Protein-DNA crosslinking in reconstituted nucleohistone, nuclei and whole cells by picosecond UV laser irradiation.

A picosecond UV laser was used to cross-link proteins to DNA in nuclei, whole cells and reconstituted nucleohistone. Irradiation of the nucleohistone resulted in crosslinking 15-20% of bound histones to DNA in a very short time (one or several picosecond pulses), the efficiency of crosslinking to single stranded DNA being higher than to double stranded DNA. All histones as well as high mobility group 1 proteins were identified in the covalently linked protein-DNA complexes upon irradiation of isolated nuclei and whole cells. A method is suggested for isolation of crosslinked material from cells and nuclei in amounts sufficient for further analysis. Experiments with reconstituted nucleohistones showed that upon irradiation at a constant dose the efficiency of crosslinking depended on the intensity of the light, thus suggesting a two-quantum process is involved in the reaction.     

Laser-induced crosslinking of histones to DNA in chromatin and core particles: implications in studying histone-DNA interactions.

UV laser irradiation has been used to covalently crosslink histones to DNA in nuclei, chromatin and core particles and the presence of the different histone species in the covalently linked material was detected immunochemically. When nuclei were irradiated and then trypsinized to cleave the N- and C- terminal histone tails, no histones have been found covalently linked to DNA. This finding shows that UV laser-induced crosslinking of histones to DNA is accomplished via the non-structured domains only. This unexpected way of crosslinking operated in chromatin, H1-depleted chromatin and core particles, i.e. independently of the chromatin structure. The efficiency of crosslinking, however, showed such a dependence: whilst the yield of crosslinks was similar in total and H1-depleted chromatin, in core particles the efficiency was 3-4 times lower for H2A, H2B and H4 and 10-12 times lower for H3. The decreased crosslinking efficiency, especially dramatic in the case of H3, is attributed to a reduced number of binding sites, and, respectively, is considered as a direct evidence for interaction of nonstructured tails of core histones with linker DNA.     

Protein kinase in HeLA nucleosomes: a reevaluation of the interactions of histomes with the ends of core particle DNA.

HeLa chromatin core particles contain a protein kinase which transfers phosphate from ATP to both nonhistone proteins and histones. The enzyme preferentially modifies H3 among the histones; about 7% of the H3 molecules in the nucleoprotein are modified at saturation. Activity of this kinase likely contributed to earlier results using crosslinking methodology to study which histones interact with the ends of core particle DNA. When the kinase is largely removed by sedimentation of core particles through sucrose gradients containing 0.45 M NaCl, crosslinking of the 5'-terminal label on DNA is observed only to histone H3. The overall efficiency of the crosslinking reaction is about 15%. The origin of the 5'-terminal 32P previously assigned as crosslinked to H4 is not explained by the current experiments.     

Histone-DNA interactions within chromatin. Isolation of histones from DNA-histone adducts induced in nuclei by UV light.

We have developed a method by which to isolate histones that have been crosslinked to DNA following irradiation of calf thymus nuclei by UV light. The procedure involves separation of protein-DNA adducts from uncrosslinked protein by Sepharose 4B chromatography under dissociating conditions. Histones which are crosslinked to DNA are released by chemical hydrolysis of the DNA and identified by SDS gel electrophoresis. The results indicate that, of the histones, H1 and H3 become crosslinked to the DNA most readily under our irradiation conditions.     

Nucleosomes from normal and regenerating rat liver

Micrococcal-nuclease digestion of rat liver nuclei selectively released mononucleosomes associated with ADP-ribosylated [Caplan, Ord & Stocken (1978) Biochem. J.174, 475-483] histone H1. Two classes of mononucleosome were detected, those that leaked out during digestion and those that were subsequently released by 5mm-sodium phosphate buffer (pH6.8)/0.2mm-NaEDTA. The former, from which histone H1 had been dissociated, contained 140-base-pair-length DNA and core histones;the latter contained core particles and mononucleosomes with histone H1 and 200-base-pair-length DNA. When normal liver nuclei were phosphorylated with [gamma-(32)P]ATP, dissociated histone H1, which could be separated from core particles with Sephadex G-200, showed (32)P uptake. (32)P uptake into histones H2A and poly(ADP-ribosyl)ated H3 was appreciable in core particles, but was less evident in nucleosomes still containing histone H1. When [(3)H]-thymidine was given to partially hepatectomized rats in S-phase, 5-10min pulses in animals of over 300g body wt. showed the presence of high-specific-radioactivity DNA in released core particles and mononucleosomes compared with DNA retained in the nuclear pellets. Mononucleosomes from rat livers in S-phase with new, [(3)H]lysine-containing histones, had higher (32)P incorporation in histones H1 and their core histones, than for di- or tri-nucleosomes. Thermal-denaturation properties of control and phosphorylated mononucleosomes and core particles were very similar; removal of histone H1 and non-histone chromosomal proteins in 0.5m-NaCl markedly increased the proportion of DNA ;melting' below 70 degrees C.     

