Studies on the cytosolic DNA of chick embryo fibroblasts and its uptake by recipient cultured cells

Cytosol and extruded DNA complexes from cultured chick embryo fibroblast cells have been separated by agarose gel chromatography at intervals after pulse labelling with [3H]thymidine. The proportion of the various cytosol components changed markedly with time: there was a lag period of 3 hr before the major labelled (5 X 10(5) dalton) DNA complex appeared in the cytosol, and a further lag period of 5 hr before it was extruded from the cell. Cultured chick embryo fibroblast, and rat spleen, cells rapidly and very efficiently import their own or each others cytosolic DNA complexes into their respective cytosol fractions: the material recovered from the cytosol of recipient cells is characteristic of the presented material. Homologous cytosolic DNA complex presented to chick embryo fibroblast cells also becomes associated with the nucleus. The rat at which this occurs is comparable with the rate of incorporation of [3H]thymidine into nuclear DNA.     

Single-strandedness of the majority of DNA sequences complementary to mRNA-coding sites isolated from rat hepatoma tissue cultured cells

Single-stranded DNA (ssDNA), separated from bulk double-stranded DNA (dsDNA) of HTC by an improved method of hydroxyapatite chromatography, exhibited the same characteristics as ssDNA previously found in various cell species. It amounted to 1.5–2% of the total nuclear DNA. Only 24–26% could be self-reassociated, but the greatest part hybridized to non-repetitious DNA fraction and about 30% hybridized to homologous mRNA.Other results tend to prove that the complementary sequences of HTC-ssDNA probably consist of non-base-paired segments attached to double helical regions of dsDNA. In effect, after hydroxyapatite chromatography, a small portion of HTC-dsDNA (2–3%) was found to be rapidly digestible by S1 nuclease and this limited digestion was sufficient to reduce markedly the hybridization rates of dsDNA with both DNA and cell-free synthesised cDNA copies of polyadenylated RNAs. Furthermore, these ³H-cDNA copies could not be annealed to ssDNA under conditions that allowed their reassociation with total nuclear DNA. These findings complete the demonstration that the greatest part of ssDNA appears to be formed via selective nicks, probably enzymatic, in the coding strand of actively transcribed DNA regions.     

Sequence organization in nuclear deoxyribonucleic acid from Physarum polycephalum. Physical properties of foldback sequences.

An investigation was performed with the use of physical techniques, to determine the nature and organization of inverted repeat sequences in nuclear DNA fragments from Physarum polycephalum. From the average size of foldback duplexes (550 nucleotide pairs), and the foldback duplex yield as determined by treatment of DNA with S1 deoxyribonuclease followed by hydroxyapatite chromatography, it is estimated that there are at least 25000 foldback sequences in the Physarum genome. Foldback DNA molecules exhibit properties intermediate between single-stranded DNA and native duplexes on elution from hydroxyapatite with a salt gradient. In addition, thermal-elution chromatography of foldback DNA from hydroxyapatite crystals shows that foldback duplexes are less stable than native DNA. These properties can be explained on the basis that inverted repeat sequences are mismatched when in the foldback configuration. The results of experiments in which the binding of foldback DNA molecules to hydroxyapatite was determined, by using fragments of different single-chain size, agree with previous studies indicating that inverted repeat sequences are located, on average, every 7000 residues throughout the Physarum genome. The inverted repeats are derived from both the repetitive and single-copy components in Physarum nuclear DNA.     

Active DNA transcription sites released from the genome of normal embryonic chicken cells.

Single-stranded DNA (ssDNA) isolated from (and amounting to 1.5-2% of) native nuclear DNA of cultured embryonic chicken cells labelled 1-2 days with 3H-thymidine was analyzed by self-hybridization, hydroxyapatite chromatography (HAC) partial digestion with S1 nuclease, isopycnic centrifugation. Two main fractions were rehybridized to excess amounts of bulk nuclear DNA or total cytoplasmic RNAs. The major fraction, equivalent to 75% of total ssDNA, consists of unique DNA sequences, apparently derived from multiple coding regions of the cell genome, since they are not self-reassociating but are hybridizable to the non repetitious portion of bulk nuclear DNA and 40-45% of them are complementary to cell RNAs. About half of these ssDNA sequences hybridizable to cell RNAs seem to be closely connected with molecules belonging to the minor ssDNA fraction. The latter fraction consists of self-reassociating, moderately repeated DNA sequences, mainly derived from non coding regions of the cell genome. These findings are discussed in the light of others, showing interspersion of coding and non coding DNA sequences and susceptibility of active genes to certain nucleasic attacks.     

