Ultrastructural organization of heterochromatin within sea urchin sperm nuclei

Chromatin within swollen or lysed isolated sperm nuclei of the sea urchin, Strongylocentrotus purpuratus, was examined by electron microscopy. Spread preparations of lysed sperm nuclei demonstrated dense aggregates of nondispersed material and beaded filaments radiating from these aggregates. These beaded fibers are similar in size and appearance to the “beads-on-a-string” seen as characteristic of chromatin spreads from numerous interphase nuclei. The beads are nucleosomes that have an average diameter of 130 Å. The interconnecting string is 40 Å indiameter and corresponds to the spacer DNA. In thin sections of swollen nuclei the sperm chromatin appears to be composed of 400 Å superbeads that are closely apposed to form 400 Å fibers. As the chromatin disperses, the superbeads are seen to be attached to one another by chromatin fibers of 110 Å diameter. In thin sections, the 400 Å superbeads appear to disperse directly into the 110 Å fibers with no intervening structures. This work demonstrates that the heterochromatin in Strongylocentrotus purpuratus sperm nuclei is composed of nucleosomes that form 100 Å filaments that are compacted into 400 Å superbeads. The superbeads coalesce to give the morphological appearance of 400 Å fibers.     

Critical electrolyte concentration of the heterochromatin and euchromatin of Triatoma infestans

The binding of toluidine blue molecules under Mg2+ competitive staining conditions was investigated in chromocentres and the euchromatin of single- and multi-chromocentred nuclei of Triatoma infestans Malpighian tubule cells. It was demonstrated that the chromocentre of single-chromocentred nuclei exhibited the largest critical electrolyte concentration (CEC) value (0.4 M), followed by the chromocentres of multi-chromocentred nuclei (0.3 M) and the euchromatin (0.2 M). The differences in CEC values were assumed to be due to differences in availability of free DNA phosphates and in packing states of the DNA-protein complexes of these chromatin types. Differences in chromatin supra-organization were evident for the chromocentral heterochromatin of single vs multi-chromocentred nuclei. This was also valid for the chromocentral heterochromatin in some multi-chromocentred nuclei, when one of the heterochromatic bodies was especially larger than the others.     

X-ray microanalysis of toluidine blue stained chromosomes: a quantitative study of the metachromatic reaction of chromatin

The stoichiometry of metachromatic staining of chromatin by toluidine blue was investigated in isolated metaphase chromosomes from L929 cells using X-ray microanalysis. Microspectrophotometric measurements revealed that a hypsochromic shift (from 595 to 570 nm) occurs in toluidine blue stained chromosomes in relation to the staining solution. Under the electron microscope, stained chromosomes. After toluidine blue staining, X-ray microanalysis of chromosomes revealed a large increase for sulphur counts and a considerable increase for Fe and Cu counts, while the signal of Mg, Ca, Cl, K and Zn was reduced. After subtraction of the intrinsic sulphur signal, S/P ratios of 0.82--for euchromatic arms--and 0.85--for centromeric heterochromatin--were obtained. They are considered representative of dye/DNA phosphate ratios. These results indicate the occurrence of a nearly stoichiometric binding of toluidine blue to chromatin DNA and suggest that an external dye stacking is responsible for the metachromatic staining of metaphase chromosomes.     

Higher order structure of chromatin: influence of ionic strength and proteolytic digestion on the birefringence properties of polynucleosomal fibers

Effects of ionic strength and proteolytic digestion on the conformation of chromatin fibers were studied by electric birefringence and relaxation measurements. The results confirm that at low ionic strength chromatin presents structural features reflecting those observed in the presence of cations. Soluble chromatin prepared from rat liver nuclei by brief nuclease digestion exhibits a positive birefringence. As the salt concentration is increased, the transition to a compact solenoidal structure is deduced from changes in electro-optical properties: the positive birefringence gradually decreases and the observed reduction in 40 mM NaCl is nearly 95%; the relaxation time decreases dramatically and the character of the kinetic changes since the decay of birefringence described initially by a spectrum of relaxation times becomes monoexponential. On digestion with proteases at low ionic strength we observe at first a rapid increase of the positive birefringence concomitant with an increase of the relaxation time. Then the birefringence decreases and becomes negative. Chromatin undergoes two successive transitions: the first transition is explained by a lengthening of nucleosomal chains without modification of the orientation of nucleosomes within the superstructure and the second one by the unwinding of the DNA tails and internucleosomal segments. When chromatin is digested at 30 mM NaCl we find a single unfolding transition characterized by the decrease of birefringence and a slight increase in the relaxation time. The results imply that the positive birefringence of chromatin does not depend on the presence of whole histone H1 and that a salt concentration of 30 mM NaCl is sufficient to modify the initial site or/and the effects of proteolytic attack.     

