Adenovirus DNA Replication I. Requirement for Protein Synthesis and Isolation of Nuclear Membrane Fractions Containing Newly Synthesized Viral DNA and Proteins

Nuclear membrane fractions were prepared by two procedures from KB cells pulse labeled with [(3)H]thymidine for 5 min late after infection with adenovirus 2: (i) the M-band technique, which yields a sharp peak containing most of the newly synthesized viral DNA, and (ii) the discontinuous sucrose gradient method, which yields three membrane fractions, one which bands at the interface between sucrose layers at density 1.18 and 1.20 g/ml and contains most of the newly synthesized viral DNA. Studies using cycloheximide to inhibit protein synthesis showed that proteins whose synthesis begins early after infection and occurs in the absence of viral DNA replication are required for viral DNA synthesis late after infection. To study the nature of these proteins, nuclear membrane fractions were isolated from cells labeled with [(3)H]leucine from 6 to 24 h postinfection in the presence of arabinosyl cytosine to block viral DNA replication, and were analyzed by electrophoresis in sodium dodecyl sulfate polyacrylamide gels. Two proteins of molecular weights 75,000 and 45,000 were the major labeled polypeptides in the nuclear membrane fractions prepared from infected cells both by the M-band and the discontinuous sucrose gradient methods. These two proteins were not found in nuclear membrane fractions from uninfected cells. It is suggested that the 75,000 and 45,000 proteins may be early viral gene products that may play a role in the viral DNA replication.     

Nuclear DNA Ligase and Its Action on Chromatin DNA in Neuronal, Glial and Liver Nuclei Isolated from Adult Guinea Pigs

Abstract: DNA ligase activities were measured in neuron-rich and glial nuclear preparations and liver nuclei isolated from adult guinea pigs. The enzymatic properties of cerebral and liver nuclear DNA ligases were studied with isolated nuclei and nuclear extracts. ATP (K_m= 46–48 μM) and bivalent cation (Mg²⁺ or Mn²⁺) were required for the maximal activities in cerebral and liver nuclei. β-Mercaptoethanol did not affect the activities, but N-ethylmaleimide and p-chloromercuribenzoate completely inhibited the activities. Deoxyadenosine-5′-triphosphate partially inhibited the activities in both cerebral and liver nuclei. An interdependent effect of Na⁺ and Mg²⁺ on the enzyme activities was observed. A high concentration (200 mM) of Na⁺ activated both enzymes and shifted to the acid side the optimal pH for both enzymes. DNA ligase was more easily extracted with lower concentrations of NaCl from liver nuclei than from cerebral nuclei, but the extraction curves from both nuclear species reached a plateau level (92% of total activities of nuclear enzymes) at 200 mM-NaCl. Apparent K_m for the substrate [³²P]phosphoryl DNA was determined according to a modification of the Michaelis-Menten equation, which was applied for the case where an unknown amount of substrate nicks in chromatin DNA coexisted with the nicks in exogenous substrate DNA. Neuronal and glial nuclear enzymes had similar K_m values (about 20 μg of [³²P]phosphoryl DNA/ml), but the liver nuclear enzyme had a higher K_m value (54 μg of [³²P]phosphoryl DNA/ml). The modified Michaelis-Menten equation provided the amounts of nicks available as substrate in chromatin DNA of isolated nuclei. Neuronal and glial nuclei contained 1.5 and 0.29 pmol of nicks/μg of nuclear DNA, respectively, in contrast to an intermediate amount of nicks in liver nuclei (0.63 pmol/μg of nuclear DNA). DNA ligase activity in neuronal nuclei [312 units (fmol of 5′-phosphomonoester converted into a phosphatase-resistant form per min at 37°C) per μg of nuclear DNA] was 11-fold higher than that in glial nuclei [28.7 units/μg of nuclear DNA]. Liver nuclei contained an intermediate activity [54.7 units/μg of nuclear DNA].     

Effect of undernutrition on DNA and RNA synthesis in subcellular fractions from different regions of the developing rat brain

The effect of undernutrition on the incorporation of [methyl-³H]thymidine into DNA and of 5-[³H]uridine into RNA of cerebral hemispheres, cerebellum, and brain stem was studied in vivo and in vitro in rats. The labeling of DNA from nuclei and mitochondria and of RNA from nuclei, mitochondria, microsomes, and soluble fractions, was also measured in vitro. The results demonstrate that nucleic acid synthesis is impaired and delayed during undernutrition. Specific effects were observed for the different brain regions and subcellular fractions: at 10 days nuclear and mitochondrial DNA and RNA synthesis was impaired, whereas at 30 days only the mitochondrial nucleic acid synthesis was affected.The delay of DNA and RNA labeling, caused by undernutrition, was most evident in the cerebellum, probably due to its intense cell proliferation during postnatal development. The specific sensitivity of mitochondria as compared to other subcellular fractions, may be due to the intense biogenesis and/or turnover of nucleic acids in brain mitochondria not only during postnatal development, but also in the adult animal.     

