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.     

Molecular hybridization of ribonucleic acid with a large excess of deoxyribonucleic acid

When RNA is annealed in solution with a sufficiently large excess of DNA, the kinetics of DNA-RNA hybridization are relatively simple. Methods are described for following the course of both DNA renaturation and DNA-RNA hybridization in this system. To explore the characteristics of the reaction a series of model systems was used. Each one utilized DNA (sheared to constant size) from a bacterium or bacteriophage and homologous cRNA, i.e. RNA synthesized in vitro on a template of the same DNA. Temperature optima were determined for the hybridization of Escherichia coli nucleic acids in 2xSSC and 3xSSC-50% formamide buffers, and of Proteus mirabilis nucleic acids in 2xSSC buffer. Rate-constants for DNA-RNA hybridization were measured by two methods. These gave somewhat different results, but in all cases the rate-constant of DNA-RNA hybridization was clearly less than that of DNA renaturation. Thus hybridization is a slower reaction than DNA renaturation. Nevertheless, in some cases, with a high concentration of DNA and a long annealing time, 90-95% of the added RNA became resistant to ribonuclease. Experiments are described which show that it is possible to deduce the analytical complexity of DNA with reasonable accuracy from its hybridization with complementary RNA. Similarly, it is possible to estimate the reiteration frequency of multiple DNA sequences (such as ribosomal DNA) from the hybridization of the total DNA with RNA complementary to the multiple sequences. The effect on the system of various DNA/RNA ratios from 100 to 1 is described.     

Evidence for the formation of nucleosome-like histone complexes on single-stranded DNA.

Using histones reconstituted with RNA and DNA celluloses, we have shown elsewhere that histones elute identically with salt from single- and double-stranded DNA, but differently from RNA (Palter and Alberts, 1979). In this paper we characterize further the suspected specific binding interactions between histones and single-stranded DNA. Nuclease digestion of complexes of histone reconstituted with single-stranded DNA generates only a small yield of discrete (approximately 9S) particles. We can, however, efficiently obtain such 9S "nucleosome-like" complexes when nuclease treatment is avoided and histones are reconstituted directly with short single-stranded DNA pieces. Strikingly, these 9S subunits contain an equimolar composition of the four nucleosomal histones. When these subunits are visualized in the electron microscope, they appear as globular particles which are morphologically indistinguishable from normal mononucleosomes. Based on their sedimentation properties, histone-to-DNA ratio, histone composition and particle diameter, we conclude that they represent an octamer of the four histones (containing two molecules of each histone) associated with single-stranded DNA. These data, viewed in the context of other information concerning chromatin, suggest that nucleosome cores may become transiently bound to single strands of DNA as DNA and RNA polymerases pass.     

Sea urchin sperm DNP. I. Chemical composition and template properties of DNP

Electrophoretic mobility, amino acid composition and salt dissociation of histones isolated from sperm of sea urchin Strongylocentrotus intermedius and calf thymus cells were studied. The special arginine-rich histone fraction (I) has been observed in sea urchin sperm chromatin, this fraction being absent in calf thymus chromatin. Dissociation of lysine-containing histone fractions from sea urchin chromatin occured in the range of 0.7 to 1.0 M NaCl concentrations. H1 of calf thymus chromatin was totally extracted with 0.6 M NaCl. In the course of a further increase of salt concentrations (up to 1.5 M NaCl) a practically total extraction of histones from sperm chromatin was observed, while about 20% of proteins remained bound to DNA in thymus chromatin after extraction with 2.0 M NaCl. The template activity of non-extracted DNP preparations from urchin sperm was equal to 2-3% of that of totally deproteinized DNA. The template activity of DNP gradually increased at protein extraction from DNP preparations. The hybridization capacity of RNA transcribed on partially dehistonized DNP templates in vitro also increased.     

Activity banding of human chromosomes as shown by histone acetylation

The expression of genes in mammalian cells depends on many factors including position in the cell cycle, stage of differentiation, age, and environmental influences. As different groups of genes are expressed, their packaging within chromatin changes and may be detected at the chromsomal level. The organization of DNA within a chromosome is determined to a large extent by the positively charged, highly conserved histones. Histone subtypes and the reversible chemical modifications of histones have been associated with gene activity. Active or potentially active genes have been associated with hyperacetylated histones and inactive genes with nonacetylated histones. Sodium butyrate increases the acetylation levels of histones in cell cultures and acts as both an inducer of gene activity and as a cell-cycle block. We describe a method to label the interphase distribution of DNA associated with various histone acetylation stages on chromosomes. Nucleosomes from untreated and butyrate-treated HeLa cells were fractionated by their acetylation level and the associated DNA labeled, and hybridized to normal human chromosomes. In the sodium butyrate-treated cells the resulting banding patterns of the high- and low-acetylated fractions were strikingly different. DNA from low-acetylated chromatin labeled several pericentric regions, whereas hybridization with DNA from highly acetylated chromatin resulted in a pattern similar to inverse G-bands on many chromsomes. The results from noninduced cells at both high and low acetylation levels were noticeably different from their induced counterparts. The capture and hybridization of DNA from interphase chromatin at different acetylation states provides a “snap-shot” of the distribution of gene activity on chromosomes at the time of cell harvest. Edited by: P.B. Moens     

