Histone modification enzymes: novel targets for cancer drugs.

In eukaryotes, genomic DNA is packaged with histone proteins into the cell nucleus as chromatin, condensing the DNA > 10,000-fold. Chromatin is highly dynamic and exerts profound control on gene expression. Localised chromatin decondensation facilitates access of nuclear machinery. Chromatin displays epigenetic inheritance, in that changes in its structure can pass to the next generation independently of the DNA sequence itself. It is now clear that the post-translational modification of histones, for example, acetylation, methylation and phosphorylation, plays a crucial role in the regulation of nuclear function through the 'histone code'. There has been significant progress in identifying and understanding the enzymes that control these complex processes, in particular histone acetyltransferases and histone deacetylases. The exciting discovery that compounds inhibiting histone deacetylase activity also have antitumour properties has focused attention on their use as anticancer drugs. As a consequence, there is ongoing evaluation of several histone deacetylase inhibitor compounds in Phase I and II clinical trials with promising early results. It is likely that many of the enzymes involved in the control of histone modification will provide therapeutic opportunities for the treatment of cancer, including histone methyltransferases and Aurora kinases.

Role of nuclear histone-H1 kinase in regeneration of rat liver.

The activities of nuclear histone-H1 kinase and C-kinase as well as the amount of phosphate bound to histone-H1 following partial hepatectomy were studied in rat. It was found that the nuclear histone-H1 kinase activity increased twice within 80 h, first 20 to 30 h, and second at 50 to 70 h after partial hepatectomy. The timing of increase of the enzyme activity correlated with increased amount of bound phosphate. On the other hand, the increase of the C-kinase activities occurred between 5 and 15 h after partial hepatectomy. Antibodies raised against human cdk2, human cyclin-A and mouse cdc2 kinase showed no detectable effect on the nuclear histone H1 kinase activity. These results suggest that phosphorylation of histone-H1 in liver regeneration may be catalysed by a putative kinase(s).

Curcumin is a non-competitive and selective inhibitor of phosphorylase kinase.

Recently, we reported that curcumin (diferuloylmethane) inhibits the growth of several different kinds of tumor cells. In order to investigate the mechanism of this inhibition, we examined the effects of curcumin on different protein kinases: highly purified protein kinase A (PkA), protein kinase C (PkC), protamine kinase (cPK), phosphorylase kinase (PhK), autophosphorylation-activated protein kinase (AK) and pp60c-src tyrosine kinase. While all kinases tested were inhibited by curcumin, only PhK was completely inhibited at relatively lower concentrations. At around 0.1 mM curcumin, PhK, pp60c-src, PkC, PkA, AK, and cPK were inhibited by 98%, 40%, 15%, 10%, 1%, and 0.5%, respectively. Lineweaver-Burk plot analysis indicated that curcumin is a non-competitive inhibitor of PhK with a Ki of 0.075 mM. Overall, our results indicate that curcumin is a potent and selective inhibitor of phosphorylase kinase, a key regulatory enzyme involved in the metabolism of glycogen. This has important implications for the anti-proliferative effects of curcumin.

Cyclin E and cyclin A as candidates for the restriction point protein.

Progression of cells into S phase is proposed to be determined by accumulation of a labile protein (the restriction point protein R; A. B. Pardee, Proc. Natl. Acad. Sci. USA, 71: 1286-1290, 1974). We report here that cyclin E and cyclin A proteins as well as their dependent histone H1 kinases satisfy all of the criteria for the R protein, which includes late G1 phase increase, an excess delay of appearance after inhibition of protein synthesis in nontransformed cells, and a faster recovery in transformed cells. We suggest that the molecular basis of the R protein could be cyclin production and inactivation.

The topoisomerase II inhibitor VM-26 induces marked changes in histone H1 kinase activity, histones H1 and H3 phosphorylation, and chromosome condensation in G2 phase and mitotic BHK cells.

We have examined the effects of topoisomerase inhibitors on the phosphorylation of histones in chromatin during the G2 and the M phases of the cell cycle. Throughout the G2 phase of BHK cells, addition of the topoisomerase II inhibitor VM-26 prevented histone H1 phosphorylation, accompanied by the inhibition of intracellular histone H1 kinase activity. However, VM-26 had no inhibitory effect on the activity of the kinase in vitro, suggesting an indirect influence on histone H1 kinase activity. Entry into mitosis was also prevented, as monitored by the absence of nuclear lamina depolymerization, chromosome condensation, and histone H3 phosphorylation. In contrast, the topoisomerase I inhibitor, camptothecin, inhibited histone H1 phosphorylation and entry into mitosis only when applied at early G2. In cells that were arrested in mitosis, VM-26 induced dephosphorylation of histones H1 and H3, DNA breaks, and partial chromosome decondensation. These changes in chromatin parameters probably reverse the process of chromosome condensation, unfolding condensed regions to permit the repair of strand breaks in the DNA that were induced by VM-26. The involvement of growth-associated histone H1 kinase in these processes raises the possibility that the cell detects breaks in the DNA through their effects on the state of DNA supercoiling in constrained domains or loops. It would appear that histone H1 kinase and topoisomerase II work coordinately in both chromosome condensation and decondensation, and that this process participates in the VM-26-induced G2 arrest of the cell.