Haematologica, Vol 92, Issue 9, 1286-1288 doi:10.3324/haematol.10680
Copyright © 2007 by Ferrata Storti Foundation

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Chronic Lymphocytic Leukemia

Roscovitine in B-chronic lymphocytic leukemia cells: high apoptosis-inducing efficacy and synergism with alemtuzumab independent of the patients’ pretreatment status

Eva Weingrill^*,°, Albert Wölfler^*, Dirk Strunk^*, Werner Linkesch^*, Heinz Sill^*, Peter M. Liebmann^°,

^* Division of Hematology, Department of Internal Medicine
^° Institute of Pathophysiology, Medical University Graz, Austria

Correspondence: Peter M. Liebmann, PhD, Institute of Pathophysiology, Centre of Molecular Medicine, Medical University Graz, Heinrichstrasse 31a, 8010 Graz, Austria. Phone: international +43.316.3807676. Fax: international +43.316.3809640. E-mail: peter.liebmann{at}meduni-graz.at

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Roscovitine induced apoptosis in isolated B-chronic lymphocytic leukemia cells of 25 patients of whom nine with relapsed and seven with fludarabine-refractory disease. It was synergistic with alemtuzumab and restored sensitivity to alemtuzumab in initially alemtuzumab-resistant samples. Observed roscovitine-induced up-regulation of CD52 surface expression may be one of the underlying mechanisms for this synergism.

Key words: B-CLL, roscovitine, alemtuzumab, apoptosis, synergism.

Despite excellent remission rates now achieved with purine analogs as well as combination therapies, the vast majority of patients with B-cell chronic lymphocytic leukemia (B-CLL) relapses after primary treatment. Among these patients, resistance to purine analogs, such as fludarabine, is common and related to poor prognosis.¹ Since treatment options for such patients are still limited, additional therapeutic strategies including new drugs are mandatory.

Roscovitine, a small-molecule inhibitor of cyclin-dependent kinases (CDK), was shown to induce apoptosis in isolated B-CLL cells by caspase activation and modulation of bcl-2 family proteins.² To establish a role for roscovitine in the treatment of relapsed B-CLL patients we isolated B-CLL cells of 25 patients. Nine of them had relapsed after and seven were clinically refractory to fludarabine therapy (clinical characteristics are shown in Table 1). Peripheral blood mononuclear cells (PBMC) of six healthy donors were also collected. All B-CLL cells and PBMC were incubated with increasing concentrations of roscovitine for 72 hours. The percentage of apoptotic cells was determined by DiOC₆/propidium iodide-staining and FACS analysis.² The exact ED50 (effective dose to induce apoptosis in 50% of cells) and ED90 values for each patient sample were calculated by median effect plots using CalcuSyn^® software (Biosoft, Cambridge, UK). We observed a potent apoptosis-inducing activity of roscovitine in B-CLL cells compared with PBMC of healthy donors, with similar ED50 and ED90 values in B-CLL cells isolated from fludarabine-refractory compared to fludarabine-sensitive and -naive patients (Figure 1A). The high efficacy of roscovitine in B-CLL cells irrespective of patients’ pretreatment status might be explained by different mechanisms of action of these drugs. While fludarabine treatment results in p53-mediated cell death, apoptosis induced by roscovitine or its pure R-enantiomer CYC202 is independent of p53 activation² or defects in p53-dependent pathways.³ The preferential apoptotic activity in B-CLL cells, which has also been observed by others,^2,3 seems to be a particular clinical benefit of roscovitine. Indeed, other CDK inhibitors, such as flavopiridol, which has already been tested in clinical studies in B-CLL patients,^4,5 do not show this phenomenon.

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Table 1. Patients’ clinical characteristics.

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Figure 1. (left). A. ED50 (white dots) and ED90 values (black dots) for roscovitine in B-CLL-cells of patients naive, sensitive or refractory to fludarabine (F) as well as PBMC of healthy subjects. While patient fludarabine status did not influence ED50 and ED90 values for roscovitine in B-CLL cells, PBMC of healthy controls displayed significantly higher ED50 and ED90 values compared with B-CLL cells (**p=0.002 and *** p<0.001 vs. PBMC) as calculated by a one-way ANOVA with Tukey Test for post-hoc analysis. B. Roscovitine sensitized alemtuzumab-hyporesponsive/resistant B-CLL cells to alemtuzumab-induced complement-mediated cytotoxicity. Nine B-CLL cell samples displaying an ED50 for alemtuzumab >20 µg/mL were incubated with 10 µM roscovitine (R) for 48 hours followed by the addition of 20 µg/mL alemtuzumab (A) with complement for another 24 hours or either drug alone and assayed for cell death. Mean percentages of DiOClow cells ± SEM are shown. A two-way repeated ANOVA evaluation followed by Tukey post-hoc analysis revealed that alemtuzumab and roscovitine alone were without significant effect, but the combination of both resulted in a significant (***p<0.001) increase in cell death compared with each treatment alone or solvent. C. Roscovitine induced up-regulation of CD52 surface expression in 10 out of 12 B-CLL samples analyzed. A paired Student’s t-test confirmed that the difference in mean fluorescence intensity (MFI) between roscovitine and solvent treated B-CLL cells was significant (p<0.05).

