Studies in heterochromatin DNA: accessibility of late replicating heterochromatin DNA in chromatin to micrococcal nuclease digestion

Heterochromatin DNA in cactus mouse (Peromyscus eremicus) replicates in the late S phase of cell cycle. A method of obtaining cells which contain DNA preferentially labeled at heterochromatic areas by a pulse-labeling of late replicating DNA is described. When the nuclei of P. eremicus cells containing radioactively labeled DNA in heterochromatin were digested with micrococcal nuclease and the resultant nucleosomal DNA was separated by gel electrophoresis, it was found that the repeat length of nucleosomal DNA in the heterochromatin DNA is not different from that of the bulk of the genomic DNA. Furthermore, there was no significant difference in the accessibility to digestion by micrococcal nuclease between the late replicating heterochromatin DNA and the total DNA under our digestion conditions. Two dimensional gel electrophoresis patterns of nucleosomal DNAs isolated from micrococcal nuclease digested nuclei from P. eremicus, P. collatus, and P. crinitus cells in culture were very similar. Cytogenetic data showed that these three species are different in heterochromatin but similar in euchromatin.     

Further characterization of a cell-free system for measuring replicative and repair DNA synthesis with cultured human fibroblasts and evidence for the involvement of DNA polymerase alpha in DNA repair.

DNA repair synthesis can be specifically measured in osmotically opened, confluent cultured human fibroblasts after exposure to DNA damaging agents such that both induction and mediation of DNA repair synthesis can take place in this cell-free system. Alternatively, by utilizing osmotically shocked, log phase cells and altering the DNA precursors, pH and ionic strength, replicative DNA synthesis can be specifically monitored. Autoradiographic studies show that virtually all of the nuclei from the lysates of the confluent, UV-iradiated cells are lightly labeled in the fashion characteristic of DNA repair. By contrast, only a fraction of nuclei is labeled in a population of unperturbed, opened log phase cells and the labeling is heavy and characteristic of replicative synthesis. Furthermore, equilibrium density gradient sedimentation shows that DNA synthesis in lysates of log-phase cells is semiconservative, whereas that with UV-irradiated cells is repair synthesis. This open cell system has been used to study the enzymology of DNA repair. Thus, dideoxythymidine triphosphate, a specific inhibitor of DNA polymerases beta and gamma, does not inhibit either replicative or repair synthesis. By contrast, aphidicolin, a specific inhibitor of DNA polymerase alpha, inhibits DNA repair and replicative synthesis in both intact and permeabilized cells. Finally, phage T4 UV-exonuclease stimulates repair synthesis, but only when phage T4 UV-endonuclease is also added to the UV-irradiated nuclei.     

Characterization of guinea pig cytomegalovirus DNA.

The genome of guinea pig cytomegalovirus (GPCMV) was analyzed and compared with that of human cytomegalovirus (HCMV). GPCMV and HCMV DNAs were isolated from virions and further purified by CsCl centrifugation. Purified GPCMV DNA sedimented as a single peak in a neutral sucrose gradient and was infectious when transfected into guinea pig embryo fibroblast cells. The cytopathology was characteristic of that seen after infection with GPCMV. Virus DNA purified from virions isolated from infected GPEF or 104C1 cells had a CsCl buoyant density of 1.713 g/cm3, which corresponds to a guanine plus cytosine content of 54.1%. The CsCl buoyant density of GPCMV DNA was slightly less than that of HCMV DNA (1.716 g/cm3), but sufficiently different so that the two virus DNA peaks did not coincide. GPCMV DNA cosedimented with T4 DNA in a neutral sucrose gradient. Restriction endonuclease cleavage of GPCMV or HCMV DNAs with HindIII, XbaI, or EcoRI yielded fragments easily separable by agarose gel electrophoresis and ranging from 1.0 X 10(6) to 25.8 X 10(6) daltons. The number, size, and molarity of GPCMV DNA fragments generated by restriction enzymes were determined. Hybridization of restriction endonuclease-cleaved GPCMV DNA with radioactively labeled HCMV DNA and, conversely, hybridization of restriction endonuclease-cleaved HCMV DNA with radioactively labeled GPCMV DNA indicated sequence homology between the two virus DNAs.     