Higher Order Structure of Chromatin: Influence of Ionic Strength and Proteolytic Digestion on the Birefringence Properties of Polynucleosomal Fibers

Abstract

Effects of ionic strength and proteolytic digestion on the conformation of chromatin fibers were studied by electric birefringence and relaxation measurements. The results confirm that at low ionic strength chromatin presents structural features reflecting those observed in the presence of cations. Soluble chromatin prepared from rat liver nuclei by brief nuclease digestion exhibits a positive birefringence. As the salt concentration is increased, the transition to a compact solenoidal structure is deduced from changes in electro-optical properties: the positive birefringence gradually decreases and the observed reduction in 40 mM NaCl is nearly 95%; the relaxation time decreases dramatically and the character of the kinetic changes since the decay of birefringence described initially by a spectrum of relaxation times becomes monoexponential.

On digestion with proteases at low ionic strength we observe at first a rapid increase of the positive birefringence concomitant with an increase of the relaxation time. Then the birefringence decreases and becomes negative. Chromatin undergoes two successive transitions: the first transition is explained by a lengthening of nucleosomal chains without modification of the orientation of nucleosomes within the superstructure and the second one by the unwinding of the DNA tails and internucleosomal segments.

When chromatin is digested at 30 mM NaCl we find a single unfolding transition characterized by the decrease of birefringence and a slight increase in the relaxation time. The results imply that the positive birefringence of chromatin does not depend on the presence of whole histone HI and that a salt concentration of 30 mM NaCl is sufficient to modify the initial site or/and the effects of proteolytic attack.     

Small angle scattering of cell nuclei

Neutron and X-ray small angle scattering techniques have been applied to study chromatin structure inside different types of cell nuclei. Scattering from genetically inactive chicken erythrocyte nuclei exhibits a maximum at Q = 0.1-0.15 nm-1 which cannot be observed by studying isolated chromatin derived from the same kind of cells. In highly active transcribing rat liver nuclei such a nuclear pattern is absent. The radius of gyration of isolated "superbeads" was determined. It is discussed whether the characteristic maximum of the nuclei originates from this superstructural organisation of chromatin. Rat liver nuclei were fractionated on sucrose gradients in order to determine whether the absence of the extra maximum in scattering profiles of these nuclei is due to overlapping effects of different chromatin organisation in the various cell types of the liver. As compared to unfractionated nuclei no strong deviations in the scattering profiles of the fractions could be observed. Erythrocyte nuclei were dialysed in buffers differing in the ionic strength of monovalent cations. The typical maximum from the nuclei is shifted from 60 nm (very low salt concentration) to about 35 nm (physiological ionic strength) and is linearly proportional to the decreasing radius of the nuclei. In conclusion, chromatin structure inside the nucleus has a scattering maximum due to an ordered packing of the fibres which is absent in nuclei with high genetic activity.     

X-ray microanalysis of toluidine blue stained chromosomes: a quantitative study of the metachromatic reaction of chromatin

Summary The stoichiometry of metachromatic staining of chromatin by toluidine blue was investigated in isolated metaphase chromosomes from L929 cells using X-ray microanalysis. Microspectrophotometric measurements revealed that a hypsochromic shift (from 595 to 570 nm) occurs in toluidine blue stained chromosomes in relation to the staining solution. Under the electron microscope, stained chromosomes showed higher electron density than control chromosomes. After toluidine blue staining, X-ray microanalysis of chromosomes revealed a large increase for sulphur counts and a considerable increase for Fe and Cu counts, while the signal of Mg, Ca, Cl, K and Zn was reduced. After subtraction of the intrinsic sulphur signal, S/P ratios of 0.82 — for euchromatic arms — and 0.85 — for centromeric heterochromatin — were obtained. They are considered representative of dye/DNA phosphate ratios. These results indicate the occurrence of a nearly stoichiometric binding of toluidine blue to chromatin DNA and suggest that an external dye stacking is responsible for the metachromatic staining of metaphase chromosomes.     

