Purification of 14C-labelled deoxyribonuclease II from HeLa S3 lysosomes and its use as a marker for the study of nuclear deoxyribonuclease II

Deoxyribonuclease II (DNAase II) in mammalian cells has generally been considered to be located in the lysosomes. Several recent studies have indicated that some DNAase II activity is present in purified nuclei; this, however, could have been due to some contamination of the nuclear fraction by lysosomes, or alternatively, it could have been caused by specific binding of lysosomal DNAase II to the nuclear fraction during isolation. Our previous studies have eliminated the possibility that lysosomal contamination was the cause of the presence of DNAase II in isolated nuclei. In this study I have purified (14)C-labelled lysosomal DNAase II and added it to cells during isolation of their nuclei. This study demonstrates that there is no specific binding of lysosomal DNAase II to the nuclear fraction and concludes that DNAase II activity observed in isolated nuclei represents an intrinsic activity that might be involved in nuclear DNA metabolism.     

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.     

Isolation and purification of large quantities of DNA replication intermediates by pH step alkaline elution

The alkaline elution technique has been modified to be used in the isolation of DNA replication intermediates and in the study of the process of DNA replication. In this procedure pulse labeled CHO cells are layered onto a membrane filter, lysed with detergent, and the nascent DNA eluted in step-wise fashion with tetrapropylammonium hydroxide at pH 11.0, 11.3, 11.5 and 12.1. Alkaline sucrose sedimentation of the eluted DNA shows that the pH 11.0 material consists of < 9S fragments consistant with those described by Okazaki and others. DNA eluting at pH 11.3 has a molecular weight of 8–12 million daltons, DNA which elutes at pH 11.5 sediments with a molecular weight of 20–30 million daltons. Two independent lines of evidence suggest that the pH 11.3 material includes DNA sequences synthesized at replicon origins. (1) Exposure of cells to low doses of X-ray prior to pulse labeling reduces the pH 11.3 fraction by 40–50% while there is little change in the other fractions. (2) Synchronization of cells by inhibiting DNA synthesis with FdU, followed by a 2 min pulse label, yields approximately 50% of the incorporated ³H-thymidine in the pH 11.3 fraction. The pH step elution technique has the following advantages: 1. Intermediates of high specific activity can be isolated from 10⁶ cells per filter; 2. By lysing cells on a filter, proteins, nucleases, and other cellular materials are eliminated; 3. DNA in the lysate is never handled, thus eliminating shearing; 4. Eluted DNA may be instantaneously neutralized by collecting into a buffer to protect it from alkaline degradation.     

A Comparison of the Killing of Cultured Mammalian Cells Induced by Decay of Incorporated Tritiated Molecules at -196°C

The killing efficiency of tritium disintegrations in frozen mammalian cells labeled with tritiated uridine, histidine, and lysine was compared with the killing efficiency of incorporated tritiated thymidine. In each case, the distribution of tritium in the cells was determined by chemical fractionation as well as by radio-autography. Of all tritium disintegrations, by far the most effective were those occurring in DNA molecules within frozen cells; such incorporated tritium has a killing efficiency of 0.006. When cells were incubated with tritiated uridine for 10 min to label nuclear RNA, the killing efficiency was 0.0015. When the cells were pulse labeled with tritiated uridine and permitted to grow in nonradioactive media for 10 hr before freezing in order to incorporate tritium into cytoplasmic RNA, the killing efficiency was reduced to 0.0010. The results suggest that decay of tritium in nuclear RNA is more effective than that in cytoplasmic RNA. When the cells were labeled with tritiated histidine or lysine for 30 min, tritium atoms were found mainly in the acid soluble rather than in the protein fraction and the killing efficiency in each case was approximately 0.0007. The results of these suicide experiments indicate that the killing efficiency of tritium disintegrations depends on where tritium is located within the cells. Tritium disintegrations in the nucleus are more effective in killing the cell than that in cytoplasm; and tritium disintegrations on DNA in the nucleus is more effective in killing the cell than that of nuclear RNA.     