Extra DNA synthesis in the dedifferentiating cells ofVicia faba roots

Summary Cell dedifferentiation was induced inVicia faba root tissues by removing the whole root meristem (decapitation) and the behaviour of the nuclear DNA in the dedifferentiating cells was studied by means of cytophotometric and autoradiographic analyses. Cytophotometric determination after Feulgen-staining showed that: 1. the vast majority of nuclei in differentiated cells were in the DNA postsynthetic phase, but their Feulgen absorption was lower than that of DNA postsynthetic nuclei (G₂, 4 C) in the meristem; 2. such a Feulgen absorption was detected in certain nuclei after root decapitation; 3. all the mitoses in the dedifferentiating tissues were diploid, fully matching the Feulgen absorption of mitoses in the meristem.After³H-thymidine (³H-T) feeding of the decapitated roots and autoradiography, the following results were obtained: 1. two populations of labeled nuclei, characterized by two different levels of scattered labeling occurred in dedifferentiating tissues, slightly labeled nuclei being much more numerous than heavily labeled nuclei; 2. the percentage of labeled nuclei was much greater than that of DNA presynthetic nuclei in the root tissues; 3. almost all the mitoses were labeled after a 16-hour³H-T feeding; 4. the percentage of slightly labeled nuclei paralleled that of dedifferentiating cells; 5. the duration of the DNA synthesis phase and that of the gap between completion of DNA synthesis and mitosis differed in heavily and slightly labeled nuclei; 6. all nuclei which entered DNA synthesis also entered mitosis.These results are interpreted to mean that: 1. after decapitation, two different DNA syntheses occur in the dedifferentiating root tissues ofV. faba: DNA reduplication in cells which dedifferentiate starting from a DNA presynthetic nuclear condition (heavily labeled nuclei) and extra DNA synthesis in cells which dedifferentiate starting from a DNA postsynthetic nuclear condition (slightly labeled nuclei); 2. extra DNA synthesis is required in these dedifferentiating cells for entry into mitosis.     

Qualitative and Quantitative Studies on DNA and RNA Synthesis in Loxodes striatus Nuclei*

SYNOPSIS. In this study the characteristics of the synthesis of DNA and RNA in the nuclei of Loxodes were investigated. Loxodes striatus is a primitive ciliate with 2 pairs of structurally differentiated diploid nuclei, the macro- and micronuclei. The macronuclei are differentiated morphologically into a clearly recognizable central core and an outer zone. To determine DNA and RNA synthesis, individual organisms were analyzed by autoradiography after incubating groups of cells with a ³H-labeled precursor ([³H]thymidine for DNA and [³H]uridine for RNA). The following observations were made: (A) All portions of macro- and micronuclei appeared to contain DNA as judged by the localizations of incorporated [³H]thymidine. (B) The macro- and micronuclei did not synthesize DNA at the same time; moreover, the duration of DNA synthesis in the former was much longer than of the latter nucleus. (C) Replication of DNA in the inner core and outer zone of the macronucleus occurred at separate times with little if any overlap. (D) All of the detectable [³H]uridine incorporation was found in the macronucleus and none in the micronucleus. Within the macro-nucleus the central core was more heavily labeled. (E) The quantitative differences in the label of the different components of the nuclear complex were investigated. (F) Contrary to the previously reported information our results suggest that DNA synthesis can occur in adult macronuclei. The possible explanation of these results is discussed in the context of the nuclear evolution of ciliates and of recent information on nuclear differentiation.     