5-Methylcytosine in Chlorelle pyrenoidosa DNAs.

The presence of 5-methylcytosine in Chlorella pyrenoidosa (strain 211/8b) DNA's has been investigated by means of paper chromatography and thermal chromatography on hydroxyapatite. It has been shown that nuclear DNA contains 3.5 mol% 5-methylcytosine whereas no significant amount of this base can be detected in chloroplast DNA. The thermal chromatography of nuclear DNA labelled from [6-3H]- or [Me-14C] methionine lead us to conclude that the 5-methylcytosine content is directly proportional to the G + C content of the various DNA fractions. The existence of methylated sequences in DNA is postulated and the biological function of the 5-methylcytosine is discussed.     

Chick-embryo DNA polymerase gamma. Identity of gamma-polymerases purified from nuclei and mitochondria

The level of DNA polymerase gamma as compared to DNA polymerases alpha and beta has been determined in chick embryo by means of specific tests: the amount of gamma-polymerase in the 12-day-old chick embryo reaches about 15% of the total polymerase activity. This enzyme is mainly localized in nuclei and mitochondria, where it represents the prevailing if not the unique DNA polymerase activity. The mitochondrial DNA polymerase gamma is likely to be associated with the internal membrane or the matrix of this organelle since it is not removed by digitonin treatment. The gamma-polymerases have been purified from chick embryo nuclei and mitochondria 500-700 times by means of DEAE-cellulose, phosphocellulose and hydroxyapatite chromatographies. The purified mitochondrial DNA polymerase gamma is closely related to the homologous enzyme purified from the nuclei of the same cells. So far, they cannot be distinguished on the basis of their sedimentation, catalytical properties and response to inhibitors or denaturating agents. The purified gamma enzymes are distinct from the chick embryo DNA polymerases alpha and beta and are not inhibited by antibodies prepared against the latter enzymes. The nuclear and mitochondrial gamma-polymerases do not respond to the oncogenic RNA virus DNA polymerase assay with natural mRNAs.     

Repetitive DNA in differentiating chick tissues

Embryonic chick DNA from different tissues was examined for differences in relative content of highly repetitive DNA which might indicate specific DNA amplification in somatic cells. The content of repetitive sequences in DNA isolated from cerebrum, muscle, and neural retina tissues, at the same and at different embryonic stages, was determined by hydroxyapatite fractionation of partially reassociated DNA samples. An unrenatured marker DNA (C14-labeled E. coli DNA) was added to each chick DNA sample in order to monitor the nonspecific single-stranded DNA retention by each hydroxyapatite column. When chick DNA samples were sheared to a double-stranded length of 1,300 nucleotide pairs, an average of 20.2% +/- 2.2% of the DNA was found to reassociate at a Cot value of 10. The quantity of the fast reassociating sequences was found to constitute the same fraction of the DNA in all the tissues studied. In addition, all the reassociated DNA samples exhibited the same CsCl density classes. The studies also indicated that most chick DNA repetitive sequences are interspersed with nonrepetitive sequences.     

Relationship between single-stranded DNA isolated from cultured muscular cells during differentiation and the transcription of messenger RNA.

Single-stranded DNA (ssDNA), equivalent to about 2% of the total nuclear DNA, was isolated by an improved method of hydroxyapatite chromatography from native nuclear DNA of rat myoblast cells and myotubes of the L6 line. Small quantities of 125I-labelled ssDNA were annealed with a large excess of unlabelled DNA, cytoplasmic RNA and mRNA from myoblasts or myotubes. The results indicated that ssDNA belongs to the non-repetitious portion of the cell genome and is formed of two distinct molecular fractions. The major ssDNA fractions (75%) consist of non-self-reassociating DNA sequences and the minor fraction (25%) consists of self-reassociating DNA sequences. About 30--32% and 25--26% of ssDNA from myoblast represent DNA sequences complementary to total cytplasmic RNAs and polyadenylated RNAs respectively. Hybridizations of ssDNA with an excess of RNA from myoblasts and/or myotubes show differences in the abundance and the diversity of mRNA during mascular differentiation. These differences were confirmed by DNA-driven reactions between 125I-labelled polyadenylated RNA and ssDNA in great excess.     

