Enhanced antitumor potential induced by chloroacetate-loaded benzophenones acting as fused tubulin-pyruvate dehydrogenase kinase 1 (PDHK1) ligands.

The majority of cancers detected every year are treated with anti-cancer compounds. Unfortunately, many tumors become resistant to antineoplastic drugs. One option is to use cocktails of compounds acting on different targets to try to overcome the resistant cells. This type of approach can produce good results, but is often accompanied by a sharp increase of associated side effects. The strategy presented herein focuses on the use of a single compound acting on two different biological targets enhancing potency and lowering the toxicity of the chemotherapy. In this light, the approach presented in the current study involves the dual inhibition of human pyruvate dehydrogenase kinase-1 (PDHK1) and tubulin polymerization using mono-, di- and tri-chloroacetate-loaded benzophenones and benzothiophenones. Synthesized molecules were evaluated in vitro on tubulin polymerization and on pyruvate dehydrogenase kinase 1. The cell cycle distribution after treatment of DA1-3b leukemic cells with active compounds was tested. Twenty-two benzo(thio)phenones have been selected by the National Cancer Institute (USA) for evaluation of their anti-proliferative potential against NCI-60 cancer cell lines including multidrug-resistant tumor cell lines. Seventeen molecules proved to be very effective in combating the growth of tumor cells exhibiting inhibitory activities up to nanomolar range. The molecular docking of best antitumor molecules in the study was realized with GOLD in the tubulin and PDHK1 binding sites, and allowed to understand the positioning of active molecules. Chloroacetate-loaded benzo(thio)phenones are dual targeted tubulin- and pyruvate dehydrogenase kinase 1 (PDHK1)-binding antitumor agents and exhibited superior antitumor activity compared to non-chlorinated congeners particularly on leukemia, colon, melanoma and breast cancer cell lines.

Case study: Targeted RNA-sequencing of aged formalin-fixed paraffin-embedded samples for understanding chemical mode of action.

Formalin-fixed paraffin-embedded (FFPE) samples are the only remaining biological archive for many toxicological and clinical studies, yet their use in genomics has been limited due to nucleic acid damage from formalin fixation. Older FFPE samples with highly degraded RNA pose a particularly difficult technical challenge. Probe-based targeted sequencing technologies show promise in addressing this issue but have not been directly compared to standard whole-genome RNA-Sequencing (RNA-Seq) methods. In this study, we evaluated dose-dependent transcriptional changes from paired frozen (FROZ) and FFPE liver samples stored for over 20 years using targeted resequencing (TempO-Seq) and whole-genome RNA-Seq methods. Samples were originally collected from male mice exposed to a reference chemical (dichloroacetic acid, DCA) at 0, 198, 313, and 427 mg/kg-day (n = 6/dose) by drinking water for 6 days. TempO-Seq showed high overlap in differentially expressed genes (DEGs) between matched FFPE and FROZ samples and high concordance in fold-change values across the two highest dose levels of DCA vs. control (R2 ≥ 0.94). Similarly, high concordance in fold-change values was observed between TempO-Seq FFPE and RNA-Seq FROZ results (R2 ≥ 0.92). In contrast, RNA-Seq FFPE samples showed few overlapping DEGs compared to FROZ RNA-Seq (≤5 for all dose groups). Modeling of DCA-dependent changes in gene sets identified benchmark doses from TempO-Seq FROZ and FFPE samples within 1.4-fold of RNA-Seq FROZ samples (93.9 mg/kg-d), whereas RNA-Seq FFPE samples were 3.3-fold higher (310.3 mg/kg-d). This work demonstrates that targeted sequencing may provide a more robust method for quantifying gene expression profiles from aged archival FFPE samples.