Differential methylation of mitochondrial and nuclear DNA in cultured mouse, hamster and virus-transformed hamster cells. In vivo and in vitro methylation

Information has been lacking as to whether mitochondrial DNA of animal cells is methylated. The methylation patterns of mitochondrial and nuclear DNAs of several mammalian cell lines have therefore been compared by four methods: (1) in vivo transfer of the methyl group from [methyl-³H]methionine; (2) in vivo incorporation of [³²P]orthophosphate and a combination of (1) and (2); (3) in vivo incorporation of [³H]deoxycytidine; (4) in vitro methylation of DNAs with ³H-labeled S-adenosylmethionine as methyl donor and DNA methylase preparations from L cell nuclei. The cell lines were mouse L cells, $\text{BHK21}\text{C13}$, $\text{C13}\text{B4}$ (baby hamster kidney cells transformed by the Bryan strain of Rouse sarcoma virus), and PyY (BHK cells transformed by polyoma virus). DNA bases were separated chromatographically, using 5-methylcytosine, 6-methylaminopurine and, in some cases, 7-methylguanine as markers.Mitochondrial DNA was found to be significantly less methylated than nuclear DNA with respect to 5-methylcytosine in all cell types studied and by all methods used. The relative advantages and disadvantages of each method have been discussed. The level of 5-methylcytosine in mitochondrial DNA as compared with that in nuclear DNA was estimated as one-fourth to one-fourteenth in various cell lines. The estimated 5-methylcytosine content per circular mitochondrial DNA molecule (mol. wt 10 × 10⁶) was about 12 methylcytosine residues for L cells and 24, 30 and 36 methylcytosine residues for BHK, B4 and PyY cells, respectively. Relative to cytosine residues, the estimate was one 5-methylcytosine per 500 cytosine residues of mitochondrial DNA and one 5-methylcytosine per 36 cytosine residues of nuclear DNA from L-cells. The values for methylcytosine of mitochondrial DNA are presumed to be maximal. PyY cells as compared with other cells had the highest methylcytosine content of both mitochondrial and nuclear DNA as estimated by method (3). No methylation of nuclear DNA was observed in confluent L cells.Evidence for the presence of DNA methylase activity associated with mitochondrial fractions was obtained. This activity could be distinguished from other cellular DNA methylase activity by differential response to mercaptoethanol. Radioactivity from ³H-labeled S-adenosylmethionine was found only in 5-methyl-cytosine of DNA.     

Uptake of bacterial DNA by Chlamydomonas reinhardi

Escherichia coli [³H]DNA supplied to vegetative cultures of wild-type (mt+) and CW15 (mt+; mutant lacking the cell wall) Chlamydomonas reinhardi could bind to the cell wall of the wild-type and to the cell membrane of CW15 mutant cells. The extent of this binding decreased with time and was to a large degree (over 90%) DNA-ase-sensitive. Nevertheless, about 0.01% of the bacterial DNA remained irreversibly associated with the cells when they reached stationary phase. The irreversible binding of the donor bacterial DNA to Chlamydomonas cells could be increased by treatment of the cultures with polycations such as DEAE-dextran, poly-L-lysine and poly-L-ornithine. Although the CW15 cells rapidly degraded bacterial DNA in the culture medium wild-type cells showed only a small effect on the molecular weight of the donor DNA.The acid-insoluble radioactivity irreversibly bound to WT (+) cells consisted mainly of oligonucleotides with a small proportion present as less depolymerized donor DNA. No radioactivity, however, was found to be associated with the recipient high molecular weight Chlamydomonas DNA.No labeled donor DNA could be recognized in the cells given bacterial [³H]DNA in early stationary phase. Instead, radioactivity found in Chlamydomonas DNA corresponded to reutilization of [³H]thymine derivatives released as a result of [³H] DNA degradation. No evidence for the integration of detectable amounts of donor DNA sequences into the host cell DNA was obtained.     

DNA damage: a consequence of the combined effect of virus infection and incorporated radioactive thymidine.

Infection of the human KB cell line with Frog Virus 3 brought about a partial degradation of radioactively labeled cell DNA as determined by alkaline sucrose sedimentation analysis. Further characterisation of this phenomenon revealed that degradation only occured when a sufficiently large amount of radioactive precursors was previously incorporated into the cell DNA. Therefore DNA damage appeared to be the result of a combined effect of incorporated radioisotopes and viral infection. It is suggested that the degradation of the radioactively labeled cell DNA could be a consequence of the inhibition of cell protein synthesis by frog Virus 3 since treatment of the cells with cycloheximide also led to DNA degradation.     