DNA replication and the nuclear membrane

To investigate the relationship between the nuclear membrane and DNA replication, Chinese hamster cells were labeled with tritiated thymidine and examined by electron microscope autoradiography. Unsynchronized cells were labeled for periods ranging from 0.5 to 20 minutes. There was no relative increase in the frequency of membrane-associated grains with the shorter labeling times, indicating that the replication point is not necessarily close to the nuclear membrane. When cells were synchronized to the beginning of the S period with mitotic selection and hydroxyurea, the percentage of membrane-associated grains was very low, indicating that DNA synthesis is not initiated at the nuclear membrane. When cells synchronized by mitotic selection were labeled at various times throughout the cell cycle, the percentage of peripheral grains was low in early S period and became progressively higher toward late S period as heterochromatin began to replicate. The labeling of Unsynchronized Microtus agrestis cells indicated that much of the peripheral labeling is due to the replication of intercallary heterochromatin. The results indicate that there is no association between the nuclear membrane and DNA replication.     

A fixed site of DNA replication in eucaryotic cells

We studied the role of the nuclear matrix (the skeletal framework of the nucleus) in DNA replication both in vivo and in a cell culture system. When regenerating rat liver or exponentially growing 3T3 fibroblasts are pulse-labeled with ³H-thymidine and nuclear matrix is subsequently isolated, the fraction of DNA remaining tightly attached to the matrix is highly enriched in newly synthesized DNA. After a 30 sec pulse labeling period and limited DNAase I digestion, the matrix DNA of 3T3 fibroblasts, which constitutes 15% of the total DNA, contains approximately 90% of the labeled newly synthesized DNA. Over 80% of this label can be chased out of the matrix DNA if the pulse is followed by a 45 min incubation with excess unlabeled thymidine. These and other kinetic studies suggest that the growing point of DNA replication is attached to the nuclear matrix. Studies measuring the size distribution of the matrix DNA also support this conclusion. Reconstitution controls and autoradiographic studies indicate that these results are not due to preferential, nonspecific binding of nascent DNA to the matrix during the extraction procedures. Electron microscopic autoradiography shows that, as with intact nuclei, sites of DNA replication are distributed throughout the nuclear matrix. A fixed site of DNA synthesis is proposed in which DNA replication complexes are anchored to the nuclear matrix and the DNA is reeled through these complexes as it is replicated.     

Repetitious and unique sequences in the heterogeneous nuclear and cytoplasmic messenger RNA of mammalian and insect cells

Initiation of DNA synthesis has been followed in mouse myeloma cells grown in suspension culture. In cells labeled with ³H-thymidine for short times, label first appears in short fragments of DNA which can be chased into bulk DNA (>50 S) upon further incubation in unlabeled thymidine. In a 15 min pulse, DNA fragments with a sedimentation coefficient of 30 S tend to accumulate. Our results support the contention that DNA synthesis is discontinuous in myeloma cells.However, a search for RNA associated with nascent DNA in the myeloma system was unsuccessful. Newly synthesized DNA was isolated on a benzoylated naphthoylated DEAE cellulose column. After heat denaturation, this fraction was centrifuged to equilibrium in a Cs₂SO₄ density gradient. The nascent DNA displays no shift in density greater than the density of the bulk DNA. When cells were pulse labeled with ³H-uridine and the nascent DNA fraction analyzed on Cs₂SO₄ density gradients, no ³H-labeled RNA was found associated with the DNA peak or at intermediate densities that would be indicative of a RNA-DNA molecule, covalently linked. Unless scission of the RNA primers occurs immediately after the initiation of DNA synthesis, our results indicate that DNA synthesis commences without RNA primers in myeloma cells.     

