Hdac3 is a key target for Hdac inhibitors that are efficacious in cutaneous T cell lymphoma. Moreover, the regulation of chromatin structure is critical as thymocytes transition from an immature cell with open chromatin to a mature T cell with tightly condensed chromatin. To define the phenotypes controlled by Hdac3 during T cell development, we conditionally deleted Hdac3 using the Lck-Cre transgene. This strategy inactivated Hdac3 in the double-negative stages of thymocyte development and caused a significant impairment at the CD8 immature single-positive (ISP) stage and the CD4/CD8 double-positive stage, with few mature CD4؉ or CD8 ؉ single-positive cells being produced. When Hdac3 ؊/؊ mice were crossed with Bcl-xL-, Bcl2-, or TCR-expressing transgenic mice, a modest level of complementation was found. However, when the null mice were crossed with mice expressing a fully rearranged T cell receptor ␣ transgene, normal levels of CD4 single-positive cells were produced. Thus, Hdac3 is required for the efficient transit from double-negative stage 4 through positive selection.
Concerns about the extent to which graduate programs adequately prepare students for the workplace have prompted numerous calls for reform. Understanding what employers look for in doctoral graduates can help schools better align graduate training with workplace needs. Twelve pharmaceutical scientists across diverse specialties and career pathways described the skills considered requisite for success in today’s science economy. Depth and breadth of knowledge, communication, collaboration, adaptability, research productivity, experiential training, and motivation and drive were among the themes identified. These results can be used to inform the development of doctoral curricula in the biomedical sciences.
The aberrant protein-protein interaction between calmodulin and mutant huntingtin protein in Huntington's disease patients has been found to contribute to Huntington's disease progression. A high-throughput screen for small molecules capable of disrupting this interaction revealed a sultam series as potent small-molecule disruptors. Diversification of the sultam scaffold afforded a set of 24 analogs or further evaluation. Several structure-activity trends within the analog set were found, most notably a negligible effect of absolute stereochemistry and a strong beneficial correlation with electron-withdrawing aromatic substituents. The most promising analogs were profiled for off-target effects at relevant kinases and, ultimately, one candidate molecule was evaluated for neuroprotection in a neuronal cell model of Huntington's disease.
Huntington’s disease is a progressive and lethal neurodegenerative disease caused by an increased CAG repeat mutation in exon 1 of the huntingtin gene (mutant huntingtin). Current drug treatments provide only limited symptomatic relief without impacting disease progression. Previous studies in our lab and others identified the abnormal binding of mutant huntingtin protein with calmodulin, a key regulator of calcium signaling. Disrupting the abnormal binding of mutant huntingtin to calmodulin reduces perturbations caused by mutant huntingtin in cell and mouse models of Huntington’s disease and importantly normalizes receptor-stimulated calcium release. Using a series of high-throughput in vitro and cell-based screening assays, we identified numerous small-molecule hits that disrupt the binding of mutant huntingtin to calmodulin and demonstrate protective effects. Iterative optimization of one hit resulted in nontoxic, selective compounds that are protective against mutant huntingtin cytotoxicity and normalized receptor-stimulated intracellular calcium release in PC12 cell models of Huntington’s disease. Importantly, the compounds do not work by reducing the levels of mutant huntingtin, allowing this strategy to complement future molecular approaches to reduce mutant huntingtin expression. Our novel scaffold will serve as a prototype for further drug development in Huntington’s disease. These studies indicate that the development of small-molecule compounds that disrupt the binding of mutant huntingtin to calmodulin is a promising approach for the advancement of therapeutics to treat Huntington’s disease.
Huntington's disease (HD) is a neurodegenerative disorder caused by an autosomal dominant mutation in the huntingtin (htt) gene. Previous studies in our lab demonstrated that disrupting the binding of mutant huntingtin (mhtt) to calmodulin (CaM) had beneficial effects in cell culture and the R6/2 transgenic animal model. The goal of the current study is to identify and develop small chemical compounds that are non‐toxic and can selectively disrupt the binding of mhtt to CaM. To this end, we employed a high throughput AlphaScreen assay along with counter‐screening assays and identified 481 hit compounds that disrupt the interaction between (His)htt‐CaM(GST). The structures of the hits obtained were analyzed and structurally diverse representative scaffolds were chosen for further development. Analogs of these compounds synthesized from the selected scaffolds were re‐screened in the primary AlphaScreen assay and tested for cytotoxicity. Next, assays were employed to determine if the hits identified in the primary screen can selectively disrupt the mhtt‐CaM interaction without affecting other functions of CaM. The compound selectivity is being determined using two CaM dependent enzymes which are abundantly expressed in neuronal cells and play an important role in neuronal function; Ca+2/CaM dependent death associated protein kinase 1 (DAPK1) and Ca+2/CaM dependent protein kinase 2 gamma (CAMK2ϒ). We have identified numerous compounds that have shown preferential activity in disrupting the (His)htt‐CaM(GST) interaction. Compounds that were non‐toxic and selectively disrupted the binding of mhtt to CaM are tested in cell‐based screening assays to determine if the compounds are protective against deleterious effects of mhtt expression. So far, we have identified two scaffolds that selectively disrupt the binding of mhtt to calmodulin and show protection against mhtt‐induced toxicity. Studies are ongoing to determine if these scaffolds will reduce accumulation of aggregated htt protein and normalize mitochondrial deficits associated with mhtt expression. In the future, these compounds will be tested for their protective effects in animal models of HD. Overall, these studies will aid in identifying compounds that will serve as novel and promising biological probes for drug development in HD.Support or Funding Information1RO1NSO88059This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.
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