Iliya G. Pashev

Preferential Binding of High Mobility Group 1 Protein to UV-damaged DNA ROLE OF THE COOH-TERMINAL DOMAIN

Binding of chromosomal high mobility group 1 protein (HMG1) to UV-damaged DNA has been studied with oligonucleotides containing a single dipyrimidine site for formation of UV photolesions. Irradiation of an oligonucleotide with unique TT dinucleotide resulted in generation of cyclobutane pyrimidine dimer with no evidence for induction of (6-4) photoproducts, whereas the analysis of irradiated TC-containing oligonucleotide detected (6-4) photoproducts but not cyclobutane pyrimidine dimers. Mobility shift assays have revealed that HMG1 protein binds preferentially to irradiated TT and TC oligonucleotides. Photoreversal of cyclobutane pyrimidine dimers with DNA photolyase and hydrolysis of the (6-4) photoproducts with hot alkali substantially reduced but did not eliminate binding of HMG1. The protein, therefore, appears to bind the two main types of UV damages in DNA, but some other photolesion(s) contributes to the preferential binding of HMG1 to irradiated DNA. By quantifying gel shift assays and considering the efficiencies of lesion formation, we determined dissociation constants of 1.2 ± 0.5 and 4.0 ± 1.5 μm for irradiated TT and TC oligonucleotides, respectively, and 70 ± 20 μm for the control non-irradiated probes. Tryptic removal of the acidic COOH-terminal domain of HMG1 significantly affected binding of the protein to both irradiated and intact oligonucleotides. The potential role of HMG1 in recognition of the UV lesions in DNA is discussed.

HMGB1 protein inhibits DNA replication in vitro: A role of the acetylation and the acidic tail

The high mobility group box (HMGB) 1 protein is a very abundant and conserved protein that is implicated in many key cellular events but its functions within the nucleus remain elusive. The role of this protein in replication of closed circular DNA containing a eukaryotic origin of replication has been studied in vitro by using native and recombinant HMGB1 as well as various modified HMGB1 preparations such as truncated protein, lacking its C-terminal tail, in vivo acetylated protein, and recombinant HMGB1 phosphorylated in vitro by protein kinase C (PKC). Native HMGB1 extracted from tumour cells inhibits replication and this effect is reduced upon acetylation and completely abolished upon removal of the acidic C-terminal tail. Recombinant HMGB1, however, fails to inhibit replication but it acquires such a property following in vitro phosphorylation by PKC.

A triple helix model for the structure of chromatin fiber

A model of chromatin fiber structure is presented in which a repeating unit of a trinucleosome forms a 3‐dimensional zigzag. Twisting and compression of the zigzag result in a triple helix structure. The model is built mainly on the flow linear dichroism data showing that (a) nucleosomal disc faces are tilted relative to the fiber axis, (b) the orientation of nucleosomes does not change upon folding and unfolding of chromatin, and (c) the orientation of nucleosomes is maintained by the globular domain of histone HI.

Histones Associated with Non-nucleosomal Rat Ribosomal Genes Are Acetylated while Those Bound to Nucleosome-organized Gene Copies Are Not

Acetylation of histones bound to rat rRNA genes has been studied relative to their organization in chromatin, either as canonical nucleosomes, containing the inactive copies, or as anucleosomal nonrepeating structures, corresponding to the transcribed genes (Conconi, A., Widmer, R. M., Koller, T., and Sogo, J. M.(1989) Cell 57, 753-761). Nuclei from butyrate-treated rat tumor cells were irradiated with a UV laser to cross-link proteins to DNA, and the purified covalent complexes were immunofractionated by an antibody that specifically recognized the acetylated histones. Upon probing with sequences coding for mature rat 28 S RNA, DNA of the antibody-bound complexes was 5-20-fold enriched relative to the total rat DNA. Since the laser cross-links histones to DNA in both active and inactive genes, one cannot distinguish which one of them, or both, are bound to acetylated histones. Alternatively, purified mononucleosomes were immunofractionated, but DNA from the antibody-bound monosomes was not enriched in coding rDNA. Taken together, these results suggest that nucleosome-organized rRNA genes are bound to nonmodified histones and that the acetylated histones are associated with the active, anucleosomal gene copies.