Specificity and biological significance of microtubule-associated protein-DNA interactions in chick

The interactions between chick brain microtubule associated proteins (MAPs) and chick DNA have been examined using DNA-cellulose chromatography, cross-blotting, and nitrocellulose filter-binding. Comparison of nitrocellulose filter-binding and cross-blotting results show that while MAPs and a minor, M_r 48 000, protein show significant binding at 50 mM NaCl, only the latter continues to bind a significant amount of DNA at 150 mM NaCl, suggesting an ionic basis for the MAP-DNA interactions. MAP-DNA interactions also show weak preference for AT-rich fractions, and are sensitive to S1 nuclease digestion. We suggest that the MAPs bind preferentially to single-stranded DNA. The binding may involve an interaction between the DNA phosphates and the highly cationic tubulin-binding domain of the MAPs. Repetitive fractions of the chick genome prepared both by hydroxyapatite chromatography and by S1 nuclease digestion show binding to a number of minor proteins present in preparations of microtubule proteins, as well as to the MAPs. We conclude that the MAPs probably do not bind specifically to repetitive DNA, in contrast to earlier reports using mouse DNA. MAP-DNA interactions are therefore unlikely to be involved in the attachment of microtubules to mitotic chromosomes.     

Molybdate and the 1,25-dihydroxyvitamin D3 receptor from chick intestine

The nature of the 1,25-dihydroxyvitamin D3 receptor from chick intestine was examined in regard to its response to sodium molybdate. Sodium molybdate (10 mM) stabilized the receptor from crude nuclear extract but not that from the supernatant or cytoplasmic fraction, suggesting the molybdate may act by binding to the DNA binding region of the receptor. At a concentration of 50 mM, sodium molybdate prevented aggregation of the nuclear receptor. This concentration of sodium molybdate also inhibited the receptor from binding to DNA cellulose while the same ionic strength KCl (90 mM) did not. These properties also suggest that molybdate interacts with the DNA binding region. Purification of the receptor using DNA cellulose chromatography has also been improved by using a sodium molybdate gradient (0-0.2 M) instead of the KCl gradient used previously.     

Purification and characterisation of a growth factor from porcine bone

A growth factor was extracted from porcine bone matrix by demineralisation and purified by heat and acid treatment, hydroxyapatite chromatography and gel filtration under dissociative conditions and reverse-phase HPLC. Using the mitogenic response of osteoblast-progenitor cells from embryonic chicken, a mitogenic activity was purified 3000-fold. The mitogenic protein thus purified shows an apparent molecular mass of 13.5 kDa in both the nonreduced and reduced form on sodium dodecyl sulfate/polyacrylamide gel electrophoresis. The mitogenic activity is sensitive to proteinase K, dithiothreitol, and resistant to DNAse, RNase, heat (70 degrees C) and pH (3-10). The factor stimulates the proliferation of osteoblast-progenitor cells from embryonic chick at a concentration of 1 ng/ml. It is active on cells from skin, periosteum and sternum and has no or little activity on cells of the calvaria, intestine or kidney of embryonic chick or on mouse AKR-2B/Balb c/3T3 cell line.     

Initiation of DNA synthesis and uptake of T antigen by chick erythrocyte nuclei in hterokaryons with SV40-transformed human cells.

Nonsynchronized and hydroxyurea (HU)-synchronized SV40-transformed human cells (W98VaD) were fused with chick embryo erythrocytes (CE). The uptake of T antigen by CE nuclei was compared with initiation of chick nuclear DNA synthesis. Uptake of T antigen by CE nuclei occurred at about the same time after fusion with asynchronous as with HU-synchronized cells. CE nuclei rapidly became T antigen-positive between 16 h and 28 h after fusion and usually almost all CE nuclei were T antigen-positive by 48 h after fusion. In contrast, initiation of chick nuclear DNA synthesis occurred as a function of time after reversal of the HU block, when the host cell nuclei were also synthesizing DNA. Chick nuclear DNA synthesis occurred in many heterokaryons before the CE nuclei became T antigen-positive by immunofluorescence.     