To study the potential synergism with drugs commonly used in patients with relapsed B-CLL we examined roscovitine in combination with mitoxantrone or alemtuzumab^6,7 applying the combination index (CI) method.^8,9 Roscovitine and alemtuzumab revealed a significant synergistic activity in 22 B-CLL samples (mean CI (±SEM) at 50%, 75% and 90% apoptotic cells: 0.92±0.05, 0.68±0.04 and 0.63±0.05, while a CI <0.9 indicates synergism, between 0.9 and 1.1 an additive effect and >1.1 antagonism). Three B-CLL samples had to be excluded from the analysis, since an ED50 for alemtuzumab due to resistance to alemtuzumab-induced complement-mediated cytotoxicity could not be established. By contrast, roscovitine plus mitoxantrone was only additive in the eleven B-CLL samples tested (CI50% 0.88±0.09, CI75% 0.96±0.07 and CI90% 1.17±0.08). These findings point to a specific mechanism of roscovitine to induce synergistic activity only with selected drugs. Interestingly, CYC202 exhibited synergistic activity with bortezomib and doxorubicin in a multiple myeloma cell line,¹⁰ but was not even additive with fludarabine in B-CLL cells.³

In our cohort there were three B-CLL samples resistant and six B-CLL samples hyporesponsive to alemtuzumab, i.e. with an ED50 for alemtuzumab >20 µg/mL compared with 4,85 µg/mL in alemtuzumab-responsive B-CLL samples. To test whether roscovitine can restore sensitivity to alemtuzumab in these samples they were incubated with 10 µM roscovitine for 48 hours followed by addition of 20 µg/mL alemtuzumab with complement for another 24 hours.^6,7 Roscovitine was able to restore alemtuzumab-induced complement mediated cytotoxicity in the initially hyporesponsive/resistant B-CLL tumors (Figure 1B).

FACS analysis showed an up-regulation of CD52 on the surface of B-CLL cells after 24 hours of incubation with 10 µm roscovitine in 10 out of 12 patient samples analyzed (Figure 1C). Expression of CD20, CD23 and CD24, another GPI-anchored protein found on the surface of B-CLL cells, remained unchanged (data not shown). However, since synergistic CI values were found in one of the two B-CLL samples, which did not show roscovitine-induced up-regulation of CD52, additional mechanisms may be involved in the synergistic activity of roscovitine and alemtuzumab.

In conclusion, we describe a potent apoptosis-inducing effect of roscovitine in isolated B-CLL cells irrespective of the patients’ pretreatment status. We also demonstrate a synergistic activity with alemtuzumab in these B-CLL tumors involving up-regulation of CD52 expression. In addition, roscovitine could restore sensitivity to alemtuzumab-induced complement-mediated cytotoxicity in initially alemtuzumab-resistant/hyporesponsive B-CLL tumors. These results suggest roscovitine is a promising candidate drug for clinical tests alone and in combination with alemtuzumab in relapsed B-CLL patients.

 
Funding: this study was supported by Österreichische Krebshilfe Steiermark (EF 05/2003) and the Franz Lanyar Foundation (P307).

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1. Keating MJ, O'Brien S, Kontoyiannis D, Plunkett W, Koller C, Beran M, et al. Results of first salvage therapy for patients refractory to a fludarabine regimen in chronic lymphocytic leukemia. Leuk Lymphoma 2002;43:1755-62.[CrossRef][Web of Science][Medline]
2. Hahntow IN, Schneller F, Oelsner M, Weick K, Ringshausen I, Fend F, et al. Cyclin-dependent kinase inhibitor Roscovitine induces apoptosis in chronic lymphocytic leukemia cells. Leukemia 2004;18:747-55.[CrossRef][Web of Science][Medline]
3. Alvi AJ, Austen B, Weston VJ, Fegan C, MacCallum D, Gianella-Borradori A, et al. A novel CDK inhibitor, CYC202 (R-roscovitine), overcomes the defect in p53-dependent apoptosis in B-CLL by down-regulation of genes involved in transcription regulation and survival. Blood 2005;105:4484-91.[Abstract/Free Full Text]
4. Byrd JC, Peterson BL, Gabrilove J, Odenike OM, Grever MR, Rai K, et al. Treatment of relapsed chronic lymphocytic leukemia by 72-hour continuous infusion or 1-hour bolus infusion of flavopiridol: results from Cancer and Leukemia Group B study 19805. Clin Cancer Res 2005;11:4176-81.[Abstract/Free Full Text]
5. Flinn IW, Byrd JC, Bartlett N, Kipps T, Gribben J, Thomas D, et al. Flavopiridol administered as a 24-hour continuous infusion in chronic lymphocytic leukemia lacks clinical activity. Leuk Res 2005;29:1253-7.[CrossRef][Web of Science][Medline]
6. Zent CS, Chen JB, Kurten RC, Kaushal GP, Marie Lacy H, Schichman SA. Alemtuzumab (CAMPATH 1H) does not kill chronic lymphocytic leukemia cells in serum free medium. Leuk Res 2004;28:495-507.[CrossRef][Web of Science][Medline]
7. Golay J, Manganini M, Rambaldi A, Introna M. Effect of alemtuzumab on neoplastic B cells. Haematologica 2004;89:1476-83.[Abstract/Free Full Text]
8. Chou TC, Talalay P. Quantitative analysis of dose-effect relationships: the combined effects of multiple drugs or enzyme inhibitors. Adv Enzyme Regul 1984;22:27-55.[CrossRef][Web of Science][Medline]
9. Takahashi N, Li W, Banerjee D, Guan Y, Wada-Takahashi Y, Brennan MF, et al. Sequence-dependent synergistic cytotoxicity of ecteinascidin-743 and paclitaxel in human breast cancer cell lines in vitro and in vivo. Cancer Res 2002;62:6909-15.[Abstract/Free Full Text]
10. Raje N, Kumar S, Hideshima T, Roccaro A, Ishitsuka K, Yasui H, et al. Seliciclib (CYC202 or R-roscovitine), a small-molecule cyclin-dependent kinase inhibitor, mediates activity via down-regulation of Mcl-1 in multiple myeloma. Blood 2005;106:1042-7.[Abstract/Free Full Text]

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