Small Molecule Transcriptional Activation Domains.

Transcriptional activators are essential for high fidelity transcription, responsible for seeking out particular genes and up-regulating them to precise levels in a signal responsive fashion. Indeed the altered transcription patterns observed in disease states can often be attributed to malfunctioning and/or misregulated transcriptional activators. Thus, molecules that can reconstitute the function of transcriptional activators, artificial transcription activators, are highly desirable commodities as mechanistic tools and transcription-targeted therapeutics. Transcriptional activators control the specificity and extent of gene upregulation through two domains: the DNA binding domain (DBD) is responsible for the former and the transcriptional activation domain (TAD) dictates the level of gene expression. It has proven quite challenging to identify TAD replacements with functional properties comparable to the natural system despite their likely advantages in terms of stability, delivery, and and/or immunogenic properties. This is likely due to the many open questions surrounding how natural transcriptional activation domains function. To address the need for the development and characterization of small molecule TADs we have employed a combination of organic chemistry, NMR spectroscopy, and biological evaluations to a class of isoxazolidines that functionally mimic natural TADs. We prepared five stereochemically pure isoxazolidine isomers, each of which contained identical functional groups (benzyl, isobutyl and hydroxyl) arranged in different positions around the isoxazolidine ring. All of these amphipathic isoxazolidines functioned as TADs in a cell-free assay, revealing that analogous to endogenous TADs, a particular positioning of functional groups is not required for transcription function. Similar functional trends were observed in a cellular assay. We further demonstrated that the small molecule TADs interact with at least a subset of the same coactivator proteins as do natural TADs. In particular, interaction with the KIX domain of Creb Binding Protein is correlated with transcription function, although binding interactions with Tra1, Med15 and Med23 are also observed. These molecules are thus anticipated to be an excellent starting point for the design of more potent small molecule regulators of transcription.PhDChemistryUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/61622/1/buhrlage_1.pd

Small-Molecule Inhibitors of USP1 Target ID1 Degradation in Leukemic Cells

Inhibitor of DNA binding 1 (ID1) transcription factor is essential for the proliferation and progression of many cancer types, including leukemia. However, the ID1 protein has not yet been therapeutically targeted in leukemia. ID1 is normally polyubiquitinated and degraded by the proteasome. Recently, it has been shown that USP1, a ubiquitin-specific protease, deubiquitinates ID1 and rescues it from proteasome degradation. Inhibition of USP1 therefore offers a new avenue to target ID1 in cancer. Here, using a ubiquitin-rhodamine–based high-throughput screening, we identified small-molecule inhibitors of USP1 and investigated their therapeutic potential for leukemia. These inhibitors blocked the deubiquitinating enzyme activity of USP1 in vitro in a dose-dependent manner with an IC50 in the high nanomolar range. USP1 inhibitors promoted the degradation of ID1 and, concurrently, inhibited the growth of leukemic cell lines in a dose-dependent manner. A known USP1 inhibitor, pimozide, also promoted ID1 degradation and inhibited growth of leukemic cells. In addition, the growth of primary acute myelogenous leukemia (AML) patient-derived leukemic cells was inhibited by a USP1 inhibitor. Collectively, these results indicate that the novel small-molecule inhibitors of USP1 promote ID1 degradation and are cytotoxic to leukemic cells. The identification of USP1 inhibitors therefore opens up a new approach for leukemia therapy. Mol Cancer Ther; 12(12); 2651–62. ©2013 AACR

Piperazinyl quinolines as chemosensitizers to increase fluconazole susceptibility of Candida albicans clinical isolates

The effectiveness of the potent antifungal drug fluconazole is being compromised by the rise of drug-resistant fungal pathogens. While inhibition of Hsp90 or calcineurin can reverse drug resistance in Candida, such inhibitors also impair the homologous human host protein and fungal-selective chemosensitizers remain rare. The MLPCN library was screened to identify compounds that selectively reverse fluconazole resistance in a Candida albicans clinical isolate, while having no antifungal activity when administered as a single agent. A piperazinyl quinoline was identified as a new small-molecule probe (ML189) satisfying these criteria.National Institutes of Health (U.S.) (1 R03 MH086456-01

