Is olomoucine, a weak CDK2 inhibitor, able to induce apoptosis in cancer cells?

Olomoucine (OLO), a substituted purine analogue, is a much weaker inhibitor of cyclin-dependent kinases than other closely related ATP derivatives. It has been recently reported that OLO did not affect the viability of normal human MRC-5 fibroblasts, but it inhibited the proliferation of human HL-60 leukemia cells. Therefore, it was interesting to explore the antiproliferative effect of OLO and to characterize its action on distinct human cancer cells differing in the functional status of the cell cycle. Human HeLa cervical carcinoma and HL-60 leukemia cells were continuously exposed to increasing concentrations of OLO for 24 h and 48 h or alternatively, cells after treatment for 24 h were postincubated in a drug-free medium. Surprisingly, OLO more strongly affected the proliferation of HL-60 cells than that of HeLa cells. Flow cytometric analyses revealed that OLO at higher doses increases the frequency of a hypoploid HL-60 cell population representing cells undergoing apoptosis. These results substantiated the data of the determination of the number of viable cells. Moreover, OLO at higher doses modulates the cell cycle progression of tested cancer cells. Detailed analyses of the DNA concentration in single cells revealed that OLO-mediated reduction of the number of G(1)-phase cells was accompanied by an increase of the frequency of G(2)-phase cells. The kinetics of these changes differed between both tested cancer cell lines, suggesting that some cancer cells exhibit increased susceptibility to OLO action. It remains to clarify whether the strong proapoptotic effect of OLO observed in HL-60 cells depends on their differentiation status.

Outcome of treatment of human HeLa cervical cancer cells with roscovitine strongly depends on the dosage and cell cycle status prior to the treatment.

Exposure of asynchronously growing human HeLa cervical carcinoma cells to roscovitine (ROSC), a selective cyclin-dependent kinases (CDKs) inhibitor, arrests their progression at the transition between G(2)/M and/or induces apoptosis. The outcome depends on the ROSC concentration. At higher dose ROSC represses HPV-encoded E7 oncoprotein and initiates caspase-dependent apoptosis. Inhibition of the site-specific phosphorylation of survivin and Bad, occurring at high-dose ROSC treatment, precedes the onset of apoptosis and seems to be a prerequisite for cell death. Considering the fact that in HeLa cells the G(1)/S restriction checkpoint is abolished by E7, we addressed the question whether the inhibition of CDKs by pharmacological inhibitors in synchronized cells would be able to block the cell-cycle in G(1) phase. For this purpose, we attempted to synchronize cells by serum withdrawal or by blocking of the mitotic apparatus using nocodazole. Unlike human MCF-7 cells, HeLa cells do not undergo G(1) block after serum starvation, but respond with a slight increase of the ratio of G(1) population. Exposure of G(1)-enriched HeLa cells to ROSC after re-feeding does not block their cell-cycle progression at G(1)-phase, but increases the ratio of S- and G(2)-phase, thereby mimicking the effect on asynchronously growing cells. A quite different impact is observed after treatment of HeLa cells released from mitotic block. ROSC prevents their cell cycle progression and cells transiently accumulate in G(1)-phase. These results show that inhibition of CDKs by ROSC in cells lacking the G(1)/S restriction checkpoint has different outcomes depending on the cell-cycle status prior to the onset of treatment.

Roscovitine up-regulates p53 protein and induces apoptosis in human HeLaS(3) cervix carcinoma cells.