Integration of Rous sarcoma virus DNA during transfection

We have investigated the organization and integration sites of Rous sarcoma virus (RSV) DNA in NIH 3T3 mouse cells transformed by transfection with unintegrated and integrated donor RSV DNAs. RSV DNAs of different cell lines transformed by unintegrated donor DNA were flanked by different cellular DNA sequences, indicating that RSV DNA integrates at multiple sites during transfection. The RSV genomes of cells transformed by transfection were colinear with unintegrated RSV DNA, except that deletions within the terminal repeat units of RSV DNA were detected in some cell lines. These results suggested that the terminal repeat sequences of RSV DNA did not necessarily provide a specific integration site for viral DNA during transfection. In addition, cell lines transformed by integrated RSV DNAs contained both the RSV genomes and flanking cellular sequences of the parental cell lines, indicating that integration of integrated viral DNA during transfection occurred by recombinational events within flanking cellular DNA sequences rather than at the terminal of viral DNA. Integration of RSV DNA during transfection thus appears to differ from integration of RSV DNA in virus-infected cells, where the terminal repeat units of viral DNA provide a highly specific integration site. Integration of donor DNA during transfection of NIH 3T3 cells instead appears to proceed by a pathway which is nonspecific for both donor and recipient DNA sequences.     

An assay for the rates of cleavage of specific sites in DNA by restriction endonucleases: its use to study the cleavage of phage lambda DNA by EcoRI and phage P22 DNA containing thymine or 5-bromouracil by HindIII

A method to measure the rates of cleavage of specific sites in DNAs by restriction endonucleases is described. Partial digests are prepared by incubating DNAs with limiting amounts of endonuclease. The termini generated by cleavage are labeled with 32P by the polynucleotide kinase-exchange reaction. The labeled termini are then identified by completing the digestion with the same endonuclease and separating the products by gel electrophoresis. As the products of complete digestion of DNA are often easily separated and can be unequivocally identified, this procedure permits comparison of the rates of cleavage of specific sites in DNAs; furthermore, because detection of the products of cleavage utilizes radioautography and does not depend upon their size, or amount, only small amounts of DNA need to be utilized. This method has been used to examine the cleavage of phage lambda DNA by EcoRI endonuclease, and to demonstrate that 5-bromouracil substitution in phage P22 DNA reduces the rate of cleavage of most sites by HindIII endonuclease approximately threefold and the rate of cleavage of one site approximately tenfold.     

Transfer of cytoplasmic and nuclear proteins between cells in culture

Evidence is presented for transfer of proteins between cells in culture, using techniques which previously have shown RNA transfer and the lack of DNA transfer between cells in culture. These techniques involved making donor cells heavier than recipient cells by having them ingest tantalum particles. After coculture of donor and recipient cells the two cell types were separated by centri- fugation on Ficoll gradients and the recipient cells analyzed for radioactively labeled proteins that may have passed from the prelabeled donor cells.These techniques also provided evidence for passage of donor cell proteins to recipient cell nuclei. Examination of the nuclear proteins in the recipient cells revealed that histones were transferred intercellularly to a greater extent than other nuclear proteins. The histone subfractions in the recipient cell nuclei were studied by acrylamide gel electrophoresis. No major differences were found in the proportion of each histone subfraction that was transferred to the recipient cell nuclei.     

In vivo cleavage of cytosine-containing bacteriophage T4 DNA to genetically distinct, discretely sized fragments