爪蟾卵无细胞系统中核的自组装和组装核染色质纤维的研究

以人工促排的非洲爪蟾卵为材料制备体外无细胞系统,加入Lambda DNA或染色质,用荧光显微镜和电子显微镜观察核的自组装现象.在核的自组装过程中可以看出由丝状、不规则块状到小球状的形态变化,直至形成与真核细胞间期核的形态、结构相似的组装核.在加入染色质时,所观察到的现象和加入Lambda DNA时相似,但形成组装核的过程较快.组装核经过适当浓缩后,以低渗铺展法使其破裂,从核中释放的染色质纤维,电镜观察与细胞核内的染色质有相似之处也有其本身的特点.用蛋白酶处理,纤维变得光滑,其上的颗粒消失;DNase的作用则可使纤维消失,只剩下一些颗粒和片段;RNase处理时没见变化.     

Dynamic inorganic ion-protein interactions in structural organization of DNA of living cell nuclei.

Staining polarization optical techniques showed differences in the structural organization of DNA of chromatin in interphase nuclei and in mitotic chromosomes. The DNA was non-birefringent in intact interphase cell nuclei, but birefringent in chromosomes and in isolated nuclei incubated in a physiological electrolyte solution. The birefringence of DNA appears to be related to an unfolding of DNA filaments induced by free cations and to the oriented binding of dye molecules to DNA phosphates. We propose that the actual concentration of free cations inside the living cell nuclei is regulated by a dynamic interaction between nuclear proteins and ions.     

On the de novo formation of compact oligonucleosomes at high ionic strength. Evidence for nucleosomal sliding in high salt.

Histone H 1-depleted chromatin made from acid extracted, intact nuclei was exposed to various ionic strengths. NaCl concentrations above 0.3 M sufficed to generate novel oligonucleosomes formerly characterized as "compact oligomers" and "spacerless dinucleosomes". Such particles could not be identified within H 1-depleted nuclei or chromatin at low ionic strengths. Their formation, proceeding within days at 0 degrees C, was accelerated by increasing ionic strengths. The data was discussed in terms of a salt-induced motion of nucleosomal core particles along the DNA to form compact oligomers.     

Chromatin supraorganization and extensibility in mouse hepatocytes with development and aging.

BACKGROUND: Chromatin supraorganization and extensibility, which lead to the formation of extended chromatin fibers (ECF), are affected by starvation and refeeding in adult mouse hepatocytes. It is expected that they could also change with mouse development and aging. METHODS: Methods used involved topochemistry, image analysis, microspectrophotometry, gravity action, and polarization microscopy. RESULTS: Increased nuclear areas and Feulgen-DNA amounts with advancing hepatocyte polyploidy were found with development and aging. A slightly less packed chromatin with more heterogeneously distributed condensation levels was detected in young and old mice. Con-A responsiveness was almost absent in young mice but very deep in aged mice. ECFs formed from nuclei of adult and aged mice but not from nuclei of young mice. The frequency of ECF formation with the long lysis protocol increased with aging. CONCLUSIONS: In young mice, a less packed chromatin state may be associated with more intense gene activity, thus increasing the DNA-nuclear matrix interactions, and inhibiting ECF formation. Reduced DNA-nuclear matrix interactions besides defects in heterochromatin formation may induce higher ECF formation and chromatin unpackaging in old mice. We suggest that differences in Con-A staining relate to different gene activity with advancing development and aging.     

Parameters influencing the flow cytometric analysis of DNA sensitivity to nuclease S1

Some parameters that influence the analysis in situ of DNA sensitivity to digestion with nuclease S1 have been studied in isolated HeLa nuclei with flow cytometry. DNA staining with the intercalating fluorochrome propidium iodide allowed the nucleolytic activity on double-stranded (ds) DNA to be determined by monitoring the relative reduction in nuclear fluorescence intensity. Nuclei isolated in buffer at low ionic strength in order to decondense chromatin fibres, showed a lower fluorescence intensity than nuclei with native chromatin, after digestion with nuclease S1 under identical conditions. Nuclei prepared with dispersed chromatin and digested with increasing amounts of enzyme showed a decrease in fluorescence intensity that reached a limit value at about 50% of the value of undigested control samples. On the other hand, in nuclei with native chromatin, fluorescence intensity decreased only about 18%. The NaCl concentration in the reaction buffer strongly influenced the DNA sensitivity to S1 nuclease. By increasing salt molarity from 5 mM to 200 mM, the digestion of dsDNA was significantly reduced as also shown by the amount of released nucleotides from purified calf thymus DNA. The detection of DNA sensitivity to nuclease S1, as assessed by the cytometric method, was shown to be more sensitive than a biochemical technique involving hydrolysis of purines. These results indicate that both the procedure for nuclei isolation and the digestion conditions have to be carefully controlled when evaluating in situ the presence of S1-sensitive sites.     

