suggest that the activation of the nucleus so that it actively incorporates amino acids into its proteins requires a preliminary synthesis of ribonucleic acid. 9. Together with earlier observations (27, 28) on the incorporation of amino acids by cytoplasmic particulates, these results show that protein synthesis can occur in both nucleus and cytoplasm.     

DNA synthesis in isolated HeLa cell nuclei. Optimalization of the system and characterization of the product.

DNA replication in isolated nuclei from synchronized HeLa cells has been studied in an effort to optimalize the system and characterize the product. The synthesis was highly dependent on the four deoxyribonucleoside triphosphates, ATP, and Mg2+. Optimum pH was about 7.8. The system was further stimulated by monovalent ions with NH4Cl and Tris-HCl (each 65 mM) being the most effective. The four ribonucleoside triphosphates and glycerol gave a slight but very reproducible and additive stimulation. Low concentrations of spermine and spermidine (0.2-1.5 X 10(-4) M) were also slightly stimulatory (10-15%) whereas higher concentrations were inhibitory. The reaction product was DNase sensitive, and banded at 1.699 g/ml in neutral CsCl together with bulk HeLa nuclear DNA. When studied by neutral CsCl and alkaline Cs2SO4 gradients, the incorporation of [3H]TTP was mainly (more than 85%) due to further elongation of strands initiated in vivo as evidenced by BrdUrd labeling.     

A polymerase activity forming 5S and pre-4S RNA in isolated HeLa cell nuclei

Isolated HeLa cell nuclei are capable of synthesizing 5S and pre-4S RNA. The labeling of these low molecular weight species has been compared with the labeling of nucleolar RNA and nuclear heterogeneous RNA. The 5S and pre-4S RNA molecules made in vitro were identified by their mobility on SDS acrylamide gels and by the sensitivity of pre-4S RNA to enzymes which cleave it in vitro to 4S RNA. Their mobilities and cleavage properties are similar to the RNA made in vivo. Unlike the nuclear heterogeneous RNA, the synthesis of the two small molecular weight RNAs is resistant to α-amanitin.A large proportion of 4S RNA labeled in vitro appears to be formed de novo. The ratio of the terminal uridine to the internal uridine 3′-monophosphate remains constant with time, even though there is linear incorporation into the pre-4S RNA in the isolated nuclei.Production of the nucleolar RNA and pre-4S RNA has been compared in the presence of various ions. The pre-4S RNA synthesis has a sharper maximum for (NH₄)SO₄ and MgCl₂ than does the synthesis of nucleolar RNA. The in vitro synthesis of pre-4S is more sensitive to ellipticine and pCMB than the production of nucleolar RNA. These differences between the production of pre-4S RNA and nucleolar RNA are discussed with respect to in vitro reinitiation and the possibility that different polymerases are involved in their synthesis.