Are there molecules of nucleoprotamine?

A short critical review of the data related to protamine and nucleoprotamine (DNP) structure is given. A new model is proposed for DNP structure in which protamine molecules are located in channels between the DNA molecules. DNA molecules are arranged hexagonally in the x–y plane, whereas their relative positions with respect to the z-axis are shifted by 0, 1/3, and 2/3 of the pitch of the double helix. As a result, large cavities are formed in three out of six channels surrounding each DNA molecule where the large grooves are juxtaposed. Protamine molecules are also proposed to have some secondary/tertiary structure prior to complex formation. Inside the channels, a protamine molecule modifies its shape to fill the large grooves of all of the three surrounding DNA molecules simultaneously, and might possibly be in touch with other protamine molecules in neighbouring positions as well. This disposition allows the protamine molecules to be located between DNA molecules without a significant increase in the lattice parameters. BioEssays 21:440–448, 1999. © 1999 John Wiley & Sons, Inc.     

Exploring the binding mode of donepezil with calf thymus DNA using spectroscopic and molecular docking methods

Donepezil (DNP) is one of approved drugs to treat Alzheimer's disease (AD). However, the potential effect of DNP on DNA is still unclear. Therefore, the interaction of DNP with calf thymus DNA (DNA) was studied in vitro using spectroscopic and molecular docking methods. Steady‐state and transient fluorescence experiments showed that there was a clear binding interaction between DNP and DNA, resulting from DNP fluorescence being quenched using DNA. DNP and DNA have one binding site between them, and the binding constant (K_b) was 0.78 × 10⁴ L·mol^?1 at 298 K. In this binding process, hydrophobic force was the main interaction force, because enthalpy change (ΔH) and entropy change (ΔS) of DNP–DNA were 67.92 kJ·mol^?1 and 302.96 J·mol^?1·K^?1, respectively. DNP bound to DNA in a groove‐binding mode, which was verified using a competition displacement study and other typical spectroscopic methods. Fourier transform infrared (FTIR) spectrum results showed that DNP interacted with guanine (G) and cytosine (C) bases of DNA. The molecular docking results further supported the results of spectroscopic experiments, and suggested that both Pi‐Sigma force and Pi‐Alkyl force were the major hydrophobic force functioning between DNP and DNA.     

Dinitrophenol Inhibits the Rejoining of Radiation-Induced DNA Breaks by L-Cells

The production and rejoining of X-ray-induced single-stranded DNA breaks was studied using the alkaline sucrose density gradient technique and by measuring the disappearance of both 5' termini and 3'-OH termini using polynucleotide kinase and DNA polymerase, respectively. All studies were conducted using L-cell suspensions irradiated both in the presence and absence of 2,4-dinitrophenol (DNP), an uncoupler of oxidative phosphorylation. Results show that the induction of single-stranded DNA breaks probably includes a nucleolytic component in addition to indirect free radical effects. A greater number of breaks were produced in the absence of DNP, suggesting that depressed adenosine triphosphate (ATP) levels reduce endogenous nucleolytic activity. The rejoining mechanism is enzymatic and requires an available ATP supply for operation. In the presence of DNP no DNA rejoining was observed following 30 min incubation after 10,000 rad. These results suggest that DNA breaks produced may be characterized by 5'-PO(4)-3'-OH termini and are rejoined by DNA ligase.     

Centrosome behavior in the exposure of tissue culture cells to energy metabolism inhibitors

The organization of the centrosome in PK cells has been analysed according to several parameters: the presence of primary cilium, the number of pericentriolar satellites, the presence of striated rootlets, the distance between two centrioles and their orientation as regards the substrate plane. 2,4-Dinitrophenol (DNP), DNP with deoxyglucose (DOG), sodium azide cause the increase of frequency of occurrence of primary cilia and the growth of mean number of satellites per active centriole. The distribution of active and inactive centrioles in control cells is described by a histogram corresponding to a histogram of accidental distribution. Under the action of DNP or DNP with DOG, but not of sodium azide a part of active centrioles settled down perpendicularly to the substrate plane increases. The orientation of inactive centrioles under all the treatments used doesn't practically change.     

The effect of gamma irradiation on the content in the thymus and liver chromatin of rats of DNA-bound proteins resistant to dissociation by phenol and sodium dodecylsulfate]

Two groups of proteins of 50-68 kD (A) and 12-14 kD (B) are the components of DNP preparations from rat thymus and liver obtained by washing with 0.075 M NaCl-0.024 M EDTA solution and deproteinization with phenol and dodecylsulfate (SDS). Immediately after irradiation with a dose of 10 Gy, there observed an approximately 1.5-fold increase in the content of only B proteins in the rat thymus fraction precipitated upon treatment with SDS-NaCl. The acidic amino acid content of this fraction and DNP preparation obtained without treatment with SDS amounts to 25 mol%; the ratio to basic amino acids was 1.3-1.4. The comparison of the amino acid content in the above DNP preparation and the "supramolecular DNA" preparation, described in the literature, that was obtained by the same phenol deproteinization and contained about 50 mol% of acidic amino acids, indicates the presence in the "supramolecular DNA" preparation of a component that increases upon irradiation: the component consists almost completely of acidic amino acids and is eliminated completely from the DNP preparation by washing with 0.075 M NaCl-0.024 M EDTA prior to deproteinization. The amino acid composition of the protein fraction A is presented.     