Calcium-binding protein regucalcin inhibits deoxyribonucleic acid synthesis in the nuclei of regenerating rat liver

The effect of regucalcin, a Ca²⁺-binding protein isolated from rat liver cytosol, on deoxyribonucleic acid (DNA) synthesis in the nuclei of regenerating rat liver was investigated. At 1 day after partial hepatectomy, the liver weight was increased about 50% of that of sham-operated rats, and it reached to the same levels as sham operation at 3 days after hepatectomy. Nuclear DNA synthesis was markedly increased at 1 day after hepatectomy, and this increase was also seen at 3 days. Nuclear DNA synthesis was clearly enhanced in the presence of EGTA (0.4 mM) in the incubation mixture. The presence of Ca²⁺ ( 1.0–25 M) caused a significant decrease in the nuclear DNA synthesis of normal rat liver. Regucalcin (0.25 and 0.5 M) clearly inhibited the nuclear DNA synthesis of normal rat liver. This inhibition was also seen in the presence of Ca²⁺ (1.0 M). Moreover, in the liver nuclei obtained at 1 day after partial hepatectomy, the presence of regucalcin (0.05–0.5 M) caused a remarkable inhibition of nuclear DNA synthesis. This effect was also revealed in the presence of EGTA (0.4 mM). Thus, the inhibitory effect of regucalcin was remarkable in regenerating rat liver nuclei in comparison with that of normal rat liver. The present results demonstrate that regucalcin can suppress nuclear DNA synthesis in regenerating rat liver. We suppose that regucalcin may have a role in the regulation of nuclear DNA synthesis in liver cell proliferation.     

Enhancement of nuclear Ca2+-ATPase activity in regenerating rat liver: involvement of nuclear DNA increase

The alteration of calcium content, Ca²⁺-ATPase activity, DNA content and DNA fragmentation in the nuclei of regenerating rat liver was investigated. Liver was surgically removed about 70% of that of sham-operated rats. the reduced liver weight by partial hepatectomy was completely restored at 3 days after the surgery. Regenerating liver significantly increased Ca²⁺-ATPase activity and DNA content in the nuclei between 1 and 5 days after hepatectomy. The nuclear calcium content was clearly increased from 2 days after hepatectomy. The increase of Ca²⁺-ATPase activity in regenerating liver was clearly inhibited by the presence of trifluoperazine (10 M), staurosporine (2.5 M) and dibucaine (10 M), which are inhibitors of calmodulin and protein kinase, in the enzyme reaction mixture. However, the nuclear enzyme activity in normal rat liver was not significantly altered by these inhibitors. Meanwhile, the increase of nuclear DNA content in regenerating liver was completely blocked by the administration of trifluoperazine (2.5 mg/100 g body weight), suggesting an involvement of calmodulin. Now, the nuclear DNA fragmentation was significantly decreased in regenerating liver, suggesting that this decrease is partly contributed to the increase in nuclear DNA content. The present study clearly demonstrates that regenerating liver enhances nuclear Ca²⁺-ATPase activity and induces a corresponding elevation of nuclear calcium content. This Ca²⁺-signaling system may be involved in the regulation of nuclear DNA functions in regenerating rat liver.     

Role of nuclear proteins on [H]actinomycin D binding during lymphocyte mitogenesis

The uptake of [³H]actinomycin D ([³H]AD) by ConA-stimulated lymphocytes was followed during 96 h of incubation and correlated with the level of nuclear proteins in the nucleus, DNA synthesis and the degree of AD-induced inhibition of RNA and DNA synthesis. During the first 48 h there is a parallel increase of drug binding to cells and a rising level of non-histone proteins (NHP) in the nucleus. During the next 48 h, DNA synthesis occurs, drug uptake decreases and the nuclear level of NHP continues to rise. The level of histones remains constant during 96 h. The variations in cellular [³H]AD uptake during 96 h are not due to changes in cell membrane permeability, since similar variations in drug binding are observed in isolated cell nuclei. NHP, obtained as 0.25 M NaCl extracts of cell nuclei, increase binding of [³H]AD to nuclei isolated from non-stimulated lymphocytes, while histones have no such effect. NHP extracted with phenol, after washing the nuclei with salt and acid solutions, or extracted with 0.25 M NaCl from non-stimulated and stimulated lymphocytes and Chang liver cells are equally active to bind [³H]AD to nuclei of non-stimulated lymphocytes. NHP from Chang cells, purified by DNA-cellulose chromatography using calf thymus DNA, stimulated [³H]AD binding to lymphocyte nuclei, indicating that the drug-binding activity is due to proteins binding to DNA. NHP increase binding of [³H]AD to pure DNA in the absence of histones. The degree of [³H]AD binding to ConA-stimulated lymphocytes during 96 h correlated with the degree of inhibition of RNA and DNA synthesis by AD.     

