BID preferentially activates BAK while BIM preferentially activates BAX, affecting chemotherapy response.

Apoptosis is a highly regulated form of cell death that controls normal homeostasis as well as the antitumor activity of many chemotherapeutic agents. Commitment to death via the mitochondrial apoptotic pathway requires activation of the mitochondrial pore-forming proteins BAK or BAX. Activation can be effected by the activator BH3-only proteins BID or BIM, which have been considered to be functionally redundant in this role. Herein, we show that significant activation preferences exist between these proteins: BID preferentially activates BAK while BIM preferentially activates BAX. Furthermore, we find that cells lacking BAK are relatively resistant to agents that require BID activation for maximal induction of apoptosis, including topoisomerase inhibitors and TRAIL. Consequently, patients with tumors that harbor a loss of BAK1 exhibit an inferior response to topoisomerase inhibitor treatment in the clinic. Therefore, BID and BIM have nonoverlapping roles in the induction of apoptosis via BAK and BAX, affecting chemotherapy response.

The human POLH gene is not mutated, and is expressed in a cohort of patients with basal or squamous cell carcinoma of the skin.

Skin cancer, the most common cancer in the general population, is strongly associated with exposure to the ultraviolet component of sunlight. To investigate the relationship between DNA damage processing and skin tumour development, we determined the POLH status of a cohort of skin cancer patients. The human POLH gene encodes DNA polymerase eta (poleta), which normally carries out accurate translesion synthesis past the major UV-induced photoproduct, the dithymine cyclobutane dimer. In the absence of active poleta in xeroderma pigmentosum variant (XPV) patients, mutations accumulate at sites of UV-induced DNA damage, providing the initiating step in skin carcinogenesis. Forty patients diagnosed with skin cancer were genotyped for polymorphisms in the POLH protein-coding sequence, using glycosylase-mediated polymorphism detection (GMPD) and direct DNA sequencing of POLH PCR products derived from white blood cell genomic DNA. All individuals carried the wild-type POLH sequence. No POLH mutations were identified in genomic DNA from skin tumours derived from 15 of these patients. As determined by RT-PCR, POLH mRNA was expressed in all normal and skin tumour tissue examined. Poleta protein was also detectable by Western blotting, in two matched normal and skin tumour extracts. An alternatively spliced form of POLH mRNA, lacking exon 2, was more readily detected in skin tissue than in white blood cells from the same patient. Real-time PCR was used to quantify POLH expression in matched normal and skin tumour-derived mRNA from a series of patients diagnosed with either basal or squamous cell carcinoma. Compared to matched normal skin tissue from the same patient, 1 of 7 SCC, and 4 of 10 BCC tumours examined showed at least a 2-fold reduction in POLH expression, while 1 of 7 SCC, and 3 of 10 BCC tumours showed at least a 2-fold increase in POLH expression. Differences in gene expression, rather than sequence changes may be the main mechanism by which POLH status varies between normal and skin tumours in the population under investigation. Knowledge of the POLH status in skin tumours could contribute to an understanding of the role of this gene in the development of the most common cancer in the general population.