Consequences of combining siRNA-mediated DNA methyltransferase 1 depletion with 5-aza-2'-deoxycytidine in human leukemic KG1 cells.

5-azacytidine and 5-aza-2'-deoxycytidine are clinically used to treat patients with blood neoplasia. Their antileukemic property is mediated by the trapping and the subsequent degradation of a family of proteins, the DNA methyltransferases (DNMT1, DNMT3A, and DNMT3B) leading to DNA demethylation, tumor suppressor gene re-expression and DNA damage. Here we studied the respective role of each DNMT in the human leukemia KG1 cell line using a RNA interference approach. In addition we addressed the role of DNA damage formation in DNA demethylation by 5-aza-2'-deoxycytidine. Our data show that DNMT1 is the main DNMT involved in DNA methylation maintenance in KG1 cells and in mediating DNA damage formation upon exposure to 5-aza-2'-deoxycytidine. Moreover, KG1 cells express the DNMT1 protein at a level above the one required to ensure DNA methylation maintenance, and we identified a threshold for DNMT1 depletion that needs to be exceeded to achieve DNA demethylation. Most interestingly, by combining DNMT1 siRNA and treatment with low dose of 5-aza-2'-deoxycytidine, it is possible to uncouple DNA damage formation from DNA demethylation. This work strongly suggests that a direct pharmacological inhibition of DNMT1, unlike the use of 5-aza-2'-deoxycytidine, should lead to tumor suppressor gene hypomethylation and re-expression without inducing major DNA damage in leukemia.

Designing a tool allowing for a standardized assessment of resistance to drug diversion.

OBJECTIVES: Drug diversion is a growing problem in numerous countries. Some laboratories have developed tamper-resistant formulations. The problem for healthcare authorities is now to assess new formulations developed to limit the risk of diversion for administration by another mode and intended mode. It would be helpful to have a pertinent panel of in vitro tests allowing assessment of how a formulation may be altered, both for healthcare authorities and for laboratories, so as to implement adequate sanitary measures. We designed a methodology/tool allowing assessment, in a standardized manner, of the formulation's resistance to drug diversion. We present the various steps leading to the construction of the scale and to its first use. METHODS: Creating a Steering Committee - Choosing assays or parameters - standardized by a monograph of the European Pharmacopoeia and pragmatic assays related to users' behaviors - for the assessment of formulation resistance to drug diversion. Designing a scale: i) applying all these tests to a panel of formulations; ii) applying a score by drug and by test; and iii) attribution of weighting per test and calculating the total score for a drug. RESULTS: Eight tests or parameters and 14 drugs (diverted drugs and controls) were chosen. Buprenorphine Subutex® had the lowest score and flunitrazepam Rohypnol® the highest. CONCLUSIONS: Our tool allowed classification of the various drugs selected. This classification correlated with results of postmarketing authorization assessment. Rohypnol®, which was the object of many measures, including formulation changes, obtained the highest score in our study.

Triptolide is an inhibitor of RNA polymerase I and II-dependent transcription leading predominantly to down-regulation of short-lived mRNA.

Triptolide, a natural product extracted from the Chinese plant Tripterygium wilfordii, possesses antitumor properties. Despite numerous reports showing the proapoptotic capacity and the inhibition of NF-kappaB-mediated transcription by triptolide, the identity of its cellular target is still unknown. To clarify its mechanism of action, we further investigated the effect of triptolide on RNA synthesis in the human non-small cell lung cancer cell line A549. Triptolide inhibited both total RNA and mRNA de novo synthesis, with the primary action being on the latter pool. We used 44K human pan-genomic DNA microarrays and identified the genes primarily affected by a short treatment with triptolide. Among the modulated genes, up to 98% are down-regulated, encompassing a large array of oncogenes including transcription factors and cell cycle regulators. We next observed that triptolide induced a rapid depletion of RPB1, the RNA polymerase II main subunit that is considered a hallmark of a transcription elongation blockage. However, we also show that triptolide does not directly interact with the RNA polymerase II complex nor does it damage DNA. We thus conclude that triptolide is an original pharmacologic inhibitor of RNA polymerase activity, affecting indirectly the transcription machinery, leading to a rapid depletion of short-lived mRNA, including transcription factors, cell cycle regulators such as CDC25A, and the oncogenes MYC and Src. Overall, the data shed light on the effect of triptolide on transcription, along with its novel potential applications in cancers, including acute myeloid leukemia, which is in part driven by the aforementioned oncogenic factors.