The nuclear associated endoplasmic reticulum and membrane biogenesis in MPC-11 cells

The incorporation of 3H-glucosamine, 3H-choline and 14C-fucose into subcellular fractions of MPC-11 cells was studied. After a 20 min period of labelling with both 3H-glucosamine and 3H-choline, greatest incorporation was observed in nuclear-associated endoplasmic reticulum (NER). 14C-fucose, however, was incorporated to a greater extent in endoplasmic reticulum (ER) membranes. Pulse-chase experiments with 3H-glucosamine showed a loss of radioactivity from NER and a simultaneous increase in the ER fraction. In comparison to NER, ER membranes were poorly labeled with 3H-glucosamine after a 20 min pulse. Following a 2 h incubation there was a 12 fold increase in radioactivity in ER membranes in comparison to a 1.2 fold increase in NER. There were no individual differences between subfractions of ER membranes with respect to 3H-glucosamine content after the pulse, or following the 2 h incubation. The results indicate that the NER is a major, early site of the synthesis of 3H-glucosamine labeled membrane glycoproteins, and that these proteins migrate into other ER membranes early after their synthesis.     

Insertion of newly synthesized proteins into the outer membrane of Escherichia coli.

The insertion of newly synthesized proteins into the outer membrane of Escherichia coli has been examined. The results show that there is no precurser pool of outer membrane proteins in the cytoplasmic membrane because first, the incorporation of a [35S]methionine pulse into outer membrane proteins completely parallels its incorporation into cytoplasmic membrane proteins, and second, under optimal isolation conditions, no outer membrane proteins are found in the cytoplasmic membrane, even when the membranes are analysed after being labeled for only 15 s. The [35S]methionine present in the outer membrane after a pulse of 15 s was found in protein fragments of varying sizes rather than in specific outer membrane proteins. This label could however be chased into specific proteins within 30--120 s, depending on the size of the protein, indicating that although unfinished protein fragments were present in the outer membrane, they were completed by subsequent chain elongation. Thus, outer membrane proteins are inserted into the outer membrane while still attached to ribosomes. Since ribosomes which are linked to the cell envelope by nascent polypeptide chains are stationary, the mRNA which is being translated by these ribosomes moves along the inner cell surface.     

Isolation of rapidly labeled RNA from mouse L-cells using cupric sulfate.

Cultured mouse L-cells, pulse labeled for 5 min with 3H-uridine, were gently suspended in 0.5mM cupric sulfate and 0.5% sodium dodecyl sulfate at 4 degrees C and treated with cold phenol. Only the RNA, containing less than 1% DNA, was extracted by this procedure. The rapidly labeled ribosomal RNA precursors (44S, 34S) and cytoplasmic 8S RNA showed specific activities higher than that of tRNA and were present in the RNA fraction insoluble in 2M NaCl.     

Analysis of the distribution of DNA repair patches in the DNA-nuclear matrix complex from human cells

The distribution of ultraviolet-induced repair patches along DNA loops attached to the nuclear matrix, was investigated by digestion with DNA-degrading enzymes and neutral sucrose gradient centrifugation. When DNA was gradually removed by DNAase 1, pulse label incorporated by ultraviolet-irradiated cells during 10 min in the presence of hydroxyurea or hydroxyurea/arabinosylcytosine showed similar degradation kinetics as prelabelled DNA. No preferential association of pulse label with the nuclear matrix was observed, neither within 30 min nor 13 h after irradiation. When the pulse label was incorporated by replicative synthesis under the same conditions, a preferential association of newly-synthesized DNA with the nuclear matrix was observed. Single-strand specific digestion with nuclease S1 of nuclear lysates from ultraviolet-irradiated cells, pulse labelled in the presence of hydroxyurea/arabinosylcytosine, caused a release of about 70% of the prelabelled DNA and 90% of the pulse-labelled DNA from the rapidly sedimenting material in sucrose gradients. The results suggest no specific involvement of the nuclear matrix in repair synthesis, a random distribution of repair patches along the DNA loops, and simultaneously multiple incision events per DNA loop.     

Reassociation kinetics of deoxyribonucleic acid in antigen-stimulated mouse-spleen cells.

