Inhibitor administration with regard to an established cytotoxic regimen. The criteria for selecting genes for validation were both their presumed relevance in the DNA damage response and previous indications of regulation by an HDAC inhibitor, and additionally, in order to find ��tumor-specific�� markers, omitting genes that typically might be associated with leukocyte biology. Four of the selected genes were induced by vorinostat in the study patients�� PBMC but did not show a similar response in the experimental tumor models. BARD1 encodes a nuclear factor with tumor suppressor activity, the stress response effectors encoded by 942206-85-1 GADD45B and DDIT3 are implicated in cell cycle arrest, DNA repair, and apoptosis, and MSH6 encodes a DNA mismatch repair protein. To date, only three studies seem to have been published on their potential use as biomarkers of therapy response. In contrast, the confirmation of MYC as the only one of the selected genes with rapid and LED209 biological activity transient change in expression in all tested conditions may point to a particular importance of myc in the therapeutic setting with fractionated radiation. Future investigations of vorinostat as possible radiosensitizing agent might be within a long-term curative radiotherapy protocol, for example as an additional component of neoadjuvant chemoradiotherapy for LARC. The confirmed presence of MYC expression in the intended radiotherapy target tissue in LARC patients encourages future exploration of this proto-oncogene as a novel biomarker endpoint. The myc protein acts both as transcriptional activator and repressor, regulating a myriad of genes that collectively conduct cell cycle progression, apoptosis, angiogenesis, and genetic instability. Specifically, it has been suggested that myc activates DNA damage repair genes, and interestingly, that myc in hypoxic tumors acts synergistically with the transcription factor hypoxia-inducible factor type 1a, HIF-1a. Recent evidence indicates that HDAC inhibition suppresses HIF-1a activity. Consequently, mitigation of DNA damage repair capacity through suppression of myc/HIF-1a synergy in hypoxic tumors, typically being resistant to radiation, provides an appealing explanation for the radiosensitizing effect of HDAC inhibitors. However, conflicting data have been presented as to how HDAC inhibition may influence the