Exposure of human HeLaS(3) cervix carcinoma cells to high doses of conventional cytostatic drugs, e.g. cisplatin (CP) strongly inhibits their proliferation. However, most cytostatic agents are genotoxic and may generate a secondary malignancy. Therefore, therapeutic strategy using alternative, not cytotoxic drugs would be beneficial. Inhibition of cyclin-dependent kinases (CDKs) by pharmacological inhibitors became recently a promising therapeutic option. Roscovitine (ROSC), a selective CDK inhibitor, efficiently targets human malignant cells. ROSC induces cell cycle arrest and apoptosis in human MCF-7 breast cancer cells. ROSC also activates p53 protein. Activation of p53 tumor suppressor protein is essential for induction of apoptosis in MCF-7 cells. Considering the fact that in HeLaS(3) cells wt p53 is inactivated by the action of HPV-encoded E6 oncoprotein, we addressed the question whether ROSC would be able to reactivate p53 protein in them. Their exposure to ROSC for 24 h induced cell cycle arrest at G(2)/M and reduced the number of viable cells. Unlike CP, ROSC in the used doses did not induce DNA damage and was not directly cytotoxic. Despite lack of detectable DNA lesions, ROSC activated wt p53 protein. The increase of p53 levels was attributable to the ROSC-mediated protein stabilization. Further analyses revealed that ROSC induced site-specific phosphorylation of p53 protein at Ser46. After longer exposure, ROSC induced apoptosis in HeLaS(3) cells. These results indicate that therapy of HeLaS(3) cells by ROSC could offer an advantage over that by CP due to its increased selectivity and markedly reduced risk of generation of a secondary cancer.

Pleiotropic effects of selective CDK inhibitors on human normal and cancer cells.

Escape from the proper control of the cell cycle by up-regulation of cyclins or aberrant activation of cyclin-dependent kinases (CDKs) as well as by inactivation of cellular inhibitors of CDKs (CKI) leads to malignant transformation. Loss of cellular CKIs in cancers provided a rationale for development of pharmacological inhibitors of CDKs. Recently synthesized CKIs, e.g., purine derivatives such as olomoucine (OLO) and roscovitine (ROSC) are non-genotoxic and exhibit increased selectivity towards CDK2 and CDK7/9. Interestingly, both drugs induce additional effects. Recently, a new, unexpected action of OLO on normal human cells was observed. OLO strongly up-regulates CLIMP-63, a 65 kD protein that mediates the anchoring of the ER to microtubules. Moreover, ROSC induces in human MCF-7 cells phosphorylation of p53 protein at Ser-46 which in turn initiates caspase-independent apoptosis. In the present contribution we raised the question whether both CKIs would be able to block cell cycle progression and to reactivate p53 protein in human HPV-positive HeLa cervix carcinoma cells. We also addressed the question whether exponentially growing cancer cells are more susceptible to the inhibitory action of CKIs than normal cells. Our results show that HeLa cells are much more sensitive to ROSC than normal fibroblasts. ROSC induces G(2) arrest and apoptosis in HeLa cells. It also reactivates and stabilizes wt p53 protein. The increase of p53 protein coincides with down-regulation of E6 oncoprotein. Thus, the biological action of substituted purines is not restricted to the inhibition of CDKs and open new perspectives for their therapeutic applications.

Cellular and organismal ageing: Role of the p53 tumor suppressor protein in the induction of transient and terminal senescence.

In recent years, an impact of the p53 tumor suppressor protein in the processes of cellular and organismal ageing became evident. First hints were found in model organisms like Saccharomyces cerevisiae, Caenorhabditis elegans, and Drosophila melanogaster where a clear connection between ageing phenotypes and pathways that are regulated by p53, were found. Interestingly, pathways that are central to the ageing process are usually also involved in energy metabolism and are highly conserved throughout evolution. This also supports the long known empiric finding that caloric restriction has a positive impact on the life span of a wide variety of organisms. Within the last years, on the molecular level, an involvement of the insulin-like growth factor and of the histone deacetylase SRIT1 could be shown. Insight on the impact of p53 on ageing at the organismal level came from mice expressing aberrant forms of the p53 protein. Obviously, the balance of the full length p53 protein and of the shorter p44/DeltaNp53 isomer bear a strong impact on ageing. The shorter isoform regulates full length p53 and in cases where there is too much of the longer isoform, this leads to elevated apoptosis resulting in decreased tumor incidence but also in premature ageing due to exhaustion of the renewal potential. Therefore, modulating the expression of the truncated p53 isoform accordingly, might lead to increased health-span and elevated life-span.