Histone-histone interactions within chromatin. Crosslinking studies using ultraviolet light.

Irradiation of either whole cells or chromatin at 280 nm results in the covalent linkage of histones 2A and 2B, presumably at their mutual binding sites. The reaction is specific and proceeds with high yield (about 80%). Irradiation of reconstituted nucleohistone containing only H2A, H2B and DNA also yields the H2A-H2B dimer. The cross-linking event is sensitive to the conformation of the H2A-H2B pair since the histones must be bound to DNA for maximum cross-linking specificity at low ionic strength. However, the histones must first interact with each other before being deposited on the DNA, since separate addition of the histones to the DNA yields no dimer upon irradiation. If irradiation is conducted at 254 nm rather than 280 nm, DNA-histone cross-linking appears to dominate.     

Histone H1 and HMG 14/17 are deposited nonrandomly in the nucleus.

We have studied the assembly of histone H1 and the high mobility group nonhistones 14/17 by isopycnic analysis after crosslinking density labeled MSB cell nuclei or chromatin. Carbodiimide crosslinking produces dense poly-H1 and hybrid density H1-H2A histone dimers, indicating that new H1 is deposited nonrandomly, albeit nonconservatively relative to new core histones. Core histone-HMG crosslinking with succinimidyl propionate yields dense HMG 14 in uniformly dense particles and new HMG 17 crosslinked to both dense and light protein, implying that HMG 14 and 17 each deposit nonrandomly; but differently with respect to new core octamers. Propionimidate crosslinking yields dense H1-HMG 17 dimers, suggesting that the interactions of new 14/17 with H1 (new HMG 14-old H1, new HMG 17-new H1) are reciprocal to their interactions with the core histones.     

Primary organization of nucleosomes. Interaction of non-histone high mobility group proteins 14 and 17 with nucleosomes, as revealed by DNA-protein crosslinking and immunoaffinity isolation

The binding sites for histones and high mobility group proteins (HMG) 14 and 17 have been located on DNA in the nucleosomal cores and H1/H5-containing nucleosomes. The nucleosomes were specifically associated with two molecules of the non-histone proteins HMG 14 and/or HMG 17 when followed by DNA-protein crosslinking and immunoaffinity isolation of the crosslinked HMG-DNA complexes. HMGs 14 and 17 were shown to be crosslinked in a similar manner to each core DNA strand at four sites: to both 3' and 5' DNA ends and also at distances of about 25 and 125 nucleotides from the 5' termini of the DNA. These sites are designated as HMG(143), (0), (25) and (125). The site HMG(125) is located at the place where no significant histone-DNA crosslinking was observed. The HMG(125) and HMG(25) sites lie opposite one another on the complementary DNA strands across the minor DNA groove and are placed, similarly to histones, on the inner side of the DNA superhelix in the nucleosome. The crosslinking of HMG 17 to the 3' ends of the DNA is much weaker than that of HMG 14. These data indicate that each of two molecules of HMG 14 and/or HMG 17 is bound to the double-stranded core DNA at two discrete sites: to the 3' and 5' ends of the DNA and at a distance of 20 to 25 base-pairs from each DNA terminus inside the nucleosome on a histone-free DNA region. Binding of HMG 14 or 17 does not induce any detectable rearrangement of histones on DNA and both HMGs seem to choose the same sites for attachment in nucleosomal cores and H1/H5-containing nucleosomes.     