Selective USP7 inhibition elicits cancer cell killing through a p53-dependent mechanism

Ubiquitin specific peptidase 7 (USP7) is a deubiquitinating enzyme (DUB) that removes ubiquitin tags from specific protein substrates in order to alter their degradation rate and sub-cellular localization. USP7 has been proposed as a therapeutic target in several cancers because it has many reported substrates with a role in cancer progression, including FOXO4, MDM2, N-Myc, and PTEN. The multisubstrate nature of USP7, combined with the modest potency and selectivity of early generation USP7 inhibitors, has presented a challenge in defining predictors of response to USP7 and potential patient populations that would benefit most from USP7-targeted drugs. Here, we describe the structureguided development of XL177A, which irreversibly inhibits USP7 with sub-nM potency and selectivity across the human proteome. Evaluation of the cellular effects of XL177A reveals that selective USP7 inhibition suppresses cancer cell growth predominantly through a p53-dependent mechanism: XL177A specifically upregulates p53 transcriptional targets transcriptome-wide, hotspot mutations in TP53 but not any other genes predict response to XL177A across a panel of similar to 500 cancer cell lines, and TP53 knockout rescues XL177A-mediated growth suppression of TP53 wild-type (WT) cells. Together, these findings suggest TP53 mutational status as a biomarker for response to USP7 inhibition. We find that Ewing sarcoma and malignant rhabdoid tumor (MRT), two pediatric cancers that are sensitive to other p53-dependent cytotoxic drugs, also display increased sensitivity to XL177A

Leucine-rich repeat kinase 2 inhibitors: a patent review (2006-2011)

NIH [P41 GM079575-03]; Michael J Fox foundation for Parkinson's disease research; Fundamental Research Funds for the Central Universities of China [2011121030]; 111 Project of Education of China [B06016]Introduction: Leucine-rich repeat kinase 2 (LRRK2) has received considerable attention since the discovery of LRRK2 mutations in families with dominantly inherited Parkinson's disease (PD) in 2004. The missense mutation G2019S is the most common LRRK2 mutation and has been identified in both familial and sporadic PD cases. The G2019S mutation enhances kinase activity suggesting that LRRK2 could be an attractive therapeutic target for PD and small-molecule ATP-competitive LRRK2 kinase inhibitors are one way to investigate this possibility. Areas covered: Currently, LRRK2 kinase inhibitors are being actively pursued by industry and academia. Herein, patents detailing the discovery of LRRK2 kinase inhibitors from 2006 through 2011 and the corresponding publications from 2006 through July of 2012 are summarized. Expert opinion: Wild-type and mutant forms of LRRK2 are currently being actively pursued as therapeutic targets for the potential treatment of PD. The increasing number of patent applications being filed for inhibitors of LRRK2 is a testament to this activity. Numerous distinct chemo-types have been reported as LRRK2 inhibitors with some demonstrating exceptional potency and selectivity for LRRK2 relative to other kinases. These compounds are being used as pharmacological 'tools' to elucidate the physiological and pathophysiological function of LRRK2 and it appears likely that some will be investigated for their potential therapeutic effects for the treatment of PD

Identification of an allosteric benzothiazolopyrimidone inhibitor of the oncogenic protein tyrosine phosphatase SHP2

The PTPN11 oncogene encodes the cytoplasmic protein tyrosine phosphatase SHP2, which, through its role in multiple signaling pathways, promotes the progression of hematological malignancies and other cancers. Here, we employ high-throughput screening to discover a lead chemical scaffold, the benzothiazolopyrimidones, that allosterically inhibits this oncogenic phosphatase by simultaneously engaging the C-SH2 and PTP domains. We improved our lead to generate an analogue that better suppresses SHP2 activity in vitro. Suppression of Erk phopsphorylation by the lead compound is also consistent with SHP2 inhibition in AML cells. Our findings provide an alternative starting point for therapeutic intervention and will catalyze investigations into the relationship between SHP2 conformational regulation, activity, and disease progression