Transfectant mosaic spheroids: a new model for evaluation of tumour cell killing in targeted radiotherapy and experimental gene therapy.

BACKGROUND: We describe an in vitro tumour model for targeted radiotherapy and gene therapy that incorporates cell population heterogeneity. MATERIALS AND METHODS: Transfectant mosaic spheroids (TMS) and transfected mosaic monolayers (TMM) are composed of two cell populations derived from a single cell line. The cells of one population were transfected with the noradrenaline transporter gene (NAT), allowing active uptake of a radiolabelled targeting agent meta-[131I]iodobenzylguanidine ([131I]MIBG); the other population of cells was derived from the same parent line and transfected with a marker gene - green fluorescent protein (GFP). After treatment with [131I]MIBG, cell kill was determined in TMM by clonogenic assay and in TMS by clonogenic assay and spheroid growth delay. RESULTS: We have used the TMS model to assess the 'radiological bystander effect' (radiation cross-fire) conferred by the beta-emitting radiopharmaceutical [131I] MIBG whose cellular uptake is facilitated by the transfected gene encoding NAT. We show that cell killing by [131I]MIBG in both TMS and TMM cultures increased in direct proportion to the fraction of NAT-transfected cells and that the degree of cell killing against fraction transfected was greater in TMS, suggestive of a greater bystander effect in the three-dimensional culture system. CONCLUSIONS: TMS provide a useful model for assessment of the effectiveness of targeted radiotherapy in combination with gene therapy when less than 100% of the target cell population is expressing the NAT transgene. Further, this novel model offers the unique opportunity to investigate radiation-induced bystander effects and their contribution to cell cytotoxicity in radiotherapy and other gene therapy applications.

Expression in UVW glioma cells of the noradrenaline transporter gene, driven by the telomerase RNA promoter, induces active uptake of [131I]MIBG and clonogenic cell kill.

One of the most effective ways to kill cancer cells is by treatment of tumours with radiation. However, the administered dose of radiation to the tumour is limited by normal tissue toxicity. Strategies which decrease normal tissue exposure relative to tumour dose are urgently sought. One such promising scheme involves gene transfer, leading to the introduction of transporters specific for pharmaceuticals which can be labelled with radionuclides. We have previously demonstrated in vitro, that transfer of the noradrenaline transporter (NAT) gene, under viral promoter control, induces in host cells the active accumulation of the radiopharmaceutical [131I]meta-iodobenzylguanidine ([131I]MIBG) which results in kill of clonogens. We now report 17-fold enhancement of [131I]MIBG uptake by UVW glioma cells transfected with the NAT gene whose expression is driven by the human telomerase RNA (hTR) promoter (70% the uptake achieved by the strong viral promoter). Multicellular spheroids composed of hTR-NAT-transfected UVW cells exhibited dose-dependent susceptibility to treatment with [131I]MIBG. This was demonstrated by decreased survival of clonogens and complete sterilization of clonogens derived from spheroids and also failure of spheroids to regrow after administration of 7 MBq/ml [131I]MIBG. These data suggest hTR regulated expression of NAT may be an effective gene therapy strategy.

A gene therapy/targeted radiotherapy strategy for radiation cell kill by.

BACKGROUND: Although [131I]meta-iodobenzylguanidine (MIBG) is currently one of the best agents available for targeted radiotherapy, its use is confined to a few neural crest derived tumours which accumulate the radiopharmaceutical via the noradrenaline transporter (NAT). To determine whether this drug could be used for the treatment of non-NAT expressing tumours following genetic manipulation, we previously showed that plasmid mediated transfection of NAT into a non-NAT expressing glioblastoma cell line, UVW, endowed the host cells with the capacity to actively accumulate [131I]MIBG. We now present data defining the conditions required for complete sterilisation of NAT transfected cells cultured as multicellular spheroids and treated with [131I]MIBG. METHODS: NAT transfected UVW cells, grown as monolayers and spheroids, were treated with various doses of [131I]MIBG and assessed for cell kill by clonogenic survival and measurement of spheroid volume over time (growth delay). Spheroids were left intact for different time periods to assess the effect of radiation crossfire on cell death. RESULTS AND CONCLUSIONS: Total clonogen sterilisation was observed when the cells were grown as three-dimensional spheroids and treated with 7 MBq/ml [131I]MIBG. The added benefit of radiation crossfire was demonstrated by the improvement in cell kill achieved by prolongation of the maintenance of [131I]MIBG treated spheroids in their three-dimensional form, before disaggregation and clonogenic assay. When left intact for 48 h after treatment, spheroid cure was achieved by exposure to 6 MBq/ml [131I]MIBG. These results demonstrate that the efficiency of cell kill by [131I]MIBG targeted therapy is strongly dependent on beta-particle crossfire irradiation. This gene therapy/targeted radiotherapy strategy has potential for [131I]MIBG mediated cell kill in tumours other than those derived from the neural crest.