Local tumor control and DNA-PK activity of peripheral blood lymphocytes in prostate cancer patients receiving radiotherapy.

Repair of DNA damage is critical for genomic stability, and DNA-dependent protein kinase (DNA-PK) has an important role in repairing double-strand breaks. We examined whether the DNA-PK activity of peripheral blood lymphocytes (PBLs) was related to biochemical (prostate-specific antigen: PSA) relapse and radiation toxicity in prostate cancer patients who have received radiotherapy. A total of 69 patients with localized adenocarcinoma of the prostate participated in this study. Peripheral blood was collected 2 years or later after radiotherapy and centrifuged, then DNA-PK activity was measured by a filter binding assay. The high DNA-PK activity group had a significantly higher PSA relapse-free survival rate than the low DNA-PK activity group. The 10-year PSA relapse-free survival was 87.0% in the high DNA-PK activity group, whereas it was 52.7% in the low DNA-PK activity group. Multivariate analysis showed the Gleason score and the level of DNA-PK activity were significant predictors of PSA relapse after radiotherapy. In addition, the low DNA-PK activity group tended to have a higher incidence of Grade 1-2 urinary toxicity than the high DNA-PK activity group. Prostate cancer patients with low DNA-PK activity had a higher rate of PSA relapse and a higher incidence of urinary toxicity. DNA-PK activity in PBLs might be a useful marker for predicting PSA relapse and urinary toxicity, possibly contributing to personalized treatment of prostate cancer.

cDNA analysis of gene expression associated with DNA-dependent protein kinase activity.

DNA-dependent protein kinase (DNA-PK) is thought to play a pivotal role in DNA double-strand break repair. We recently demonstrated the association of DNA-PK activity in peripheral blood lymphocytes (PBL) with the incidence of chromosomal aberrations and the risk of cancer. In this study, we applied cDNA array technology to find the expression of genes which are associated with DNA-PK activity in PBLs with various levels of DNA-PK activity. Most genes correlated with DNA-PK activity involved cell cycle regulation. Moreover, the transcription factor E2F1, which plays an important role in cell cycle progression, exhibited strong correlation with the DNA-PK activity and Rbp130, which is considered a negative regulator of E2F, showed inverse correlation with DNA-PK activity. In silico promoter analyses showed the presence of at least one E2F binding site in the promoter regions of Ku70, Ku86, DNA-PKcs and genes associated with DNA-PK activity. In order to examine the relationship among the E2F1 expression, the expression of genes related with DNA-PK activity, and DNA-PK activity, we activated PMLs by PHA to progress the cell cycle. After PHA activation of PML, the expression of E2F1 and DNA-PK activity increased. The expression of most genes in PHA-stimulated PBLs had a similar relationship with DNA-PK activity to that without PHA stimulation. These results indicate that the E2F transcription factor may regulate the concerted expression of genes related with DNA-PK activity.