In order to directly compare the complexity of the genome of lymphoid cells which have been antigenically stimulated, with that of non-immunized and non-lymphoid cells, DNA was pulse labeled and extracted from BALB/c mouse spleen cells at various time intervals after antigenic stimulation in vivo; the reassociation rates of these newly synthesized DNA preparations were compared with those of the total mouse spleen DNA, obtained from same sources and at the same times. DNA labeled for 60 min at 43, 53, or 72 h after antigenic restimulation, reassociated faster than the corresponding total DNA. On the other hand, the ressociation profile of DNA, labeled for 60 min during the first 24 after restimulation did not differ from that of the total DNA extracted at the same time. When labeled thymidine was available for incorporation at a constant concentration over a period of 24 h, reassociation patterns of labeled DNA were identical to those of the corresponding total DNA at all times after restimulation. Newly synthesized nuclear DNA exhibited reassociation profiles identical to those of the corresponding total nuclear DNA at all times tested. Also, no differences between the reassociation rates of nuclear and total cellular DNA were observed. It was concluded that antigenic stimualtion does not induce a major amplification of genes in the stimulated cells, and that the rapidly reassociating DNA species described represent extranuclear (cytoplasmic) DNA.     

Visualization of focal nuclear sites of DNA repair synthesis induced by bleomycin in human cells

In this study, we examined DNA repair synthesis in human cells treated with the radiomimetic drug bleomycin, which efficiently induces double-strand breaks (DSBs). Using tyramide-biotin to amplify fluorescent signals, discrete nuclear foci from the incorporation of 5-iododeoxyuridine (IdU) were detected in proliferating human cells treated with bleomycin. We believe this comes from the repair of DSBs. An increase in the number of foci (>5 per nucleus) was detected in a major fraction (75%) of non-S-phase cells labeled for 30 min with IdU 1 h after the end of bleomycin treatment. The fraction of cells with multiple IdU-containing foci was found to decrease 18 h after treatment. The average number of foci per nucleus detected 1 h after bleomycin treatment was found to decrease twofold between 1 and 3.5 h, indicating that the foci may be associated with the slow component of DSB repair. The presence of DSBs in bleomycin-treated cells was confirmed using antibodies against phosphorylated histone H2AX (gamma-H2AX), which is strictly associated with this type of DNA damage. After treatment with bleomycin, non-S-phase cells also displayed heterogeneous nuclear foci containing tightly bound proliferating cell nuclear antigen (PCNA), suggesting an ongoing process of unscheduled DNA synthesis. PCNA is known to be involved in base excision repair, but a fraction of the PCNA foci may also be associated with DNA synthesis occurring during the repair of DSBs.     

Adenovirus deoxyribonucleic acid replication. II. Synthesis of viral deoxyribonucleic acid in vitro by a nuclear membrane fraction from infected KB cells.

A cell-free system for the study of viral DNA replications was developed by the isolation of a nuclear membrane fraction "DNA replication complex" from adenovirus 2-infected human KB cells late after infection. This complex which possesses both DNA polymerase activity and a virus-specific endonuclease synthesizes exclusively virus-specific DNA sequences in vitro by a semiconservative mechanism. Analysis by rate zonal sedimentation in alkaline sucrose gradients showed that the products of the reaction are small DNA chains approximately 6 to 9 S, presumably "Okazaki intermediates," that are not sealed under our in vitro conditions. Analysis by rate zonal sedimentation in neutral sucrose gradients showed that labeled viral DNA fragments are hydrogen bonded to viral 18 S DNA segments, 0.25 the size of the linear, viral 31 S DNA genome. The 18 S DNA is probably a specific cleavage product of the viral endonuclease found in the replication complex and could represent intermediates in viral DNA replication or degradation products.     

