Synthesis and Preclinical Evaluation of a Highly Improved Anticancer Prodrug Activated by Histone Deacetylases and Cathepsin L.

Lack of absolute selectivity against cancer cells is a major limitation for current cancer therapies. In the previous study, we developed a prodrug strategy for selective cancer therapy using a masked cytotoxic agent puromycin [Boc-Lys(Ac)-Puromycin], which can be sequentially activated by histone deacetylases (HDACs) and cathepsin L (CTSL) to kill cancer cells expressing high levels of both enzymes. Despite the promise as a selective cancer therapy, its requirement of relatively high dosage could be a potential issue in the clinical setting. To address this issue, we aimed to further improve the overall efficacy of our prodrug strategy. Since the proteolytic cleavage by CTSL is the rate-limiting step for the drug activation, we sought to improve the substrate structure for CTSL activity by modifying the α-amino protecting group of lysine. Here we show that protection with Fmoc [Fmoc-Lys(Ac)-Puromycin] exhibits a marked improvement in overall anticancer efficacy compared to the original Boc-Lys(Ac)-Puromycin and this is mainly due to the highly efficient cellular uptake besides its improved substrate structure. Furthermore, to address a concern that the improved drug efficacy might direct high toxicity to the normal cells, we confirmed that Fmoc-Lys(Ac)-Puromycin still retains excellent cancer selectivity in vitro and no obvious systemic off-target toxicity in vivo. Thus our preclinical evaluation data presented here demonstrate that the Fmoc-Lys(Ac)-Puromycin exhibits substantially improved anticancer efficacy, further supporting our approach for the selective cancer therapy.

Selective cancer targeting with prodrugs activated by histone deacetylases and a tumour-associated protease.

Eradication of cancer cells while minimizing damage to healthy cells is a primary goal of cancer therapy. Highly selective drugs are urgently needed. Here we demonstrate a new prodrug strategy for selective cancer therapy that utilizes increased histone deacetylase (HDAC) and tumour-associated protease activities produced in malignant cancer cells. By coupling an acetylated lysine group to puromycin, a masked cytotoxic agent is created, which is serially activated by HDAC and an endogenous protease cathepsin L (CTSL) that remove the acetyl group first and then the unacetylated lysine group liberating puromycin. The agent selectively kills human cancer cell lines with high HDAC and CTSL activities. In vivo studies confirm tumour growth inhibition in prodrug-treated mice bearing human cancer xenografts. This cancer-selective cleavage of the masking group is a promising strategy for the next generation of anticancer drug development that could be applied to many other cytotoxic agents.

Ski-interacting protein (SKIP) interacts with androgen receptor in the nucleus and modulates androgen-dependent transcription.

BACKGROUND: The androgen receptor (AR) is a member of the nuclear receptor (NR) superfamily of ligand-inducible DNA transcription factors, and is the major mediator of male sexual development, prostate growth and the pathogenesis of prostate cancer. Cell and gene specific regulation by the AR is determined by availability of and interaction with sets of key accessory cofactors. Ski-interacting protein (SKIP; SNW1, NCOA62) is a cofactor shown to interact with several NRs and a diverse range of other transcription factors. Interestingly, SKIP as part of the spliceosome is thought to link mRNA splicing with transcription. SKIP has not been previously shown to interact with the AR. RESULTS: The aim of this study was to investigate whether SKIP interacts with the AR and modulates AR-dependent transcription. Here, we show by co-immunoprecipitation experiments that SKIP is in a complex with the AR. Moreover, SKIP increased 5α-dihydrotestosterone (DHT) induced N-terminal/C-terminal AR interaction from 12-fold to almost 300-fold in a two-hybrid assay, and enhanced AR ligand-independent AF-1 transactivation. SKIP augmented ligand- and AR-dependent transactivation in PC3 prostate cancer cells. Live-cell imaging revealed a fast (half-time=129 s) translocation of AR from the cytoplasm to the nucleus upon DHT-stimulation. Förster resonance energy transfer (FRET) experiments suggest a direct AR-SKIP interaction in the nucleus upon translocation. CONCLUSIONS: Our results suggest that SKIP interacts with AR in the nucleus and enhances AR-dependent transactivation and N/C-interaction supporting a role for SKIP as an AR co-factor.

Chromosomal instability in mouse embryonic fibroblasts null for the transcriptional co-repressor Ski.

Ski is a transcriptional regulator that has been considered an oncoprotein given its ability to induce oncogenic transformation in avian model systems. However, studies in mouse and in some human tumor cells have also indicated a tumor suppressor activity for this protein. We found that Ski-/- mouse embryo fibroblasts exhibit high levels of genome instability, namely aneuploidy, consistent with a tumor suppressor function for Ski. Time-lapse microscopy revealed lagging chromosomes and chromatin/chromosome bridges as the major cause of micronuclei (MN) formation and the subsequent aneuploidy. Although these cells arrested in mitosis after treatment with spindle disrupting drugs and exhibited a delayed metaphase/anaphase transition, spindle assembly checkpoint (SAC) was not sufficient to prevent chromosome missegregation, consistent with a weakened SAC. Our in vivo analysis also showed dynamic metaphase plate rearrangements with switches in polarity in cells arrested in metaphase. Importantly, after ectopic expression of Ski the cells that displayed this metaphase arrest died directly during metaphase or after aberrant cell division, relating SAC activation and mitotic cell death. This increased susceptibility to undergo mitosis-associated cell death reduced the number of MN-containing cells. The presented data support a new role for Ski in the mitotic process and in maintenance of genetic stability, providing insights into the mechanism of tumor suppression mediated by this protein.