Mutants of bacteriophage T4D that are defective in genes 42 (dCMP hydroxymethylase), 46 (DNA exonuclease), and 56 (dCTPase) produce limited amounts of phage DNA in Escherichia coli B. In this DNA, glucoylated 5-hydroxymethylcytosine is completely replaced by cytosine. We found that this DNA rapidly becomes fragmented in vivo to at least 16 discrete bands as visualized on agarose gels subjected to electrophoresis. The sizes of the fragments ranged from more than 20 to less than 2 kilobase pairs. When DNAs from two of these bands were radioactively labeled in vitro by nick translation and hybridized to XbaI restriction fragments of cytosine-containing T4 DNA, evidence was obtained that the two bands are genetically distinct, i.e., they contain DNA from different parts of the T4 genome. Mutational inactivation of T4 endonuclease II (gene denA) prevented the fragmentation. Three different mutations in T4 endonuclease IV (gene denB) caused the same minor changes in the pattern of fragments. We conclude that T4 endonuclease II is required, and endonuclease IV is involved to a minor extent, in the in vivo production of these cytosine-containing T4 DNA fragments. We view these DNA fragments as "restriction fragments" since they represent degradation products of DNA "foreign" to T4, they are of discrete size, and they are genetically distinct. Thus, this report may represent the first, direct in vivo demonstration of discretely sized genetically distinct DNA restriction fragments.     

Restriction and modification in B. subtilis: the role of homology between donor and recipient DNA in transformation and transfection

Non-modified DNAs from phages SPO2 and phi 105, and prophage DNAs extracted from lysogens carrying these phages, were used to transfect isogenic r+m+ B. subtilis recipients which were either non-lysogenic, or had been lysogenized with a homologous or a non-homologous phage. Restriction of transfecting phage and prophage DNA occurred in non-lysogenic recipients and in recipients lysogenic for a non-homologous phage. No effect of restriction was observed when phage or prophage DNA was used to transfect recipients carrying a homologous prophage. This is analogous to the absence of restriction in transformation and indicates that in B. subtilis the distinction between transforming and transforming and transfecting DNA is not made at the initial stages of DNA uptake and processing, but rather at later stages, where recognition of homologous regions in donor and recipient DNA plays an important role.     

Sequence specificity of the wild-type dam+) and mutant (damh) forms of bacteriophage T2 DNA adenine methylase

Non-glucosylated, non-methylated phage T2 DNA was methylated in vitro with partially purified wild-type (dam⁺) or mutant (dam^h) T2 DNA adenine methylase. The radioactively labeled methyladenine-containing DNA was enzymatically degraded and the resulting oligonucleotides were separated according to chain length by DEAE-cellulose chromatography. Following “fingerprinting” by two-dimensional electrophoresis, we determined the sequence for various di-, tri- and tetranucleotides containing radioactive N⁶-methyldeoxyadenosine. From this analysis we conclude that both T2 dam⁺ and T2 dam^h contain the sequence 5′…G-mA -Py…3′.     

Optimal conditions for uptake of exogenous DNA by Chinese hamster lung cells deficient in hypoxanthine-guanine phosphoribosyltransferase.

Conditions were characterized for maximizing the uptake of exogenous mammalian cell DNA by hypoxanthine-guanine phosphoribosyltransferase-deficient Chinese hamster lung cells. Recipient cell cultures in an exponential growth phase were found to be more competent in taking up DNA than stationary cultures. Polyornithine enhanced the uptake of exogenous DNA more reproducibly and to a greater extent than did any of the other facilitators tested (DEAE-dextran, CaCl2, latex spheres, spermine, polylysine and polyarginine). Maximal DNA incorporation occurred when polyornithine and DNA were mixed together prior to inoculation. About 25-30% of the DNA inoculum became deoxyribonuclease-resistant in a typical experiment utilizing polyornithine as the facilitator. Both homologous and heterologous exogenous DNAs rapidly became associated with recipient cell nuclei: approximately 95% of the deoxyribonuclease-resistant donor DNA was nuclear-associated 15 min after inoculation.     

Stimulation of DNA replication by growth factor and hormones in Swiss 3T3 cells: comparison of the rate of entry into S phase with in vitro DNA synthesis and DNA polymerase alpha activity

An approach to the investigation how growth factors and hormones regulate mammalian cell proliferation is to study the activity of enzymes involved in DNA replication. Quiescent cultures of Swiss mouse 3T3 cells were stimulated with prostaglandin F2 alpha, insulin, and/or hydrocortisone for a time at which less than 50% of the cells had initiated DNA synthesis. Such cells were lysed with a Ca++-containing hypotonic buffer and incubated with a nucleotide mixture including [3H]thymidine-triphosphate for 1 hr at 37 degrees C. The amount of radioactive label incorporated into the trichloroacetic acid (TCA)-precipitate and the percentage of labeled nuclei correlated with the in vivo stimulation. Analysis of radioactively and density-labeled DNA in sucrose and CsC gradients indicated that the incorporation of label reflected semiconservative replication. DNA polymerase activities were assayed in supernatants from whole-cell lysates prepared with a hypotonic buffer not containing Ca++. Using various templates, it was shown that the increase in activity of DNA polymerase alpha correlated with the percentage of cells in S phase upon the different stimulation, while DNA polymerase beta activity after various times of stimulation showed that this activity increased only when cells began to enter S phase, regardless of the combination of growth factor and hormones.     