Superstructures of wet inactive chromatin and the chromosome surface

Superpacking of chromatin and the surface features of metaphase chromosomes have been studied by SiO replication of wet, unstained, and unfixed specimens in an exceedingly thin (≤ 1 nm) aqueous layer, keeping them wet. Hydrophilic Formvar substrates allow controlled thinning of the aqueous layer covering the wet specimens. Whole mounts of chromatin and chromosomes were prepared by applying a microsurface spreading method to swollen nuclei and mitotic cells at metaphase. The highest level of nucleosome folding of the inactive chromatin in chicken erythrocytes and rat liver nuclei is basically a second-order superhelical organization (width 150–200 nm, pitch distance 50–150 nm) of the elementary nucleosome filament. In unfavorable environments (as determined by ionic agents, fixative, and dehydrating agents) this superstructure collapses into chains of superbeads and beads. Formalin (10%) apparently attacks at discrete sites of chromatin, which are then separated into superbeads. The latter consist of 4–6 nucleosomes and seemingly correspond to successive turns of an original solenoidal coil (width 30–35 nm), which forms the superhelical organization. When this organization is unfolded, eg, in 1–2 mM EDTA, DNAse-sensitive filaments (diameter 1.7 nm) are seen to be wrapped around the nucleosomes. The wet chromosomes in each metaphase spread are held to each other by smooth microtubular fibers, 20–30 nm in diameter. Before they enter into a chromsome, these fibers branch into 9–13 protofilaments, each 5 nm wide. The chromosome surface contains a dense distribution of subunits about 10–25 nm in diameter. This size distribution corresponds to that of nucleosomes and their superbeads. Distinct from this beaded chromosome surface are several smooth, 23–30-nm-diameter fibers, which are longitudinal at the centromere and seem to continue into the chromatid structure. The surface replicas of dried chromosomes do not show these features, which are revealed only in wet chromosomes.     

Daunomycin-induced unfolding and aggregation of chromatin.

Using equilibrium dialysis and sedimentation velocity analysis, we have characterized the binding of the anti-tumor drug daunomycin to chicken erythrocyte chromatin before and after depletion of linker histones and to its constitutive DNA under several ionic strengths (5, 25, and 75 mM NaCl). The equilibrium dialysis experiments reveal that the drug binds cooperatively to both the chromatin fractions and to the DNA counterpart within the range of ionic strength used in this study. A significant decrease in the binding affinity was observed at 75 mM NaCl. At any given salt concentration, daunomycin exhibits higher binding affinity for DNA than for linker histone-depleted chromatin or chromatin (in decreasing order). Binding of daunomycin to DNA does not significantly affect the sedimentation coefficient of the molecule. This is in contrast to binding to chromatin and to its linker histone-depleted counterpart. In these instances, preferential binding of the drug to the linker DNA regions induces an unfolding of the chromatin fiber that is followed by aggregation, presumably because of histone-DNA interfiber interactions.     

Repeating oligonucleosomal units. A new element of chromatin structure.

Supranucleosomal chromatin structure has been analysed by the use of histone H1 polymers crosslinked in nuclei and extended chromatin with bifunctional reagents methyl-4-mercaptobutyrimidate (MMB) and dimethyl suberimidate dihydrochloride. Almost pure H1 homopolymers were obtained in milligram amounts and examined for the distribution in molecular weights. The H1 homopolymer molecules both from nuclei and chromatin have been found to be integer multiples of an elementary structure (called "clisone") consisting of 12 histone H1 molecules. This finding strongly suggests that nucleosomal chains of chromatin are not uniform but rather organized as repeating oligonucleosomal units each consisting of 12 nucleosomes. Correlation between oligonucleosomal structures in nuclei and chromatin implies that a linearized nucleosomal chain retains the information on chromatin superstructure. The relation of the disclosed 12-nucleosome units to superbeads (nucleomeres) and other structures is discussed.     

