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.     

Reaction between tetranitromethane and deoxyribonucleoproteins]

A comparative kinetic study has been made of tetranitromethane nitration of tyrosine residues in deoxyribonucleoprotein preparation (DNP) treated with EDTA and/or UV light at lambda=253.7 nm, as well as obtained by enzymatic digestion of nucleosomes. UV-light-induced protein-DNA linkages stabilize the structure of the preparation, whereas the action of chelate agents causes DNP-200 angstrom leads to DNP-100 angstrom transfer. Comparison of kinetic data and the results of the amino acid analysis of individual fractions of nitrated histones allowed to conclude that the differences observed between the degree and the rate of nitration are due to internucleosomic interactions which form the supernucleosomic structure of DNP.     

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.     

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.     

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.     

Aggregation of fragmented chromatin associated with the synthesis of products of its treatment with nuclease

Isolated cell nuclei were incubated with nucleases followed by extraction of chromatin with a low salt buffer. With an increase of nuclear chromatin degradation with DNAse I or micrococcal nuclease, solubilization of deoxyribonucleoprotein (DNP) by a low salt buffer increases, reaching a maximum upon hydrolysis with 2-4% nuclear DNA and then decreases appreciably after extensive treatment with nucleases. Soluble fragmented chromatin aggregates in the course of treatment with DNAase. I. Addition to gel chromatin preparations of exogenous products of nuclease treatment of isolated nuclei leads to its aggregation. Pretreatment of nuclear chromatin with RNAase prevents solubilization of DNP by low ionic strength solutions. Some experimental data obtained with the use of severe nuclease treatment are discussed; for a correct interpretation of these data the aggregation of fragmented chromatin by products of its nuclease degradation should be taken into consideration.     

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.     

Probing the structure of bacterial deoxyribonucleoproteins with exogenous and endogenous nucleases

During digestion of deoxyribonucleoproteins (DNP) of gram-negative bacteria by micrococcal nuclease and Ca2+, Mg2+-dependent endonuclease in situ regular series fragments-and large nuclease-resistent fragments of DNP were revealed by electrophoresis. The DNP length of the smallest DNP-fragment was tentatively 120-140 base pairs. In investigated bacterial species DNP contained at least two basic proteins which had electrophoretic mobility similar to that of histone H4 of eucaryot. It is suggested that bacterial DNPs have common regular structure.     

Rheiological behaviour of deoxyribonucleoprotein systems of chromatin. I. DNP in high ionic strength solutions (0.7 M NaCl)]

The rheological behaviour of deoxyribonucleoprotein (DNP) in high ionic strength solutions (0,7 M NaCl) is indicative of the presence, in these systems, of linearly ordered DNP microstructures, which are reversibly destroyed by mechanical influences. The examination of the models of spatial network which are capable of providing the limit of fluidity for low concentrated DNP solutions permits to abandon the model of bound tracery network. The existence of interrupted network is proposed which is formed by fixation of microstructures in the secondary potential minimum without direct contact. It is concluded that DNP is able to organize liquid-cristalline structures with linear orientation of the axes of microstructural elements. The possibility of superhelical organization of such microstructures is not excluded. The long-range surface forces take part in stabilization of DNP-microstructures.     

Nature of RNA synthesis on embikhin-damaged templates

Embichin, a bifunctional alkylating mutagenic agent, inhibits RNA-synthesizing capacity of DNA and chromatin. The template capacity for decreasing the embichin-injured chromatin is caused by substantial reduction in the number of RNA molecules synthesized by this template. When DNA extracted from embichin-injured chromatin is used as a template, its template restriction is accounted for by an approximately 5-fold decrease in the RNA average molecular weight. The deoxyribonucleoprotein complexes reconstituted from embichin-injured DNA and control chromatic proteins had a lower template capacity compared with that of DNP reconstituted from control DNA. It is concluded that both links between DNA and proteins and DNA injuries are responsible for the inhibition of genome template capacity.     

Study of calf thymus deoxyribonucleoproteins by means of gel electrophoresis,effect of ionic composition on the mode of chromatin fragmentation

Calf thymus soluble deoxyribonucleoproteins (DNP) obtained by sonication of chromatins isolated both in a “physiological” salt medium and in a buffered water were resolved into four fractions on electrophoresis. The DNA extracted from DNP obtained in a salt medium occurs in fragments of discrete sizes while the sonicated chromatin gel obtained in a buffered water gives rise to a heterogeneous population of DNA fragments upon deproteinization. It is suggested that regularly spaced “weak” points exist in native chromatin and that the regularity is destroyed during isolation procedures involving the transfer of the nuclei into water.     

