Dual HDAC and PI3K Inhibitor CUDC-907 Downregulates MYC and Suppresses Growth of MYC-dependent Cancers.

Upregulation of MYC is a common driver event in human cancers, and some tumors depend on MYC to maintain transcriptional programs that promote cell growth and proliferation. Preclinical studies have suggested that individually targeting upstream regulators of MYC, such as histone deacetylases (HDAC) and phosphoinositide 3-kinases (PI3K), can reduce MYC protein levels and suppress the growth of MYC-driven cancers. Synergy between HDAC and PI3K inhibition in inducing cancer cell death has also been reported, but the involvement of MYC regulation is unclear. In this study, we demonstrated that HDAC and PI3K inhibition synergistically downregulates MYC protein levels and induces apoptosis in "double-hit" (DH) diffuse large B-cell lymphoma (DLBCL) cells. Furthermore, CUDC-907, a small-molecule dual-acting inhibitor of both class I and II HDACs and class I PI3Ks, effectively suppresses the growth and survival of MYC-altered or MYC-dependent cancer cells, such as DH DLBCL and BRD-NUT fusion-positive NUT midline carcinoma (NMC) cells, and MYC protein downregulation is an early event induced by CUDC-907 treatment. Consistently, the antitumor activity of CUDC-907 against multiple MYC-driven cancer types was also demonstrated in animal models, including DLBCL and NMC xenograft models, Myc transgenic tumor syngeneic models, and MYC-amplified solid tumor patient-derived xenograft (PDX) models. Our findings suggest that dual function HDAC and PI3K inhibitor CUDC-907 is an effective agent targeting MYC and thus may be developed as potential therapy for MYC-dependent cancers. Mol Cancer Ther; 16(2); 285-99. ©2016 AACR.

Potential advantages of CUDC-101, a multitargeted HDAC, EGFR, and HER2 inhibitor, in treating drug resistance and preventing cancer cell migration and invasion.

CUDC-101 is a novel, small-molecule, anticancer agent targeting histone deacetylase (HDAC), EGF receptor (EGFR), and HER2. It is currently in phase I clinical development in patients with solid tumors. Previously, we reported that CUDC-101 has potent antiproliferative and proapoptotic activity in cultured tumor cells and in vivo xenograft models. We now show that cancer cells that have acquired resistance to single-target EGFR inhibitors through upregulation of AXL or loss of E-cadherin remain sensitive to CUDC-101, which inhibits MET- and AXL-mediated signaling, restores E-cadherin expression, and reduces cell migration. CUDC-101 also efficiently inhibited the proliferation of MET-overexpressing non-small cell lung cancer and gastric cancer cell lines and inhibited the migration and invasion of invasive tumor cells. Taken together, these results suggest that coupling HDAC and HER2 inhibitory activities to an EGFR inhibitor may potentially be effective in overcoming drug resistance and preventing cancer cell migration.

Conditional expression of the TVA receptor allows clonal analysis of descendents from Cre-expressing progenitor cells.

An understanding of the number and types of progeny produced by progenitor cells during development provides a foundation for studies of when and where cell fate determination takes place. Lineal relationships can be revealed by the identification of descendents of cells that express a recombinase, such as Cre or Flp. This method provides data concerning gene expression history, but does not provide clonal resolution among the descendents. An alternative method employs retroviral labeling, which permits the identification of clones, but does not allow for the tracking of gene expression history. Here we report a combination of these methods to circumvent each method's limitations. By employing the specificity of Cre expression, and by selecting only a subset of cells with a Cre history for retroviral infection, clones with a gene expression history can be labeled. The method utilizes a conditional allele of the avian tumor virus receptor A (TVA), which allows infection of mouse cells following Cre activity, with mammalian retroviral vectors pseudotyped with the ASLV-A envelope glycoprotein (EnvA). We quantified the efficiency and specificity of this system in vivo and in vitro. We also generated a series of retroviral vectors encoding a variety of histochemical and fluorescent reporter genes that enable the tracking of mixtures of clones, thus enabling better resolution of clonal boundaries. This method and new vectors can be used to further our understanding of the gene expression patterns of progenitor cells that make particular daughter cells, as well as provide a platform for manipulating identified subsets of developing cells.