The Ski protein negatively regulates Siah2-mediated HDAC3 degradation.

Ski acts as a transcriptional co-repressor by multiple direct and indirect interactions with several distinct repression complexes. Ski represses retinoic acid (RA) signaling by interacting with, and stabilizing, key components of the co-repressor complex, namely, HDAC3. However, little is known as to how the Ski protein can stabilize HDAC3. In the present study, we identified the Siah2 protein as a potential E3 ubiquitin ligase that mediated proteasomal degradation of HDAC3. Reciprocal co-immunoprecipitation assays further revealed that Ski interacts with Siah2. Furthermore, co-expression of the Ski protein stabilized the level of Siah2 protein. Since Siah2 regulates its own level of expression by self-degradation, the stabilization of Siah2 by Ski is an indication that Ski association leads to inhibition of Siah2 E3 ubiquitin ligase activity. Only wild-type Ski and Ski truncation mutants that were in the same complex with Siah2 could stabilize HDAC3 levels. Taken together, the results suggest that association with Ski leads to inhibition of Siah2 E3 ubiquitin ligase activity and in this way, the Ski protein inhibits Siah2-mediated proteasomal degradation of HDAC3.

The Ski protein can inhibit ligand induced RARalpha and HDAC3 degradation in the retinoic acid signaling pathway.

Recent data has implicated the Ski protein as being a physiologically relevant negative regulator of signaling by retinoic acid (RA). The mechanism by which Ski represses RA signaling is unknown. Co-immunoprecipitation and immunofluorescence assay showed that Ski and RARalpha are in the same complex in both the absence and presence of RA, which makes Ski different from other corepressors. We determined that Ski can stabilize RARalpha and HDAC3. These results suggest that Ski represses RA signaling by stabilizing corepressor complex.

Ski negatively regulates erythroid differentiation through its interaction with GATA1.

The Ski oncoprotein dramatically affects cell growth, differentiation, and/or survival. Recently, Ski was shown to act in distinct signaling pathways including those involving nuclear receptors, transforming growth factor beta, and tumor suppressors. These divergent roles of Ski are probably dependent on Ski's capacity to bind multiple partners with disparate functions. In particular, Ski alters the growth and differentiation program of erythroid progenitor cells, leading to malignant leukemia. However, the mechanism underlying this important effect has remained elusive. Here we show that Ski interacts with GATA1, a transcription factor essential in erythropoiesis. Using a Ski mutant deficient in GATA1 binding, we show that this Ski-GATA1 interaction is critical for Ski's ability to repress GATA1-mediated transcription and block erythroid differentiation. Furthermore, the repression of GATA1-mediated transcription involves Ski's ability to block DNA binding of GATA1. This finding is in marked contrast to those in previous reports on the mechanism of repression by Ski, which have described a model involving the recruitment of corepressors into DNA-bound transcription complexes. We propose that Ski cooperates in the process of transformation in erythroid cells by interfering with GATA1 function, thereby contributing to erythroleukemia.

Direct interaction of Ski with either Smad3 or Smad4 is necessary and sufficient for Ski-mediated repression of transforming growth factor-beta signaling.

The oncoprotein Ski represses transforming growth factor (TGF)-beta signaling in an N-CoR-independent manner. However, the molecular mechanism(s) underlying this event has not been elucidated. Here, we identify an additional domain in Ski that mediates interaction with Smad3 which is important for this repression. This domain is distinct from the previously reported N-terminal Smad3 binding domain in Ski. Individual alanine substitution of several residues in the domain significantly affected Ski-Smad3 interaction. Furthermore, combined mutations within this domain, together with those in the previously identified Smad3 binding domain, can completely abolish the interaction of Ski with Smad3, while mutation in each domain alone retained partial interaction. By introducing those mutations that abolish direct interaction with Smad3 or Smad4 individually, or in combination, we show that interaction of Ski with either Smad3 or Smad4 is sufficient for Ski-mediated repression of TGF-beta signaling. Furthermore our results clearly demonstrate that Ski does not disrupt Smad3-Smad4 heteromer formation, and recruitment of Ski to the Smad3/4 complex through binding to either Smad3 or Smad4 is both necessary and sufficient for repression.

Signal-dependent N-CoR requirement for repression by the Ski oncoprotein.

The oncoprotein Ski represses transforming growth factor-beta (TGF-beta) and nuclear receptor signaling. To achieve this, Ski has been proposed to recruit the corepressor N-CoR to either the TGF-beta-regulated Smad transcription factors or nuclear receptors. Here we define the role of the Ski/N-CoR interaction in Ski-mediated repression of TGF-beta and vitamin D signaling. We show that Ski can negatively regulate vitamin D-mediated transcription by directly interacting with the vitamin D receptor. More importantly, a Ski single point mutant lacking N-CoR binding revealed that the Ski/N-CoR interaction is essential for repression of vitamin D signaling, but, surprisingly, not TGF-beta signaling. Thus, Ski modulates transcription in either an N-CoR-dependent or -independent manner depending on the signaling pathways targeted.