Fractionation of chromosomal deoxyribonucleoproteins by partition in two-phase aqueous polymer systems

Deoxyribonucleoprotein (DNP)¹ prepared by shearing chromatin of mouse cells may be fractionated in 2-phase aqueous Dextran-polyethyleneglycol mixtures. A partial separation of DNPs with different non-histone protein/DNA ratios may be obtained in a single-step partition. Separation of a spectrum of fractions of DNP has been obtained by countercurrent distribution using the same 2-phase polymer system. DNP fractions which bear nascent RNA (representing approximately $\text{1}\text{3}$ of the total DNA) may be separated from the major fraction of DNP; they are found in the same region of the distribution pattern as DNP fractions with the highest non-histone protein/DNA ratio.     

Labeling of DNA probes with a photoactivatable hapten

A photoactivatable reagent for introducing haptens onto DNA probes has been prepared using a commercially available bifunctional linker arm reagent and amino-derivatized 2,4-dinitrophenyl (DNP). The resulting compound (photo-DNP) couples efficiently to DNA using an ordinary sunlamp. Under optimum conditions, about 7-23 DNP molecules per 1000 bases are incorporated into the DNA. Hybridization experiments demonstrate that as little as 1.5 x 10(5) copies of target DNA can be detected by filter hybridization with a photo-DNP-labeled probe and immunochemical detection.     

THE FINE STRUCTURE OF THE DNP COMPONENT OF THE NUCLEUS : An Electron Microscopic Study Utilizing Autoradiography to Localize DNA Synthesis

In the present investigation, the sites of deoxyribonucleic acid (DNA) synthesis and the fate of labeled deoxyribonucleoprotein (DNP) were studied in autoradiographs of ultrathin sections viewed with the electron microscope. Tritiated thymidine was employed as a label for DNA in the nuclei of proliferating cells of regenerating salamander limbs. In the autoradiographic method reported here, dilute NaOH was used to remove the gelatin of the emulsion after exposure and development. The exposed silver grains are not displaced by this treatment and the resolution of fine structure in the underlying section is greatly improved. Our observations suggest that the DNP component is a meshwork of interconnected filaments 50 to 75 A in diameter, which may be cross-linked to form what Frey-Wyssling would term a "reticular gel." The filamentous DNP meshwork is dispersed throughout the interphase nucleus during DNA synthesis, whereas in chromosomes, which are relatively inert metabolically, the meshwork is denser and is aggregated into compact masses. Dense chromatin centers in interphase nuclei are similar in fine structure to chromosomes and are also inert with respect to DNA synthesis. In the Discussion, the structure of the filamentous meshwork in chromatin is compared with that in chromosomes, and speculations are made as to the functional significance of the variations in DNP fine structure observed.     

Studies of deoxyribonucleoproteins progressively depleted of proteins in solutions of variousionic strengths

The conformation of deoxyribonucleoprotein (DNP) from calf thymus at different stages of deproteinization was studied. The dissociation of the first portion of histone produces no effect on the hydrodynamical and optical behavior of DNP particles. The conformational transition of a macromolecule was observed as soon as the ratio of protein to DNA ? 0.9. The effect of ionic strength on the conformation of DNP particles with high protein content was more strongly pronounced than that for DNA. On the contrary, DNP particles depleted of proteins (protein/DNA < 0.9) were found to be less sensitive than DNA to the variation of ionic strength. These data imply that the DNP molecules rich in proteins possess a superstructure that is destroyed as the protein/DNA ratio becomes 0.9. The data were analyzed in view of current theories on various model concepts. The most probable model to describe the DNP molecule was chosen by comparing the calculated and experimentally obtained parameters. We believe that DNP is best described as a “compressed coil,” possibly including superhelical regions.     