Role of nuclear proteins on [3H]actinomycin D binding during lymphocyte mitogenesis

The uptake of [³H]actinomycin D ([³H]AD) by ConA-stimulated lymphocytes was followed during 96 h of incubation and correlated with the level of nuclear proteins in the nucleus, DNA synthesis and the degree of AD-induced inhibition of RNA and DNA synthesis. During the first 48 h there is a parallel increase of drug binding to cells and a rising level of non-histone proteins (NHP) in the nucleus. During the next 48 h, DNA synthesis occurs, drug uptake decreases and the nuclear level of NHP continues to rise. The level of histones remains constant during 96 h. The variations in cellular [³H]AD uptake during 96 h are not due to changes in cell membrane permeability, since similar variations in drug binding are observed in isolated cell nuclei. NHP, obtained as 0.25 M NaCl extracts of cell nuclei, increase binding of [³H]AD to nuclei isolated from non-stimulated lymphocytes, while histones have no such effect. NHP extracted with phenol, after washing the nuclei with salt and acid solutions, or extracted with 0.25 M NaCl from non-stimulated and stimulated lymphocytes and Chang liver cells are equally active to bind [³H]AD to nuclei of non-stimulated lymphocytes. NHP from Chang cells, purified by DNA-cellulose chromatography using calf thymus DNA, stimulated [³H]AD binding to lymphocyte nuclei, indicating that the drug-binding activity is due to proteins binding to DNA. NHP increase binding of [³H]AD to pure DNA in the absence of histones. The degree of [³H]AD binding to ConA-stimulated lymphocytes during 96 h correlated with the degree of inhibition of RNA and DNA synthesis by AD.     

Cessation of Nuclear DNA Synthesis in Differentiating Naegleria*

SYNOPSIS. DNA synthesis during growth and differentiation in Naegleria gruberi strain NEG populations has been studied. Autoradiography of cells labeled with [³H]thymidine revealed that grains are concentrated over the nuclei in logarithmically growing populations of cells, whereas in differentiating cells, grains are scattered over the cytoplasm; i.e. no significant nuclear labeling is detectable. It was established by MAK chromatographic analysis that [³H]thymidine is incorporated into double-stranded DNA in Naegleria and that the actual amount of incorporation in the logarithmically growing populations of cells is 20 times greater than that in differentiating cells. These results suggest that nuclear DNA synthesis is reduced markedly soon after the initiation of differentiation, while cytoplasmic DNA synthesis continues. It was established from cell cycle analysis that the approximate intervals of G₁, S, G₂, and M phases were 180, 183, 90, and 28 min, respectively. Hence, the reduction in the nuclear DNA synthesis in differentiating cells is not due to the inhibition of initiation of DNA replication, but rather to the termination of the DNA replicating process. Thus DNA synthesis is curtailed in the presence of RNA and protein synthesis which are required for differentiation.     

DNA biosynthesis in rat liver mitochondria: Inhibition by sulfhydryl compounds and stimulation by cytoplasmic proteins

The sulfhydryl compounds, 2-mercaptoethanol, dithiothreitol, cysteine. and glutathione inhibit the incorporation of [³H]dTTP or [³H]dATP into mitochondrial DNA by rat liver mitochondria in vitro. The lack of inhibition by non-SH-containing analogs indicates that the SH group is responsible for the inhibition.The inhibition does not result from an effect of the sulfhydryl compounds on precursor permeability, ATP formation, or respiration, or the action of the thiol on the outer mitochondrial membrane. An intact inner membrane is not required for the action of the inhibitor. Furthermore, SH compounds do not appear to exert their effect by activation of a mitochondrial nuclease, chemical breakdown of high molecular-weight mitochondrial DNA or dissociation of membrane-bound DNA from the inner mitochondrial membrane. Incorporation of labeled precursor into DNA by mitochondrial DNA polymerase, when removed from the inner mitochondrial membrane, is not inhibited by SH compounds.Cytoplasmic extracts prepared from rat and mouse tumors and 22-h regenerating rat liver contain a protein(s) not detectable in normal rat liver which can reverse the inhibition by SH compounds of the synthesis of mitochondrial DNA in rat liver mitochondria in vitro.More importantly, when the stimulatory protein(s) is partially purified by affinity chromatography on DNA-cellulose, it is possible to demonstrate that this protein(s) also stimulates the synthesis of mitochondrial DNA by normal rat liver mitochondria in vitro in the absence of the sulfhydryl inhibitor.     