The enhancers and promoters of the Xenopus laevis ribosomal spacer are associated with histones upon active transcription of the ribosomal genes

The presence of histones on the enhancer-promoter region of the X.laevis ribosomal spacer has been studied in embryos at stage 40, where the ribosomal genes are actively transcribed. Isolated tadpole nuclei were either fixed with formaldehyde or irradiated with UV laser to crosslink histones to DNA. The purified protein-DNA complexes were immunoprecipitated with antibodies to the histones H1, H2A and H4 and the DNA fragments carrying the respective histones were analyzed for the presence of spacer enhancer-promoter sequences by hybridization to specific DNA probe. The two independent crosslinking procedures revealed the presence of these DNA sequences in the precipitated DNA. The quantitative analysis of the UV laser-crosslinked complexes showed that histones H2A and H4 were associated with enhancer-promoter DNA in amounts similar to those found for bulk DNA, whilst the content of H1 was reduced.     

Proximity and accessibility studies of histones in nuclei and free nucleosomes.

Histone proximity in chromatin was studied with the cleavable crosslinking reagent, dithiobissuccinimidyl propionate. Crosslinks between H4 and H2a, H4 and H2b, H4 and H3, H2a and H2b, H2b and H3 were found. H1 is also crosslinked to the nucleosomal histones. In nuclei, unsheared chromatin, and H1 depleted chromatin, the four nucleosomal histones are crosslinked at similar relative rates both in 5 mM salt and 100 mM salt. After micrococcal nuclease treatment to generate nucleosomes, H2a and H2b are crosslinked faster than H4 and H3. C14-NEM titration of thiopropionate residues bound to each histone shows that H2a and H2b are more accessible to this reagent after nuclease treatment but that the increased binding was not sufficient by itself to explain the increase in crosslinking. Bolton Hunter reagent was used to further study the accessibility of the four nucleosomal histones in whole chromatin and nuclease digested chromatin. These studies showed that salt increases the accessibility of all four histones while nuclease treatment decreases H4 accessibility.     

Condensation of DNA and chromatin by histones H1, H5 and protamines. The influence of a protein phosphorylation

A mutual displacement of the DNA crosslinking protiens, protamines, histones H1 and H5, is observed if cell nuclei are incubated in solutions containing one of these species. While their competition is in accord with their specific positive charge, a displacement of the core histones does not occur. Crosslinking proteins give rise to the formation of macrocomplexes from DNA and core particles, respectively which in the present study are investigated by stray-light and centrifugation methods. It is shown than the reduction of electrostatic affinities, which in vivo is achieved by a protein phosphorylation, serves to enhance complex sizes, probably by permitting at thermodynamically controlled, ordered association of DNA segments.     

Assembly of newly replicated chromatin.

Mild staphylococcal nuclease digestions under isotonic conditions release fragments of a 200 Å diameter fiber from nuclei of Drosophila melanogaster tissue culture cells. These soluble fragments have high sedimentation coefficients (30–100S) and show tightly packed nucleosomes in the electron microscope. Under the same conditions, newly replicated chromatin is released as more slowly sedimenting fragments (14S). Within 20 min after DNA replication, the nascent chromatin gradually matures into compact supranucleosomal structures which are indistinguishable from bulk chromatin on the isokinetic sucrose gradients.We have used this fractionation technique to examine the question of the fate and assembly of the new histones. After short pulses with either ³⁵S-methionine or ³H-lysine, the radioactive histones do not co-sediment with the bulk chromatin but appear instead in the fractions where the newly replicated DNA is found. Furthermore, the various nascent histones appear in different fractions on the gradient: histones H3 and H4 in 10–15S structures, histones H2A and H2B in 15–50S structures and histone H1 in 30–100S structures. These results, together with the analysis of pulse and pulse-chase experiments of both nascent DNA and histones, strongly suggest that histones H3 and H4 are deposited first on the nascent DNA (during or slightly after the DNA is replicated), histones H2A and H2B are deposited next (2–10 min later) and histone H1 is deposited last (10–20 min after DNA replication). A high turnover 20,000 dalton protein is also associated with the newly replicated chromatin.     