Linker histone-DNA complexes: enhanced stability in the presence of aluminum lactate and implications for Alzheimer's disease

The binding of human brain linker histone proteins to a radiolabelled human Alu repetitive element was examined by mobility shift assay. Analysis of the complexes formed from protein extracts of whole neocortical nuclei, under physiological conditions in vitro revealed that linker histone H1(0) has the highest affinity for the Alu DNA sequence. The linker histone-DNA complexes assembled in the presence of aluminum lactate were more resistant to sodium chloride-induced dissociation than those formed in the presence of sodium lactate. The enhanced stability of deoxyribonucleoprotein (DNP) complexes in the presence of the aluminum cation may be of significance in neurodegenerative conditions such as Alzheimer's disease where aluminum preferentially associates with DNA containing structures of the nucleus.     

Characteristics of sulfhydryl groups of histone H3 from the calf thymus using mercury-containing nitroxyl radicals

The interaction between total histone and deoxyribonucleoprotein (DNP) preparations from calf thymus with mercury-containing nitroxyl radicals in low ionic strength solutions, 2 M NaCl and urea was investigated. It was found that the label is rapidly incorporated into the SH-groups of histone H3 to produce characteristic EPR signals. Titration of SH-groups within DNP demonstrated that in low ionic strength solutions only one SH-group (presumably, the SH-group of the cysteine residue in position 110) is accessible to the reagents. After dissociation by 2 M NaCl, two SH-groups become titrable; however, the EPR spectra point to differences in the conformational state of these two groups. In 4 M urea, these differences are compensated for by structural disintegration. The spin labels may be used for the analysis of SH-groups under different conditions and at different functional states of nucleoproteins.     

Structure and histone composition of chromatin in Physarum polycephalum]

In Physarum polycephalum several degrees of organisation of deoxyribonucleoprotein fibres were found. The complexes of histones and the DNA duplex seem to "be packed" at first into a 100 A fibre and then into a 200 A fibre of DNP. In Ph. polycephalum the electrophoretic mobilities of histone fractions 4 and 6 are comparable to that of fractions f3/f2b and f2a1 of calf thymus, resp. Histone fractions 3 and 5 move a bit faster than fractions f1 and f2a2, resp. Thus, the myxomycete P. polycephalum is similar to higher eukaryotes as concerns the ultrastructure of chromatin and electrophoretic properties of histones.     

Proteins of Caulobacter crescentus strongly binding to DNA. Spectroscopic analysis of major histone-like proteins.

The protein composition of deoxyribonucleoprotein (DNP) from Caulobacter crescentus, protected from exogenous nucleases, was analysed. This fraction was obtained by purification of cell lysate on Sephacryl S-400. It contained the following proteins: 13.4 kDa (HCc), 15.2 kDa, 17.5 kDa, 28 kDa and 40 kDa. The strength of protein 15.2 kDa binding to ds-DNA was the same as that of the eukaryotic histones H2A and H2B. Proteins 13.4 kDa (HCc) and 17.5 kDa purified to homogeneity have a UV spectrum identical to protein HU of Escherichia coli which lacks tryptophane and tyrosine. This confirms the classification of protein HCc to the class of HU-like proteins.     

Antigen-induced changes in lymphoid cell histones. IV. Changes in solubility of isolated chromatin

In this study we have examined the solubility of deoxyribonucleoprotein (DNP) isolated from control and antigen-affected thymocytes. 2-M sodium chloride extracts containing the DNP of rat thymus glands were serially diluted. A comparison was made of the effect of dilution on fiber formation in the control and test series. Fiber formation is usually complete for the control material at a salt concentration between 0.63 and 0.57 M. The test material shows some fiber formation within this range. However, a significant portion of the DNP is precipitated at dilutions of 0.54–0.48 M. Ammoniacal silver (A-S) stains the control fibers a characteristic yellowish color. With the test material, those fibers formed within the control range tended to be stained yellowish brown by A-S, whereas those formed only after greater dilution stained blackish. These data, coupled with our previous observations on altered A-S staining, clearly demonstrate an antigen-induced physical and/or chemical alteration of the histone or histone-DNA complex of lymphoid cell chromatin.     

Studies on Nuclei of Paramecium aurelia. II. Amino Acid Composition and Electrophoretic Properties of the Chromosomal Basic Proteins*

SYNOPSIS. The basic proteins of Paramecium aurelia nucleus were extracted from isolated nuclei and deoxyribonucleoprotein (DNP) of such nuclei. About 35–40% of the nuclear protein, predominantly a lysine-rich histone, is acid soluble. Five major components of the histone can be distinguished by polyacrylamide gel electrophoresis. Some components of Paramecium histone are similar to those of mammalian histones in their electrophoretic mobility, but they differ from the latter in the electrophoretic velocity and relative levels. The basic to acidic amino acid ratio of the histone from the ciliate is ～1.1–1.5, and its amino acid composition resembles closely that of yeast histone. Through the use of Sephadex G-200 gel filtration for purification of the histones extracted directly from isolated nuclei 2 basic proteins were resolved—component I, with an elution volume of 1.4, constitutes ～20% and component II, with an elution volume of 1.9, ～80%.