Stig Linder

Docetaxel induces apoptosis in hormone refractory prostate carcinomas during multiple treatment cycles

Caspase-cleaved proteins are released from disintegrated apoptotic cells and can be detected in the circulation. We here addressed whether caspase-cleaved cytokeratin 18 (CK18-Asp396) can be used as a serum biomarker for assessment of the clinical efficiency of chemotherapy in hormone-refractory prostate cancer (HRPC). A total of 82 patients with HRPC were evaluated during 751 treatment cycles, either with estramustine (EMP)/vinorelbine or with EMP/docetaxel. The levels of CK18-Asp396 and of total CK18 were measured in patient serum before and during therapy by ELISA. Docetaxel induced significant increases in serum CK18-Asp396 (P<0.0001) and total CK18 (P<0.0002), suggesting induction of apoptosis. Similarly, vinorelbine induced increases in both CK18-Asp396 and CK18 (P<0.001 and 0.011). In contrast, EMP induced increases in total serum CK18 (P<0.0001), but not in CK18-Asp396 (P=0.13). The amplitudes of docetaxel-induced increases were associated with baseline prostate-specific antigen (PSA) and CK18 serum levels in these patients, consistent with tumoral origin of caspase-cleaved fragments. Docetaxel induced significant increases in CK18-Asp396 during second-, third- and fourth-line therapy and induced increased levels of CK18-Asp396 during treatment cycles 1–8. In contrast, vinorelbine induced significant increases only during cycles 1–3. In a subgroup of 32 patients that received EMP/vinorelbine in second line followed by EMP/docetaxel in third line, docetaxel induced stronger increases than vinorelbine (P=0.008). These results show that the CK18-Asp396 serum marker can be used to assess tumour apoptosis in vivo and suggest that the clinical efficiency of docetaxel in HRPC is due to induction of apoptosis during multiple treatment cycles.

Specific demonstration of drug-induced tumour cell apoptosis in human xenografts models using a plasma biomarker

Pharmacodynamic (PD) assays should be used before advancing new drugs to clinical trials. Most PD assays measure the response to drugs in tissue, a procedure which requires tissue biopsies. The M30-Apoptosense ELISA is a PD biomarker assay for the quantitative determination of caspase-cleaved cytokeratin 18 (CK18) released from apoptotic carcinoma cells into blood. We here demonstrate that whereas the M30-Apoptosense ELISA assay detects human caspase-cleaved CK18, the mouse and rat CK18 caspase cleavage products are detected with low affinity. The M30-Apoptosense ELISA therefore facilitates the determination of drug-induced apoptosis in human tumour xenografts in rodents using plasma samples, largely independently from host toxicity. Increases of caspase-cleaved CK18 were observed in plasma from different carcinoma xenograft models in response to anticancer drugs. The appearance caspase-cleaved CK18 in plasma was found to reflect formation of the caspase-cleaved epitope in FaDu head-neck carcinomas and in cultured cells. The M30-Apoptosense assay allows determination of tumour response in blood from xenograft models and from patients, providing a powerful tool for translational studies of anticancer drugs.

Massive induction of apoptosis of multicellular tumor spheroids by a novel compound with a calmodulin inhibitor-like mechanism

Abstract Background: A number of anticancer drug candidates have been identified by cell-based screens utilizing tumor cells grown in monolayer culture. Since such cultures are poor models of 3-D tumor

127 Identification of CB3, a novel inhibitor of the ubiquitin-proteasome system

Preclinical testing is an important part of cancer drug development. The aim of this thesis was to establish and evaluate preclinical in vitro methods useful in the development of new anticancer drugs. In paper I, the development of non-clonogenic assays (FMCA-GM) using CD34+ stem cells for assessment of haematological toxicity was described. A high correlation was seen when comparing the 50% inhibitory concentrations (IC50) from FMCA-GM with the IC50 from the established clonogenic assay (CFU-GM). In paper II, FMCA-GM was complemented with additional cell models, establishing a normal cell panel. In vitro toxicity towards the five normal cell types was compared with known clinical adverse event profiles. The normal cell panel roughly reflected the tissue specific toxicities but was most useful in the prediction of therapeutic index. In paper III the use of peripheral blood lymphocytes from human, dog, rat and mouse to detect species differences in cellular drug sensitivity was described. Good agreement between our method and the established CFU-GM assay was observed. In paper II the benefit of using primary tumour cells from patients to predict cancer diagnosis-specific activity was studied. The in vitro activity of fourteen anticancer drugs was tested in tumour samples of both haematological and solid tumour origin. In general, clinical activity was well reflected. In paper IV, the efficacy and toxicity models were applied for experimental follow-up of a novel inhibitor of the ubiquitin-proteasome system, CB3 (Phosphoric acid, 2,3-dihydro-1,1-dioxido-3-thienyl diphenyl ester). In the preliminary characterization of CB3, antitumour activity and a favourable toxicity profile were displayed, although the exact mechanism of action remains to be elucidated. CB3 will therefore be further investigated. In conclusion, the work presented here contributes to different parts of the preclinical drug development and the methods may aid in the characterization of anticancer compounds