Chemical and biological characterization of low-molecular-weight human skeletal growth factor

Skeletal growth factor (SGF) activity was extracted from human bone matrix by demineralization and purified under dissociative conditions using hydroxyapatite, HPLC gel-filtration and HPLC reverse-phase chromatography. Human SGF thus purified was characterized chemically and biologically. Purified human SGF stimulated chick embryo bone cell proliferation at picomolar concentrations (half maximum at 2-3 ng/ml) and had little or no activity on other cell types tested (mouse 3T3 and normal rat kidney fibroblasts, embryonic chick intestinal and human placental cells). Human SGF did not displace 125I-labeled epidermal growth factor binding to normal rat kidney cells and did not stimulate normal rat kidney cell colony formation in soft agar. Human SGF activity was sensitive to trypsin, chymotrypsin, papain, dithiothreitol and performic acid but was resistant to heat (upto 70 degrees C), pH (3-10), cyanogen bromide, alkaline phosphatase and neuraminidase and did not bind jack bean concanavalin A or kidney bean lectin. From our chemical and biological studies it appears that human SGF is different from other known polypeptide growth factors: epidermal growth factor, fibroblast growth factor, insulin, insulin-like growth factor-I, platelet-derived growth factor and transforming growth factor.     

DNA Repair in Human/Embryonic Chick Heterokaryons: Ability of Each Species to Aid the Other in the Removal of Ultraviolet-Induced Damage

Cultured human and embryonic chick fibroblasts possess different enzyme-mediated processes to repair cyclobutyl pyrimidine dimers induced in their deoxyribonucleic acid (DNA) by ultraviolet (UV) radiation. While dimers are corrected in human cells by excision repair, a photoenzymatic repair process exists in embryonic chick cells for the removal of these potentially deleterious UV photoproducts. We have utilized a sensitive enzymatic assay to monitor the disappearance, i.e. repair, of dimer-containing sites in fused populations of human and chick cells primarily consisting of multinucleate human/chick heterokaryons. Fused cultures were constructed such that UV photoproducts were present only in chick DNA when evaluating excision repair and only in human DNA when evaluating photoenzymatic repair. Based on the kinetics of site removal observed in these cultures we are led to conclude the following: Within heterokaryons per se the photoreactivating enzyme derived from chick nuclei and at least one excision-repair enzyme (presumably a UV endonuclease) derived from human nuclei act on UV-damaged DNA in foreign nuclei with an efficiency equal to that displayed toward their own nuclear DNA. Hence, after cell fusion these chick and human repair enzymes are apparently able to diffuse into foreign nuclei and once therein competently attack UV-irradiated DNA independently of its origin. In harmony with the situation in nonfused parental cultures, in heterokaryons the chick photoenzymatic repair process rapidly removed all dimer-containing sites from human DNA including the residual fraction normally acted upon slowly by the human excision-repair process.     

Satellite DNA in differentiating chick tissues

Embryonic chick DNA from different tissues was examined for differences which might indicate specific DNA amplification in somatic cells. The problem was approached by determining the DNA compositional heterogeneity and searching for possible variation in different tissues of the 12-day chick. Neural retina, muscle, and whole decapitated (general) chick DNA were analyzed in CsCl and Cs2SO4 density gradients. While overloaded CsCl gradients showed a main band (rho = 1.701 g/cm3) and a heavy shoulder (rho = 1.716 g/cm3), overloaded Cs2SO4 gradients displayed a main band (rho = 1.426 g/cm3) and a discrete heavy satellite (rho = 1.447 g/cm3). This satellite, comprising approximately 1% of the whole cell DNA, appeared to be of nuclear origin and not related to mitochondrial DNA, which was found to have a density of 1.426 g/cm3 in Cs2SO4. No differences were found in the densities of the main band or the satellite DNA in the DNA samples isolated from the different tissues. However, the method of DNA isolation was found to be of crucial importance when comparing satellite DNA's among different tissues.     

Further studies on the extrusion of cytosol macromolecules by cultured chick embryo fibroblast cells

The RNA and lipid-associated macromolecules extruded by chick embryo fibroblast cells have been analysed by chromatography. The results taken with those previously obtained suggest that cultured chick embryo fibroblasts excrete a wide range of cytosol macromolecules into the surrounding medium. As previously found with DNA and protein, the chromatographic patterns found with supernatant and cell cytosol preparations were closely similar, suggesting that the media supernatant macromolecules are cytosal derived. A proportion of the RNA and lipid associated material elutes at the same position as the previously observed for DNA and protein on gel exclusion chromatography, suggesting that cell cytosol contains a discrete DNA-RNA-protein lipid complex (size approx 5 X 10(5) dalton) which is extruded by cultured cells.     