Analysis of the distribution of DNA repair patches in the DNA-nuclear matrix complex from human cells

The distribution of ultraviolet-induced repair patches along DNA loops attached to the nuclear matrix, was investigated by digestion with DNA-degrading enzymes and neutral sucrose gradient centrifugation. When DNA was gradually removed by DNAase 1, pulse label incorporated by ultraviolet-irradiated cells during 10 min in the presence of hydroxyurea or hydroxyurea/arabinosylcytosine showed similar degradation kinetics as prelabelled DNA. No preferential association of pulse label with the nuclear matrix was observed, neither within 30 min nor 13 h after irradiation. When the pulse label was incorporated by replicative synthesis under the same conditions, a preferential association of newly-synthesized DNA with the nuclear matrix was observed. Single-strand specific digestion with nuclease S₁ of nuclear lysates from ultraviolet-irradiated cells, pulse labelled in the presence of hydroxyurea/arabinosylcytosine, caused a release of about 70% of the prelabelled DNA and 90% of the pulse-labelled DNA from the rapidly sedimenting material in sucrose gradients. The results suggest no specific involvement of the nuclear matrix in repair synthesis, a random distribution of repair patches along the DNA loops, and simultaneously multiple incision events per DNA loop.     

Phospholipid Metabolism and Membrane Synthesis During Sporulation in Bacillus megaterium

In view of previously published reports of localized membrane growth in exponentially growing Bacillus megaterium and in sporulating Bacillus cereus, an attempt was made to describe phospholipid metabolism and the topology of membrane synthesis during sporulation in B. megaterium. The cells were pulsed with radioactive glycerol or acetate at the time of septum formation, and the specific activity of the lipid fraction was measured at various times through the free spore stage. The bulk of the material labeled during septation could not be recovered in the spore. Rather, it was found that the labeled lipid fraction underwent considerable turnover during spore development. Additionally, other experiments revealed that the lipid made before the initiation of sporulation was also subject to extensive turnover. In order to minimize both the confounding effects of lipid turnover and the possible presence of lateral diffusion of labeled lipid in the membrane, autoradiography of cells pulse labeled with radioactive glycerol at the time of septation was performed; a symmetrical grain distribution resulted. Thus, despite previously published suggestions to the contrary, the current experimental techniques could not demonstrate the existence of localized membrane synthesis in B. megaterium during sporulation.     

Insertion of newly synthesized proteins into the outer membrane of Escherichia coli

The insertion of newly synthesized proteins into the outer membrane of Escherichia coli has been examined. The results show that there is no precursor pool of outer membrane proteins in the cytoplasmic membrane because first, the incorporation of a [³⁵S]methionine pulse into outer membrane proteins completely parallels its incorporation into cytoplasmic membrane proteins, and second, under optimal isolation conditions, no outer membrane proteins are found in the cytoplasmic membrane, even when the membranes are analysed after being labeled for only 15 s.The [³⁵S]methionine present in the outer membrane after a pulse of 15 s was found in protein fragments of varying sizes rather than in specific outer membrane proteins. This label could however be chased into specific proteins within 30–120 s, depending on the size of the protein, indicating that although unfinished protein fragments were present in the outer membrane, they were completed by subsequent chain elongation.Thus, outer membrane proteins are inserted into the outer membrane while still attached to ribosomes. Since ribosomes which are linked to the cell envelope by nascent polypeptide chains are stationary, the mRNA which is being translated by these ribosomes moves along the inner cell surface.     

Fine structural in situ analysis of nascent DNA movement following DNA replication

Nascent DNA (newly replicated DNA) was visualized in situ with regard to the position of the previously replicated DNA and to chromatin structure. Localization of nascent DNA at the replication sites can be achieved through pulse labeling of cells with labeled DNA precursors during very short periods of time. We were able to label V79 Chinese Hamster cells for as shortly as 2 min with BrdU; Br-DNA, detected by immunoelectron microscopy, occurs at the periphery of dense chromatin, at individual dispersed chromatin fibers, and within dispersed chromatin areas. In these regions DNA polymerase alpha was also visualized. After a 5-min BrdU pulse, condensed chromatin also became labeled. When the pulse was followed by a chase, a larger number of gold particles occurred on condensed chromatin. Double-labeling experiments, consisting in first incubating cells with IdU for 20 min, chased for 10 min and then labeled for 5 min with CldU, reveal CldU-labeled nascent DNA on the periphery of condensed chromatin, while previously replicated IdU-labeled DNA has been internalized into condensed chromatin. Altogether, these results show that the sites of DNA replication correspond essentially to perichromatin regions and that the newly replicated DNA moves rapidly from replication sites toward the interior of condensed chromatin areas.     