Nuclear fragmentation and DNA degradation during programmed cell death in petals of morning glory (Ipomoea nil)

We studied DNA degradation and nuclear fragmentation during programmed cell death (PCD) in petals of Ipomoea nil (L.) Roth flowers. The DNA degradation, as observed on agarose gels, showed a large increase. Using DAPI, which stains DNA, and flow cytometry for DAPI fluorescence, we found that the number of DNA masses per petal at least doubled. This indicated chromatin fragmentation, either inside or outside the nucleus. Staining with the cationic lipophilic fluoroprobe DiOC₆ indicated that each DNA mass had an external membrane. Fluorescence microscopy of the nuclei and DNA masses revealed an initial decrease in diameter together with chromatin condensation. The diameters of these condensed nuclei were about 70% of original. Two populations of nuclear diameter, one with an average diameter about half of the other, were observed at initial stages of nuclear fragmentation. The diameter of the DNA masses then gradually decreased further. The smallest observed DNA masses had a diameter less than 10% of that of the original nucleus. Cycloheximide treatment arrested the cytometrically determined changes in DNA fluorescence, indicating protein synthesis requirement. Ethylene inhibitors (AVG and 1-MCP) had no effect on the cytometrically determined DNA changes, suggesting that these processes are not controlled by endogenous ethylene.     

Cell cycle-related transfer of proteins between the nucleus and cytoplasm of Physarum polycephalum

The proteins of wild-type and polyploid plasmodia of P. polycephalum were prelabelled with [³H]leucine and [¹⁴C]leucine. The two types of plasmodia were then fused for 2 h. Following fusion the nuclei were isolated and the smaller wild-type cell nuclei separated from the larger polyploid cell nuclei. The proteins were isolated from the recipient cell nuclei and the recipient nuclear proteins extracted. Ratios of ³H/¹⁴C in the various nuclear protein fractions show that during fusion differential transfer of labelled preformed proteins from the donor cell into the recipient cell nucleus occurs. The quantity of proteins transferred varies among the different fractions and with the phase of the cell cycle. Isotopic dilution experiments indicate that these differences in protein transfer are, in part, due to a high rate of synthesis and turnover of the nuclear proteins.     

Effects of polyamines on DNA synthesis using various subcellular DNA polymerases extracted from normal rat liver, tumour-bearing rat liver, and tumour cells

The effects of polyamines on DNA synthesis in vitro using various subcellular DNA polymerase fractions from normal and tumour-bearing rat livers, and tumour cells were investigated. When nuclear and mitochondrial DNA polymerase fractions were used, DNA synthesis on activated DNA was increased 3.5-8-fold by the addition of 20 mM putrescine or cadaverine. However, DNA synthesis was not stimulated by the addition of spermidine or spermine at any concentration tested. In contrast, DNA synthesis using the cytoplasmic DNA polymerase fraction was not stimulated at various concentrations of any of the four polyamines tested. The stimulatory effects of putrescine and cadaverine were absent when nuclear fractions from tumour-bearing rat liver or from tumour cells were used. In addition, in vitro DNA synthesis was not stimulated by 20 mM putrescine or cadaverine when nuclear extracts from the livers of rats administered putrescine subcutaneously were used. The specific activities of DNA polymerases extracted from tumour cells and tumour-bearing rat liver were already fully stimulated. These results suggest that DNA polymerases in tumour cells and tumour-bearing liver cells are stimulated by trapped putrescine produced in tumour cells and are thus no longer activated by exogenous putrescine.     

Possible involvement of DNA-repair events in the transdifferentiation of mesophyll cells ofZinnia elegans into tracheary elements

In cultures of isolated mesophyll cells ofZinnia elegans, transdifferentiation into tracheary elements is induced by a combination of auxin and cytokinin and is blocked by inhibitors of DNA synthesis and poly (ADP-ribose) synthesis. During transdifferentiation, a very low level of synthesis of nuclear DNA was found in some cultured cells by microautoradiography after pulse-labeling with [³H]thymidine. Density profiles of nuclear DNA that had been double-labeledin vivo with bromodeoxyuridine (BrdU) and [³H]thymidine indicated that this DNA synthesis was repair-type synthesis. The sedimentation velocity of nucleoids increased during the culture of isolated mesophyll cells and the increase was dependent on phytohormones. This phenomenon may reflect the rejoining of DNA strand breaks after repair-type DNA synthesis during transdifferentiation. Treatment of cells with inhibitors of DNA synthesis or of poly(ADP-ribose) synthesis prevented the increase in the sedimentation velocity of nucleoids. The data suggest the involvement of DNA-repair events in the transdifferentiation of mesophyll cells into tracheary elements.     