Involvement of phage T5 tail proteins and contact sites between the outer and inner membrane of Escherichia coli in phage T5 DNA injection.

The penetration of phage T5 DNA into the Escherichia coli envelope takes place through ion channels (Boulanger, P., and Letellier, L. (1992) J. Biol. Chem. 267, 3168-3172). To identify putative phage protein(s) involved in the formation of these channels, E. coli cells were infected at 37 degrees C with radioactively labeled phage and their envelopes were fractionated. After a flotation gradient, proteins belonging to the phage tail were recovered both in fractions containing the contact sites between the inner and outer membranes and in the outer membrane. The electrophoretic banding pattern of phage proteins indicates that the contact sites were enriched in the protein pb2. Moreover, infected cells were significantly enriched in contact sites as compared to intact cells. There was no enrichment of contact sites and very little radioactivity was found in this fraction and in the outer membrane when the cells were infected at 4 degrees C (i.e. under conditions where the phage does not inject its DNA). These results suggest that both contact sites and pb2 may play a central role in the translocation of phage T5 DNA.     

Cell to cell transmission of donor DNA overcomes differential incorporation of non-homologous and homologous markers in Neisseria gonorrhoeae

The neisseriae are naturally competent for DNA transformation. This genetic study examines whether the modification status of chromosomal donor DNA affects transformation of Neisseria gonorrhoeae to drug resistance. When a single modification system was inactivated, unmodified chromosomal donor DNA was not restricted when used to transform the cognate restriction+ host, irrespective of whether the donor DNA carried a point mutation (homologous marker) or a drug-resistance gene cassette (non-homologous marker). These observations contrasted transformations performed with unmodified plasmid donor DNAs, where the incoming DNA was excluded. However, during the study, it became apparent that certain strains of gonococci showed differential incorporation of non-homologous markers when compared with the incorporation of the homologous marker, even when the donor DNAs were prepared from parental strains. Differential incorporation of markers could be rescued either through cell to cell transmission of donor DNA, or by performing in vitro transformations with donor DNA preparations that were obtained from spent culture supernatants. Overall, the data indicate that, in addition to the exclusion of foreign DNA through the requirement for a genus-specific uptake sequence, gonococci appear capable of excluding DNA on the basis of homology.     

Fate of heterologous deoxyribonucleic acid in Bacillus subtilis.

CsCl density gradient fractionation of cell lysates was employed to follow the fate of Escherichia coli, phage T6, and non-glucosylated phage T6 deoxyribonucleic acid (DNA) after uptake by competent cells of Bacillus subtilis 168 thy minus trp minus. Shortly after uptake, most of the radioactive Escherichia coli or non-glucosylated T6 DNA was found in the denatured form; the remainder of the label was associated with recipient DNA. Incubation of the cells after DNA uptake led to the disappearance of denatured donor DNA and to an increase in the amount of donor label associated with recipient DNA. These findings are analogous to those previously reported with homologous DNA. By contrast, T6 DNA, which is poorly taken up, appeared in the native form shortly after uptake and was degraded on subsequent incubation. The nature of the heterologous DNA fragments associated with recipient DNA was investigated with Escherichia coli 2-H and 3-H-labeled DNA. Association of radioactivity with recipient DNA decreased to one-fourth in the presence of excess thymidine; residual radioactivity could not be separated from recipient DNA by shearing (sonic oscillation) and/or denaturation, but was reduced by one-half in the presence of a DNA replication inhibitor. Residual radioactivity associated with donor DNA under these conditions was about 5% of that originally taken up. Excess thymidine, but not the DNA replication inhibitor, also decreased association of homologous DNA label with recipient DNA; but, even in the presence of both of these, the decrease amounted to only 60%. It is concluded that most, or all, of the Escherichia coli DNA label taken up is associated with recipient DNA in the form of mononucleotides via DNA replication.     

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.