Nucleosome Binding Properties and Co-Remodeling Activities of Native and in Vivo Acetylated HMGB-1 and HMGB-2 Proteins †

The participation of HMGB-1 and -2 proteins in chromatin remodeling is investigated. Here, the ability of these proteins and their posttranslationally acetylated forms to affect SWI/SNF and RSC-dependent nucleosome mobilization was studied. Both proteins assisted nucleosome sliding induced by the two remodelers. Following acetylation, these proteins acquire the ability to bind to core particles, a property that has not yet been documented with parental proteins. We further report that compared to the nonmodified proteins, acetylated HMGB-1 and -2 exhibited both stronger binding to linker DNA-containing nucleosomes and a higher co-remodeling activity. Acetylation of HMGB-1 and -2 proteins enhanced binding of SWI/SNF to the nucleosome but did not affect its ATPase activity.

Native HMGB1 protein inhibits repair of cisplatin-damaged nucleosomes in vitro.

The high mobility group box (HMGB) 1 protein, one of the most abundant nuclear non-histone proteins has been known for its inhibitory effect on repair of DNA damaged by the antitumor drug cisplatin. Here, we report the first results that link HMGB1 to repair of cisplatin-treated DNA at nucleosome level. Experiments were carried out with three types of reconstituted nucleosomes strongly positioned on the damaged DNA: linker DNA containing nucleosomes (centrally and end-positioned) and core particles. The highest repair synthesis was registered with end-positioned nucleosomes, two and three times more efficient than that with centrally positioned nucleosomes and core particles, respectively. HMGB1 inhibited repair of linker DNA containing nucleosomes more efficiently than that of core particles. Just the opposite was the effect of the in vivo acetylated HMGB1: stronger repair inhibition was obtained with core particles. No inhibition was observed with HMGB1 lacking the acidic tail. Binding of HMGB1 proteins to different nucleosomes was also analysed. HMGB1 bound preferentially to damage nucleosomes containing linker DNA, while the binding of the acetylated protein was linker independent. We show that both the repair of cisplatin-damaged nucleosomes and its inhibition by HMGB1 are nucleosome position-dependent events which are accomplished via the acidic tail and modulated by acetylation.

Distribution of high mobility group and other acid-soluble proteins in fractionated chromatin

Chromatin was fractionated by digestion with deoxyribonuclease II and precipitation with MgCl2. The Mg2+-soluble fraction, known to be enriched in transcribed DNA sequences, was enriched also in high mobility group proteins 1 and 2 and contained almost all other acid-soluble nonhistone proteins.

THE ROLE OF HISTONE-H1 AND NON-STRUCTURED DOMAINS OF CORE HISTONES IN MAINTAINING THE ORIENTATION OF NUCLEOSOMES WITHIN THE CHROMATIN FIBER

Calf thymus chromatin was digested with trypsin and the structural alterations which occurred were followed by flow linear dichroism. After a sharp initial increase, the amplitude of the positive signal gradually decreased followed by a change of the sign of the dichroism and further increase of the negative signal up to a plateau. These changes of the dichroism were compared to the respective changes in the histone pattern. It was shown that the positive dichroism of chromatin did not depend on the condensation state of chromatin, and that the orientation of the nucleosomes along the chromatin fiber was maintained by the globular domain of H1 and the non-structured parts of core histones.

The binding affinity of HMG1 protein to DNA modified by cis-platin and its analogs correlates with their antitumor activity

The antitumor activity of cis-platin is believed to result from its interaction with cellular DNA and subsequent processing of DNA adducts by damage recognition proteins. Among them are the high mobility group (HMG) proteins 1 and 2, which have been hypothesized to mediate the effect of cis-platin. One possibility suggests that the tight binding of HMG1 to DNA adducts blocks the repair of damaged DNA. In order to further evaluate such a mechanism, several cis-platinum complexes with known antitumor activity have been used to treat DNA and the affinity of HMG1 to the DNA adduct induced by each drug was determined. The dissociation constants for the complexes of HMG1 with the platinated probe were obtained by gel mobility shift assays. The antitumor activity of the tested platinum compounds was found to correlate with the binding affinity of HMG1 to the respective drug-DNA adduct. These findings support the view that HMG1 contributes to cytotoxicity of cis-platin by shielding damaged DNA from repair. In addition, they offer a fast test for screening new platinum compounds for antitumor activity.

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.