Parameters influencing the flow cytometric analysis of DNA sensitivity to nuclease S1

Summary Some parameters that influence the analysis in situ of DNA sensitivity to digestion with nuclease S1 have been studied in isolated HeLa nuclei with flow cytometry. DNA staining with the intercalating fluorochrome propidium iodide allowed the nucleolytic activity on double-stranded (ds) DNA to be determined by monitoring the relative reduction in nuclear fluorescence intensity. Nuclei isolated in buffer at low ionic strength in order to decondense chromatin fibres, showed a lower fluorescence intensity than nuclei with native chromatin, after digestion with nuclease S1 under identical conditions. Nuclei prepared with dispersed chromatin and digested with increasing amounts of enzyme showed a decrease in fluorescence intensity that reached a limit value at about 50% of the value of undigested control samples. On the other hand, in nuclei with native chromatin, fluorescence intensity decreased only about 18%. The NaCl concentration in the reaction buffer strongly influenced the DNA sensitivity to S1 nuclease. By increasing salt molarity from 5 mM to 200 mM, the digestion of dsDNA was significantly reduced as also shown by the amount of released nucleotides from purified calf thymus DNA. The detection of DNA sensitivity to nuclease S1, as assessed by the cytometric method, was shown to be more sensitive than a biochemical technique involving hydrolysis of purines. These results indicate that both the procedure for nuclei isolation and the digestion conditions have to be carefully controlled when evaluating in situ the presence of S1-sensitive sites.     

Nucleosome packing in interphase chromatin.

Higher-order chromatin fibers (200--300 A in diameter) are reproducibly released from nuclei after lysis in the absence of formalin and/or detergent. Electron microscope analysis of these fibers shows that they are composed of a continuous array of closely apposed nucleosomes which display several distinct packing patterns. Analysis of the organization of nucleosomes within these arrays and their distribution along long stretches of chromatin suggest that the basic 100-A chromatin fiber is not packed into discrete superbeads and is not folded into a uniform solenoid within the native 250-A fiber. Furthermore, because similar higher-order fibers have been visualized in metaphase chromosomes, the existence of this fiber class appears to be independent of the degree of in vivo chromatin condensation.     

Assembly of oligonucleosomes into a limit series of multimeric higher-order chromatin structures

Chicken erythrocyte chromatin, obtained after fragmentation with micrococcal nuclease, appears to remain folded in a stable distribution of supranucleosomal structures in buffers containing 80 mM NaCl. These supranucleosomal particles are composed of on average 25 nucleosomes. However, the integrity of the linker DNA within these particles is not required. The supranucleosomal particles have been interpreted by others as superbeads cut out of a preexisting granular nominal 30-nm chromatin fibre. We show that the same distribution of supranucleosomal structures (even those containing internal DNA scissions) can be reconstituted from unfolded nuclear chromatin extracts as present in 10 mM or 600 mM NaCl. Moreover, fractions of oligonucleosomes with mean lengths between 6 and 15 nucleosomes reassemble or aggregate into a limit series of multimeric species. The existence of an assembly barrier could be inferred as we were unable to observe a stable and soluble assembly product containing more than about 25 nucleosomes. We propose an alternative explanation for the generation and observation of a constant distribution of supranucleosomal structures in nuclear extracts, based on the assembly or aggregation property of oligonucleosomes and on the existence of an assembly barrier.     

DNA-protein binding in interphase chromosomes

The metachromatic dye, azure B, was analyzed by microspectrophotometry when bound to DNA fibers and DNA in nuclei with condensed and dispersed chromatin. The interaction of DNA and protein was inferred from the amount of metachromasy (increased β/α-peak) of azure B that resulted after specific removal of various protein fractions. Dye bound to DNA-histone fibers and frog liver nuclei fixed by freeze-methanol substitution shows orthochromatic, blue-green staining under specific staining conditions, while metachromasy (blue or purple color) results from staining DNA fibers without histone or tissue nuclei after protein removal. The dispersed chromatin of hepatocytes was compared to the condensed chromatin of erythrocytes to see whether there were differences in DNA-protein binding in "active" and "inactive" nuclei. Extraction of histones with 0.02 N HCl, acidified alcohol, perchloric acid, and trypsin digestion all resulted in increased dye binding. The amount of metachromasy varied, however; removal of "lysine-rich" histone (extractable with 0.02 N HCl) caused a blue color, and a purplish-red color (µ-peak absorption) resulted from prolonged trypsin digestion. In all cases, the condensed and the dispersed chromatin behaved in the same way, indicating the similarity of protein bound to DNA in condensed and dispersed chromatin. The results appear to indicate that "lysine-rich" histone is bound to adjacent anionic sites of a DNA molecule and that nonhistone protein is located between adjacent DNA molecules in both condensed and dispersed chromatin.