Apoptosis in UV-C light irradiated p53 wild-type, apaf-1 and p53 knockout mouse embryonic fibroblasts: interplay of receptor and mitochondrial pathway.

Mouse embryonic fibroblasts (MEFs) deficient for the transcription factor p53 are hypersensitive to UV-C light. They also show a reduced recovery from UV-C induced replication blockage and are unable to repair UV-C photoproducts. In this study, we utilized wild-type (wt), Apaf-1 deficient (apaf-1(-/-)) and p53 deficient (p53(-/-)) MEFs in order to elucidate the role of non-repaired UV-C lesions in apoptotic signalling. Corresponding with the cellular sensitivity determined by the WST assay, p53(-/-) cells displayed the highest level of apoptosis, whereas wt cells showed moderate apoptosis after UV-C irradiation. Apaf1(-/-) cells were most resistant. In wt cells apoptosis was executed both via the mitochondrial and the receptor-mediated pathway, as shown by Bcl-2 decline, induction of fasR and activation of caspases-3,8,9. In apaf-1(-/-) (p53(+/+)) cells, the mitochondrial pathway was blocked downstream of Bcl-2, indicating that in this case apoptosis was mediated via the induction of fasR and caspase-3,8 activation. In p53 deficient cells, non-repaired UV-C induced DNA lesions triggered sustained up-regulation of fas ligand (fasL) mRNA, which was not seen in wt and apaf-1(-/-) cells. Therefore, in p53(-/-) MEFs, the receptor/ligand triggered pathway appeared to be dominant. This was confirmed by significant reduction of apoptosis after DN-FADD transfection. As opposed to wt and apaf-1(-/-) cells, p53 deficient MEFs showed no induction of Fas receptor and no Bcl-2 decline. Nevertheless, the resulting caspase-8 and -3 activation was stronger compared to wt and apaf-1(-/-) cells. The data indicate that UV-C light activates in MEFs both the Fas (CD95, Apo-1) receptor and the mitochondrial damage pathways. In p53(-/-) cells, however, the high level of non-repaired DNA damage forces signalling by fasL upregulation, leading to enhanced UV-C-induced apoptosis.

Cytogenetic detection of a trans-species bystander effect: induction of sister chromatid exchanges in murine 3T3 cells by ganciclovir metabolized in HSV thymidine kinase gene-transfected Chinese hamster ovary cells.

Due to the very limited transduction capacity of hitherto available vectors, the success of gene therapy of tumours by means of suicide genes has so far essentially depended on the transfer of toxic drug metabolites from transduced (metabolizing) cells to adjacent non-transduced cells via gap junctions (bystander effect). Most experimental systems for the detection of a bystander effect yield net data of cell losses and cannot differentiate between killed transduced versus killed bystander cells. Here we report on metabolic cooperation in vitro between CHO cells stably transfected with the thymidine kinase gene of herpes simplex virus type-1 (HSVtk) (metabolizing cells) and Swiss albino 3T3 cells (bystander cells). Both cell lines are readily distinguishable by single cell and colony morphology and by their chromosomal constitution. While 3T3 cells cultured alone were refractory to the antiviral drug ganciclovir (GCV), co-culture with CHO-HSVtk(+) cells led to a dramatic reduction in plating efficiency as well as to a 4-fold increase in sister chromatid exchange rates induced by very low GCV concentrations in the 3T3 bystander cells. The modulator of gap junctional cooperation, all-trans retinoic acid, caused a strong augmentation of the bystander effect, while 18alpha-glycyrrhetinic acid, an inhibitor of gap junctional communication, drastically diminished the toxicity of GCV in the bystander cells. Whereas CHO-HSVtk(+) cells showed a distinct immunoreactivity for connexin43 in the cell membranes, 3T3 cells were almost negative. The co-culture system described here allows unequivocal distinction between metabolizing and bystander cells. In this way, mechanistic aspects of the transfer of genotoxic/cytotoxic metabolites to cells, which per se are unable to form them, become accessible to investigation.

DNA polymerase beta mediates protection of mammalian cells against ganciclovir-induced cytotoxicity and DNA breakage.

The efficacy of suicide herpes simplex virus-1 thymidine kinase (HSVtk)/ganciclovir (GCV) gene therapy is often limited by intrinsic resistance of tumor cells. Here we show that repair of GCV incorporated in DNA is a factor involved in GCV resistance. A protective role of DNA repair in GCV-induced cell killing is supported by the following findings: (a) GCV-exposed Chinese hamster ovary-HSVtk cells exhibited both reduced repair of GCV and cloning efficiency in the presence of a specific polymerase beta (beta-pol) inhibitor, prunasin; (b) DNA beta-pol-deficient mouse fibroblasts were more sensitive to the cytotoxic, apoptosis-inducing, and genotoxic (DNA breakage and chromosomal aberration-inducing) effects of GCV as compared with wild-type and beta-pol-complemented cell lines; (c) methoxyamine, an inhibitor of beta-pol-dependent short-patch base excision repair, sensitized wild-type and complemented beta-pol cells to GCV, whereas it had no effect on the sensitivity of beta-pol-null cells to GCV. Because methoxyamine-mediated sensitization of beta-pol wild-type and beta-pol-complemented cells to GCV did not reach the level of null cells, we suggest that both beta-pol-dependent short- and long-patch base excision repair are involved in protection of cells to GCV. Some implications for HSVtk/GCV gene therapy are being discussed.

Hamster Bcl-2 protein is cleaved in vitro and in cells by caspase-9 and caspase-3.

Full-length cDNA of hamster bcl-2 (771 nt) was cloned by RT-PCR and inserted into pGEX-4T-1 to produce the recombinant hamster Bcl-2 protein. The purified recombinant Bcl-2 protein (26.4 kDa) was used as a substrate for the active human caspase-3 and caspase-9 in vitro. It is shown here that Bcl-2 is efficiently cleaved by caspase-3 to a 23 kDa fragment. Although not possessing a putative caspase-9 cleavage site in its sequence, hamster Bcl-2 was also cleaved by caspase-9 into exactly the same 23 kDa cleavage product, indicating that cleavage occurred at the same site. Caspase-3- and caspase-9-mediated cleavage of Bcl-2 was efficiently blocked by caspase-3 (zDEVD) and caspase-9 (zLEHD) inhibitor, respectively. We also show that caspase-9/-3-mediated cleavage of Bcl-2 occurs in vivo during apoptosis in CHO-HSV-TK cells after exposure to the antiviral drug ganciclovir.

Cloning and functional analysis of cDNA encoding the hamster Bcl-2 protein.

We have cloned cDNA encoding hamster Bcl-2 protein from total RNA of CHO-9 cells by RT-PCR using oligonucleotide primers sharing homology with the sequence of mouse and rat bcl-2. The fragments spanning the total coding region were cloned into pCR4-TOPO and sequenced for verification. The hamster bcl-2 cDNA has a size of 711 nucleotides and encodes a polypeptide of 236 amino acids. Hamster Bcl-2 shares 95.8 and 88.6% similarity with mouse and human Bcl-2, respectively. Northern blot analysis revealed a single 7.5 kb bcl-2 transcript in hamster (CHO-9), mouse (BK4), and rat (H5) cells and a 8.5 kb bcl-2 mRNA in human (HeLa MR) cells. The bcl-2 cDNA (771 bp) was recloned into pcDNA3 and the recombinant construct was transiently transfected into MGMT-deficient HeLa MR cells. Expression of hamster Bcl-2 rendered the cells more resistant to MNNG-induced cytotoxicity, which is consistent with the anti-apoptotic function of Bcl-2.