DNA SYNTHESIS IN NEURONAL, GLIAL AND LIVER NUCLEI ISOLATED FROM THE ADULT GUINEA PIG

Abstract— [³H]Deoxythymidine-5′-triphosphate incorporation into P₅₁ (51% neuronal nuclei: 49% glial nuclei), P₃ (3% neuronal nuclei: 97% glial nuclei) and liver nuclear preparations, isolated from the adult guinea pig, was determined in the presence of the other three complementary deoxyribonucleo-tides. The enzymic characteristics of the DNA synthesis reaction were studied and DNA polymerase contents were estimated in neuronal, glial and liver nuclei. (1) Cerebral and liver nuclei exhibited similar enzymic properties for DNA synthesis activities with a few discrepancies. (2) P₅₁ nuclei synthesized DNA 2.4-fold more actively than P₃ nuclei. Liver nuclei carried out the most active DNA synthesis. The proportion of chromatin DNA available as template and primer was estimated by comparison with native calf thymus DNA. The available proportions found, in terms of the total chromatin DNA. were 2.39% for P₅₁ nuclei, 1.38% for P₃ nuclei and 37.6% for liver nuclei. (3) Exogenous native and heat-denatured calf thymus DNA were utilized as template and primer by DNA polymerase in nuclei in different ways depending on the nuclear species. The enzyme was saturated with native DNA by elevating the concentration and the activity reached a plateau. Denatured DNA inhibited the activity at the higher concentrations. (4) From the enzyme activities at a saturation concentration of exogenous DNA, DNA polymerase contents were estimated: P₅₁ nuclei, 39.2 ± 2.6 (s.e.m. ) units (fmol of TMP incorporated/30 min at 31°C)/μg of nuclear DNA; P₃ nuclei. 24.5 ± 1.6; and liver nuclei, 72.5 ± 8.1; the specific activity obtained on a protein basis was 1.55 times higher with P₃ nuclei than with P₅₁ nuclei. (5) Denatured DNA inhibited the nuclear DNA polymerase activity dependent on native DNA. The efficiency of inhibition was in the order: P₃ > P₅₁ > liver nuclei.     

Phosphorylation of nuclear matrix proteins in isolated regenerating rat liver nuclei

The phosphorylation of nuclear matrix proteins from normal and regenerating rat liver nuclei was examined using an $\text{in vitro}$ system of isolated nuclei and γ-³²P-ATP. Phosphorylation of the nuclear matrix proteins was 2–3 fold higher than that of the total nuclear proteins in normal nuclei. The level of phosphorylation of the matrix proteins was enhanced an additional three fold at a period in liver regeneration (12 hours) just preceding the onset of DNA synthesis.     

Preferential synthesis of plastid DNA and increased replication of plastids in cultured tobacco cells following medium renewal

During the culture of tobacco BY 2 cells derived from Nicotiana tabacum L. cv. Bright Yellow 2, morphological changes of plastid (pt) nucleoids and their replication were examined by fluorescence microscopy after staining with 46-diamidino-2-phenylindole. Upon transfer to fresh medium, the fluorescence intensity originating from pt nucleoids increased markedly. Copy numbers of ptDNA per cell calculated from the quantitative data by super-sensitive microspectroscopy increased 11-fold within 1 d of culture to reach 11 000, then decreased gradually to 1 000 after one week of culture. Autoradiography by labelling with [³H]thymidine showed that DNA synthesis in plastids occurred exclusively during the first day of culture, whereas nuclear DNA synthesis was observed from the first to the sixth day of culture. Replication of plastids was most frequently observed on the second day. Thereafter the formation of starch granules predominated in plastids up to the fifth day of culture, but the starch granules disappeared in the stationary-phase cells. The meaning of such preferential synthesis of ptDNA upon transfer to fresh medium is discussed in relation to the interaction between plastids and nuclei.Abbreviations pt plastid - DAPI 4,6-diamidino-2-phenylindole     

Phospholipids of outer and inner nuclear membranes in rat liver and BHK-21 cells

Isolated nuclei of rat liver and BHK-21 cells were treated with citric acid and the resulting outer nuclear membrane sheets were separated from the nuclear residues surrounded by the inner nuclear membrane. Both fractions contained approximately equal amounts of phospholipid in both cell types. The phospholipid compositions of the two fractions were remarkably similar. The results are in accordance with the notion of the structural continuity of the two nuclear membranes.