Structural changes in chromatin of heat shock protein 70 gene of Drosophila during transcription

Using "protein-image" hybridization technique combined with various crosslinking methods, for formaldehyde-prefixed nuclei we have analysed changes induced by activation in the chromatin structure of HSP-70 genes. From the crosslinking data it follows that chromatin of actively transcribed genes undergoes some structural rearrangements resulting in certain weakening of the contacts between DNA and the globular parts of histones so that the histones remain bound to DNA through their N-terminal regions. In addition, there have been found two specific regions with a reduced content of histones: the 5'-promoter of HSP-70 gene and a region distanced by approximately 1 k.b. from the 3'-end of the HSP-70 gene.     

Denaturation, renaturation, and loss of DNA during in situ hybridization procedures

With the aim of optimizing in situ hybridization methods, alkaline, acid, and thermal denaturation procedures have been studied for their ability to separate the DNA strands of nuclear DNA and for the DNA losses they induce. Isolated methanol/acetic acid-fixed mouse liver nuclei have been used as a biological object. The results, obtained with acridine orange staining and microfluorometry, show that all denaturations studied lead to almost complete strand separation. Quantitative DNA staining and cytometry indicated that with heat and alkaline denaturation about 40% of the DNA is lost. Acid denaturation led to about 20% DNA loss. For the alkaline denaturation, the DNA retention could be improved to a 20% DNA loss by adding 70% ethanol to the denaturation medium. During hybridization, another 20% DNA loss occurs. When denatured nuclei are brought under annealing conditions, a rapid renaturation of a considerable fraction of the remaining DNA occurs. The extent of renaturation was dependent on the type of denaturation used. For the ethanolic alkaline denaturation, it was estimated to be 35%. Quantitative nonautoradiographic in situ hybridization experiments with acetylaminofluorene-modified mouse satellite DNA showed that alkaline denaturation procedures are superior to the heat and acid denaturation. As proven by acridine orange fluorescence measurements, hybridization conditions can be designed that permit DNA.RNA hybridization under in situ DNA.DNA denaturing conditions. These conditions should be very useful, especially for in situ hybridization with single-stranded RNA probes.     

Molecular hybridization between rat liver deoxyribonucleic acid and complementary ribonucleic acid

RNA (cRNA) was synthesized in vitro on a template of rat liver DNA and its hybridization with rat liver DNA was studied by using the nitrocellulose-filter method. Sonication of the DNA diminished its apparent capacity to hybridize with RNA by about 50%. This is not due to cross-linkage of DNA molecules, because it could be shown that less than 2% of the sonicated DNA was cross-linked. The effect is due instead to the small size of the sonicated DNA molecules. Below a single-stranded molecular weight of 5×10⁵ the DNA showed a progressive loss of capacity to hybridize with decrease in molecular weight. Evidence is presented suggesting that the apparently diminished capacity of the DNA to hybridize is due to loss of hybridized DNA from the membrane filters. When cRNA at concentrations of up to 25μg/ml is annealed with sonicated total DNA, an apparent hybridization saturation value is found at which about 2.5% of the DNA is hybridized with RNA. Increasing the cRNA concentration tenfold brought about the hybridization of a second component of the DNA approximately equal in amount to the first. The renaturation of rat liver DNA was studied by measuring the fall in the extinction at 260nm and two different components of renaturation were observed within the reiterated fraction of DNA. By hybridizing cRNA with different fractions of rat DNA the two components of the hybridization curve are shown to correspond to the two components of the renaturation curve. The conclusion is drawn that at a cRNA concentration of 250μg/ml most of the reiterated fraction of rat liver DNA is hybridized after annealing for 16h under standard conditions (0.30m-sodium chloride–30mm-sodium citrate at 65°C). Even with such a high cRNA concentration little or no hybridization of the slowly renaturing DNA fraction occurs. It is suggested that the most highly reiterated DNA component is poorly transcribed in vitro.     

Chromatin fractionation according to the strength of its matrix bond

Extraction in low salt concentration followed by centrifugation allows rat liver nuclear chromatin to be divided into two fractions: the supernatant chromatin and matrix chromatin. The former fraction contains about 60-70% of initial DNA and about 15% of initial protein along with all five histones, and an insignificant amount of non-histone proteins. RNA synthesis in the matrix chromatin fraction is 2-3 times more intense than that in the original nuclei. The data on gradient centrifugation do not suggest the elongation of RNA molecules synthesized in the matrix fraction. The results obtained as compared with the literature data suggest that the matrix chromatin fraction is enriched with active genes.