The effect of polyene antibiotics on fractions of DNP both bound and not bound to dog kidney nuclear membranes]

Effects of amphotericine B and nistatine on nuclear membrane-bound DNP (DNPm) and free DNP (DNPf) from dog kidney are studied. Intravenous injection of amphotericine B resulted in the increase of binding of DNP particles with nuclear membrane: the content of DNA in DNPm fraction was 50-fold increased. The injection of nistatine did not affect DNP binding with nuclear membrane. Amphotericine B alone increased the protein-DNA ratio and decreased the RNA/DNA ratio in DNPf fraction. Both amphotericine B and nistatine sharply increased the protein/DNA ratio and practically did not change the RNA/DNA ratio in DNPm fraction. Amphotericine B produced considerable changes in temperature denaturation of DNA in DNPo, while nistatine produced no effect. Both antibiotics considerably changed the composition of acid soluble proteins in DNPm and DNPf, non-histone proteins in DNPf, and also they caused the changed and quantitative redistribution of separate lipid components in DNPm lipids. Polyene antibiotics are suggested to effect on animal cell nuclear structures.     

Interphase chromosomal deoxyribonucleoprotein isolated as a discrete structure from cultured cells

A new procedure is described for the preparation of interphase chromatin from cultured mouse cells (line P815). The primary objective of this procedure was to eliminate exchanges of histones between deoxynucleoprotein molecules; this objective is shown experimentally to have been attained. The chromatin is released from cells by the non-ionic detergent Nonidet P40 in medium of low ionic strength (0.1 mM-KNa₂PO₄), and may then be sedimented as a structure which conserves the general form and ultrastructural characteristics of chromatin within the cell. The nuclear envelope cannot be detected in these structures by electron microscopy, and their content of choline-containing phospholipids is less than 10% of that of nuclei. The maintenance of form in this structure must thus depend on properties of the chromatin itself, and possibly on the more compact peripheral chromatin.Soluble DNP² prepared by shearing these structures has the same relative contents of DNA, histones, non-histone proteins and RNA as DNP prepared by standard methods. Analyses by electrophoresis on polyacrylamide gels of the non-histone proteins reveals certain differences from the pattern of these proteins in DNP prepared by a salt precipitation method. The template activity for RNA synthesis, in the presence of Escherichia coli RNA polymerase of sheared, soluble DNP prepared by this procedure, is comparable to that of DNP prepared by other methods. However, in the absence of exogenous RNA polymerase the rate of RNA synthesis by structured (unsheared) chromatin is about ten times higher than the rate using sheared DNP.The rapid removal of the nuclear envelope in this lysis procedure allowed experimental examination of the origin of the histones and non-histone proteins of DNP. When DNP was prepared from a mixture of two populations of cells, one containing DNA distinguishable by a density label and the other containing radioactively labelled proteins, radioactive proteins were found exclusively in DNP of normal density, and not in dense DNP and vice versa. It is concluded that the proteins of DNP prepared in this way are not acquired during the preparation procedure but were already associated with DNA in vivo, and that other proteins are not bound non-specifically to DNA during the preparation of DNP. When a mixture of DNP molecules prepared, in this way is precipitated in 150 mm-NaCl and redissolved, some radioactively labelled histones migrate onto dense DNA molecules.This procedure is suitable for routine, quantitative isolation of chromosomal DNP from small numbers of cells; it is also applicable to cells of other cultured lines.     

Effect of UV-light on the structure of soluble deoxyribonucleoprotein-200 A]

The effects of UV-light (253,7 nm) on the structure of DNP and its protein and nucleic components were studied. The formation of protein-DNA covalent bonds in DNP-200 A at low ionic strength was confirmed. Under certain irradiation conditions more than 80% of protein may be linked to the DNA; all histone fractions were linked to the same extent and at the same rates. The local denaturation of DNA in the region of photo-induced thymine-thymine dimers and other photoadducts dramatically changed the rate and specificity of the effects of staphylococcal nuclease, which directly affected the composition and size of the fragments formed. A possible application of UV-irradiated DNP for various structural investigations is discussed.     

Changes in chromatin structure at the replication fork. DNase I and trypsin-micrococcal nuclease effects on approximately 300- and 150-base pair nascent DNAs

DNase I, trypsin, and micrococcal nuclease are used to further probe the structure of nascent deoxyribonucleoprotein (DNP) fractions which appear after in vivo 20-s pulse labeling of sea urchin embryos with [3H]thymidine. We present evidence that the large nascent DNP which protects the approximately 300-base pair large nascent DNA consists of at least one nucleosome core. This is based on fractionation in denaturing polyacrylamide gels of DNA extracted from large nascent DNP fractions of a micrococcal nuclease + DNase I digest of nuclei. The data also suggest the existence of a DNase I-hypersensitive site(s) within the large nascent DNP; this is consistent with the hypothesis that the latter consists of closely packed dinucleosome cores. Histone H1 and non-histone proteins do not account for the previously reported unusual hyperresistance of the large nascent DNA against micrococcal nuclease. The protection offered this approximately 300-base pair nascent DNA was not eliminated by an 0.2-microgram/ml trypsin pretreatment which removes the above proteins from the chromatin. However, 5-10 micrograms/ml of trypsin, which remove a portion of the NH2 termini of the four core histones of nucleosomes, eliminate the hyperresistance of the large nascent DNA to subsequent micrococcal nuclease digestion, while nascent and bulk monomer DNAs remain unaffected. This indicates histone-histone and/or histone-DNA interactions within the large nascent DNP which differ from those of nascent and bulk mononucleosome cores.     