Lysyl hydroxylase. Further purification and characterization of the enzyme from chick embryos and chick embryo cartilage.

A purification of up to 4000-fold is reported for lysyl hydroxylase (EC 1.14.11.4) from extract of chick-embryo homogenate and one of about 300-fold from extract of chick-embryo cartilage. Multiple forms of the enzyme were observed during purification from whole chick embryos. In gel filtration the elution positions of the two main forms corresponded to average molecular weights of about 580000 and 220000. These two forms could also be clearly separated in hydroxyapatite chromatography. In addition, some enzyme activity was always eluted between the two main peaks both in gel filtration and in hydroxyapatite chromatography. The presence of the two main forms was also observed when purifying enzyme from chick embryo cartilage. Both forms of the enzyme hydroxylated lysine in arginine-rich histone, which does not contain any -X-Lys-Gly- sequence. No difference was found between the enzyme from whole chick embryos and from chick embryo cartilage in this respect. Lysyl hydroxylase was found to have affinity for concanavalin A, indicating the presence of some carbohydrate residues in the enzyme molecule. Lysyl and prolyl hydroxylase activities increased when the chick embryo homogenate was assayed in the presence of lysolecithin. Preincubation of the homogenate either with lysolecithin or with Triton X-100 increased lysyl hydroxylase activity in homogenate, and in the 1500 x g and 150000 x g supernatants, suggesting that the increase in the enzyme activity was due to liberation of the enzyme from the membranes. Divalent cations were found to inhibit the activity of lysyl and prolyl hydroxylases in vitro. An inhibition of about 50% was achieved with 15 mM calcium 60 muM copper and 3 muM zinc concentrations. The mode of inhibition was tested with Cu2+, and was found to be competitive with Fe2+.     

Induction of anti-EBNA-1 protein by 12-O-tetradecanoylphorbol-13-acetate treatment of human lymphoblastoid cells.

Binding of the Epstein-Barr virus (EBV) nuclear antigen (EBNA-1) to BamHI-C DNA was studied by affinity column chromatography followed by immunoblotting with human serum specific for EBNA-1. Two species of EBNA-1 (68 and 70 kilodaltons) were identified in nuclear extracts of the EBV-positive Burkitt's lymphoma cell line Raji and not in nuclear extracts of the EBV-negative Burkitt's lymphoma cell line BJAB. Both EBNA-1s bound specifically to the region required for EBV plasmid DNA maintenance (oriP) located in the BamHI-C fragment. Upon treatment with 12-O-tetradecanoylphorbol-13-acetate, which activates latent EBV genome in Raji cells, the 68-kilodalton EBNA-1 was uncoupled from binding to EBV oriP. Nuclear extracts from 12-O-tetradecanoylphorbol-13-acetate-treated BJAB cells also uncoupled the binding of both EBNA-1s to oriP. DNA-cellulose column chromatography identified two protein species which competed for and uncoupled the binding of EBNA-1 to oriP. The two cellular competitors we called anti-EBNA-1 proteins had molecular masses of 60 and 40 kilodaltons, respectively. They were not found in nuclear extracts of BJAB cells not activated by 12-O-tetradecanoylphorbol-13-acetate.     

Characterization of inverted repeated sequences in Ascaris nuclear DNA

The inverted repeated sequences of the chromatin-eliminating nematode Ascaris lumbricoides var. suum have been examined by electron microscopy and by hydroxyapatite chromatography, both in the germ-line and in the somatic DNA. 38% of the inverted repeats of the germ-line DNA analysed in the electron microscope have a single-stranded loop, in comparison to about 50% of looped structures in the somatic DNA. The loops are on average 2.3 X 10(3) base pairs (bp) long. The rest of the foldback DNA consists of simple hairpins. The average length of looped and unlooped inverted repeats is of the order of 300-400 bp in the germ-line and in the somatic DNA. The content of S1-resistant foldback duplexes isolated by hydroxyapatite chromatography amounts to 1.3% in spermatids, with an average length of 350 bp, and to 1.1% in intestinal or larval cell nuclei, with a length of about 320 bp. We estimate by two different methods that there exist approximately 12500 inverted repeats per haploid germ-line genome and approximately 8000 in the haploid somatic genome. A statistical analysis of the data indicates that the great majority of the foldback sequences are randomly distributed in the Ascaris genome, with a spacing of about (40-80) X 10(3) bp, both in the germ-line and in the somatic DNA.