Nuclear membrane lipid peroxidation products bind to nuclear macromolecules

Ascorbate-Fe2+-driven lipid peroxidation processes in isolated rat liver nuclei give rise to products that bind to DNA and total nuclear proteins. This has been demonstrated by integrating [3H]arachidonic acid into the nuclear membranes. Lipid peroxidation was estimated from the formation of 2-thiobarbituric acid chromophore, and from the relative distribution of 3H-peroxidation products between the lipidic fraction and the nonlipidic fraction of the nuclear suspensions during incubation. The amount of 3H-peroxidation products associated with DNA and total nuclear proteins increased about threefold, when compared to control experiments (no ascorbate-Fe2+), after 180 min of incubation. In contrast, the radioactivity associated with the histone fraction was observed to decrease during incubation. The positive correlation obtained between the formation of thiobarbituric acid chromophore and the association of radioactivity with DNA and nuclear proteins indicates that the binding processes were dependent on peroxidation of the nuclear membrane lipids.     

Formation, size, and solubility in chloroform/methanol of products of protein synthesis in isolated mitochondria of rat liver and Zajdela hepatoma.

The number, size, solubility in chloroform/methanol and some aspects of the formation of the components labeled by radioactive amino acids in isolated mitochondria of rat liver and Zajdela hepatoma were studied. Isolated mitochondria were labeled with radioactive amino acids under various conditions, and the distribution of radioactivity in sodium dodecylsulfate-polyacrylamide gels after electrophoresis of mitochondrial membrane fraction was analysed. 1. Isolated mitochondria of rat liver and Zajdela hepatoma incroporated radioactive amino acids almost exclusively into the membrane fraction. Electrophoretic analysis of this fraction revealed the presence of 15 distinct peaks of radioactivity with corresponding apparent molecular weights of 10 000 to 58 000. The electrophoretic mobility of the labeled components was identical and the general pattern of the radioactivity distribution in the gel for the rat liver and the tumour mitochondria was very similar. 2. Components of the membrane fraction of rat liver mitochondria labeled in vitro displayed an unequal solubility in acidic (2 mM HC1) chloroform/methanol (2/1) mixture; as detected by sodium dodecylsulfate-polyacrylamide gel electrophoresis a single labeled component with apparent molecular weight of 10 000 was soluble in neutral chloroform/methanol. 3. Inverse relation was observed between amino acid incorporation activity of isolated mitochondria and the portion of the label incorporated into the component with apparent molecular weight 10 000. The identity of this component with that soluble in neutral chloroform/methanol mixture has been indicated. 4. The rate of incorporation of [3H]leucine by isolated Zajdela hepatoma mitochondria into the components with lower (10 000-25 000) apparent molecular weights decreased with time, whereas that into components with higher (above 25 000) apparent molecular weight remained approximately constant within the time interval tested (30 min). 5. From the total radioactivity incorporated into the membrane fraction during 5-min pulse labeling of isolated Zajdela hepatoma mitochondria by [3H]leucine up to 25% was recovered in the region of the gel corresponding to a component with apparent molecular weight 10 000. After 25 min chase the radioactivity in this region decreased about 3.5 times while the specific radioactivity of the total membrane fraction did not change significantly. The pattern of radioactivity distribution observed after the pulse was preserved by chloramphenicol. 6. Unlabeled sonicated mitochondria or postribosomal supernatant from rat liver regenerating in the presence of chloramphenicol were incubated with neutral chloroform/methanol extract of in vitro with [14C]leucine labeled rat liver mitochondria. After this incubation several labeled components with apparent molecular weights above 10 000 were recovered in the electrophoreograms of the originally unlabeled fractions.