Interactions of acetylated histones with DNA as revealed by UV laser induced histone-DNA crosslinking

The interaction of acetylated histones with DNA in chromatin has been studied by UV laser-induced crosslinking histones to DNA. After irradiation of the nuclei, the covalently linked protein-DNA complexes were isolated and the presence of histones in them demonstrated immunochemically. When chromatin from irradiated nuclei was treated with clostripain, which selectively cleaved the N-terminal tails of core histones, no one of them was found covalently linked to DNA, thus showing that crosslinking proceeded solely via the N-terminal regions. However, the crosslinking ability of the laser was preserved both upon physiological acetylation of histones, known to be restricted to the N-terminal tails, and with chemically acetylated chromatin. This finding is direct evidence that the postsynthetic histone acetylation does not release the N-terminal tails from interaction with DNA.     

Release of nucleosomes from nuclei by bleomycin-induced DNA strand scission

Mononucleosomes were released from both isolated mammalian (hog thyroid) and protozoan (Tetrahymena) nuclei by the bleomycin-induced DNA-strand breaking reaction. Trout sperm nuclei, on the other hand, were protected from the bleomycin-mediated DNA degradation. The mononucleosomes released from the bleomycin-treated nuclei contained the core histones H2A, H2B, H3, and H4; while HMG1 and HMG2 proteins, in addition to the core histones, were detected in the mononucleosomes obtained by micrococcal nuclease digestion of nuclei. HMGs, but not H1 histone, were dissociated into the supernatant by cleavage of chromatin DNA with bleomycin, whereas both HMGs and H1 were found in that fraction by digestion of nuclei with micrococcal nuclease. HMG1 and HMG2 were exclusively dissociated from chromatin with 1 mM bleomycin under the solvent condition where the DNA strand-breaking activity of the drug is repressed. These observations suggest the possibility that bleomycin preferentially binds to linker DNA regions not occupied by H1 histone in chromatin and exclusively dissociates HMG proteins and breaks the DNA strand. The results of the effects on bleomycin-induced DNA cleavage of nuclei of various drugs including polyamines, chelating agents, intercalating antibiotics such as mitomycin C or adriamycin, and radical scavengers are also presented.     

The presence of F3-F2a1 dimers and F1 oligomers in chromatin.

The oligomeric structure of histones in nuclei and chromatin has been studied by crosslinking nuclei and chromatin with 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide. Crosslinked histones were detected as new high molecular weight components on SDS gels, and the protomers of the crosslinked histones were identified by their characteristic ¹²⁵I-fingerprints. The results show that a considerable portion of histones F3 and F2a1 exist in nuclei and chromatin as an F3-F2a1 dimer. Evidence is presented that histone F1 probably exists in chromatin as large oligomers.     

Interaction of benzo[alpha]pyrene diol-epoxide with nuclei and isolated chromatin.

Chicken erythrocyte chromatin and nuclei were labeled with benzo[alpha]-pyrene (B[alpha]P) diol-epoxide (anti) and digested with micrococcal nuclease to mono- and dinucleosomes. Analysis of the distribution of the carcinogen showed that the internucleosomal region bound 3-4 times more carcinogen per unit DNA than did nucleosomes. The enhanced binding of the 'ultimate' carcinogen to the internucleosomal region was similar when isolated chromatin or nuclei were used for in vitro labeling. Furthermore, isolation of the histone core proteins, H2A, H2B, H3 and H4, revealed that only 15% of the carcinogen was associated with the histones and that the majority of the carcinogen was bound to chromosomal DNA. Fluorography of purified nucleosomal histones showed that the covalent association of the carcinogen was mainly with histones H3 and H2B.     

Replication of Xenopus erythrocyte nuclei in a homologous egg extract requires prior proteolytic treatment

Reactivation and reinitiation of DNA replication in quiescent frog erythrocyte nuclei has been analyzed following incubation in extracts prepared from activated Xenopus eggs. Nuclear decondensation and DNA synthesis only occurred if nuclei were pretreated with low doses of trypsin. This protease treatment did not digest histones, but did degrade several nonhistone proteins. Activated erythrocyte nuclei swell and begin DNA synthesis by 30 min after being mixed with the egg extract. In some extracts virtually complete genome replication was achieved in all nuclei after 2-3 hr. Addition of several protease inhibitors during sperm nuclear isolation significantly reduced the template efficiency of these preparations. We concluded that proteolytic alteration of nonhistone nuclear structural proteins may be a general mechanism which permits quiescent nuclei to reenter the replication cycle. Erythrocyte nuclei and egg extracts provide an excellent experimental system in which to investigate the processes of nuclear reactivation.