Studies on deoxyribonucleoprotein structure. Small-angle X-ray scattering in solutions of various ionic strengths.

The cross-sectional radius of gyration of the deoxyribonucleoprotein (DNP) threads was measured by small-angle X-ray scattering in a wide range of ionic strengths (from 0.0005 to 2 M NaCl). For DNP in a solution of low ionic strength, this value is 30 Å. The increase of ionic strength results in partial deproteinization of DNP, while the cross-sectional radius of gyration varies from 25 Å for DNP in 0.7 M NaCl to 10 Å for DNP in 2 M NaCl. It is suggested that gradual deproteinization by the increase of NaCl concentration causes conformational changes, which are associated with the alteration of the DNP superstructure. The data are interpreted on the basis of the superhelical model of DNA packing in DNP; however, the coexistence of superhelical and unfolded regions in the DNP structure is also a possibility.     

Analysis of brain chromatin subunit composition using different endonucleases]

A comparison of the processes of chromatin digestion in brain and liver nuclei by Ca, Mg-dependent and staphylococcal endonucleases demonstrates a similarity of the subunit composition of chromatin from both tissues and reveals the same type of linked DNA regions. However, a formation of low molecular weight DNP fragments during hydrolysis and the DNA spectra of soluble and insoluble DNP fragments suggest that brain chromatin contains these fragments alongside with the regions, which are specific for this particular tissue, predominate in it and are resistant to staphylococcal and, particularly, to Ca, Mg-dependent endonucleases. This is paralleled with a non-histone protein enrichment of different brain chromatin fractions and an expansion of the electrophoretic monomer band towards the fragment with a greater molecular weight. It may be assumed that brain nucleosomes are characterized by a higher size heterogeneity of linked DNA, part of which are mostly covered by non-histone proteins, and/or are characterized by a greater set variety.     

Studies on deoxyribonucleoproteins. IX. Subfractions of deoxyribonucleoproteins from rat and mouse liver.

By carrier-free continuous electrophoresis, deoxyribonucleoprotein from rat and mouse liver could be separated into two subfractions. The more anodic fraction (DNP I), comprising 5 - 8 per cent of the total, contains fewer proteins (two types of histones only). [3H]Cyclophosphamide caused in vivo a 2.5 times higher alkylation of the DNA in in DNP I than of the DNA in DNP II. These and additional results led to the suggestion of a structural model with DNP I as a spacer in the deoxyribonucleoprotein fiber.     

In vivo and in vitro phosphorylation of DNA-binding proteins from Escherichia coli.

A deoxyribonucleoprotein (DNP) complex has been isolated from Escherichia coli cells by chromatography on Sephadex G-200. The DNP complex contains phosphoproteins and the content of phosphorus bound to the DNP protein is 3 times higher than in cytoplasmic proteins not bound to DNA. These results have been confirmed by in vivo (32-P-KH2PO4) and in vitro (32-P-ATP) phosphorylation of E. coli DNA-binding proteins isolated by chromatography on DNA--cellulose.     

Folding of deoxyribonucleic acid in chromatin]

A structural model for the folding of deoxyribonucleic acid (DNA) in chromatin has been evolved on the basis of the X-ray diffraction patterns of deoxyribonucleoproteids (DNP). The DNA is oriented in the direction of DNP fibres and does not exhibit a superhelical structure. In the nu-bodies the DNA is folded 7 times to and fro on the envelope of a cylinder 10 nm in diameter. The height of the DNA-hairpins is 9 nm - 10 nm. The spacing between the refolded DNA segments is 3,6 nm. This supramolecular folding crystalization of the DNA is a general principle of organization and, through different types of morphological growth of the folding crystals, leads to the chromatin, to psi-DNA, to DNA monocrystals, and to DNA packing in some phage heads.     

Fragmentation of chromatin by endogenous nucleases, accumulation of the subnucleosomal fragments with high electrophoretic mobility]

Digestion of chromatin by endogenous nucleases to nucleosomes (140-160 base pairs of DNA) is accompanied by the accumulation of subnucleosomal DNP particles with high electrophoretic mobility (20-40 base pairs of DNA). All histones associate with the 140-160 base pairs fragment. The production of subnucleosomal DNP particles does not correlate with the degradation of histone H1 and the appearance of nucleosomes lacking histone H1. Degradation of the protein in this fragment is accompanied by the appearance of free DNA. The data obtained are in agreement with the hypothesis on the origin of subnucleosomes from the nucleosomal locus preferentially associated with the non-histone proteins and on the autonomy of these loci and of the loci associated with histone H1 in the nucleosome.