SARS-CoV-2 is the causative viral pathogen driving the COVID-19 pandemic that prompted an immediate global response to the development of vaccines and antiviral therapeutics. For antiviral ...therapeutics, drug repurposing allows for rapid movement of the existing clinical candidates and therapies into human clinical trials to be tested as COVID-19 therapies. One effective antiviral treatment strategy used early in symptom onset is to prevent viral entry. SARS-CoV-2 enters ACE2-expressing cells when the receptor-binding domain of the spike protein on the surface of SARS-CoV-2 binds to ACE2 followed by cleavage at two cut sites by TMPRSS2. Therefore, a molecule capable of inhibiting the protease activity of TMPRSS2 could be a valuable antiviral therapy. Initially, we used a fluorogenic high-throughput screening assay for the biochemical screening of 6030 compounds in NCATS annotated libraries. Then, we developed an orthogonal biochemical assay that uses mass spectrometry detection of product formation to ensure that hits from the primary screen are not assay artifacts from the fluorescent detection of product formation. Finally, we assessed the hits from the biochemical screening in a cell-based SARS-CoV-2 pseudotyped particle entry assay. Of the six molecules advanced for further studies, two are approved drugs in Japan (camostat and nafamostat), two have entered clinical trials (PCI-27483 and otamixaban), while the other two molecules are peptidomimetic inhibitors of TMPRSS2 taken from the literature that have not advanced into clinical trials (compounds 92 and 114). This work demonstrates a suite of assays for the discovery and development of new inhibitors of TMPRSS2.
Nonsteroidal anti-inflammatory drugs (NSAIDs) are well-known for their effects on inflammatory gene expression. Although NSAIDs are known to impact multiple cellular signaling mechanisms, a recent ...finding is that the NSAID salicylate can disrupt histone acetylation, in part through direct inhibition of the lysine acetyltransferase (KAT) p300/CBP. While salicylate is a relatively weak KAT inhibitor, its CoA-linked metabolite is more potent; however, the ability of NSAID metabolites to inhibit KAT enzymes biochemically and in cells remains relatively unexplored. Here we define the role of metabolic and nonmetabolic mechanisms in inhibition of KAT activity by NSAID chemotypes. First, we screen a small panel of NSAIDs for biochemical inhibition of the prototypical KAT p300, leading to the finding that many carboxylate-containing NSAIDs, including ibuprofen, are able to function as weak inhibitors. Assessing the inhibition of p300 by ibuprofen-CoA, a known NSAID metabolite, reveals that linkage of ibuprofen to CoA increases its biochemical potency toward p300 and other KAT enzymes. In cellular studies, we find that carboxylate-containing NSAIDs inhibit histone acetylation. Finally, we exploit the stereoselective metabolism of ibuprofen to assess the role of its acyl-CoA metabolite in regulation of histone acetylation. This unique strategy reveals that formation of ibuprofen-CoA and histone acetylation are poorly correlated, suggesting metabolism may not be required for ibuprofen to inhibit histone acetylation. Overall, these studies provide new insights into the ability of NSAIDs to alter histone acetylation, and illustrate how selective metabolism may be leveraged as a tool to explore the influence of metabolic acyl-CoAs on cellular enzyme activity.
The androgen receptor is a key regulator of prostate cancer and the principal target of current prostate cancer therapies collectively termed androgen deprivation therapies. Insensitivity to these ...drugs is a hallmark of progression to a terminal disease state termed castration-resistant prostate cancer. Therefore, novel therapeutic options that slow progression of castration-resistant prostate cancer and combine effectively with existing agents are in urgent need. We show that JG-98, an allosteric inhibitor of HSP70, re-sensitizes castration-resistant prostate cancer to androgen deprivation drugs by targeting mitochondrial HSP70 (HSPA9) to suppress aerobic respiration. Rather than impacting androgen receptor stability as previously described, JG-98's primary effect is inhibition of mitochondrial translation, leading to disruption of electron transport chain activity. Although functionally distinct from HSPA9 inhibition, direct inhibition of the electron transport chain with a complex I or II inhibitor creates a similar physiological state capable of re-sensitizing castration-resistant prostate cancer to androgen deprivation therapies. These data identify a significant role for HspA9 in mitochondrial ribosome function and highlight an actionable metabolic vulnerability of castration-resistant prostate cancer.
Undergraduate students in the teaching laboratory have successfully used N-heterocyclic carbenes (NHCs) as organocatalysts for the acetylation of primary alcohols, despite the high water sensitivity ...of uncomplexed (“free”) NHCs. The free NHC readily reacted with chloroform, resulting in an air- and moisture-stable adduct that liberates the free NHC when heated to temperatures above 45 °C in solution. The free NHC is a kinetically competent catalyst for the acetylation of benzyl, n-amyl, and isoamyl alcohols, a process that was monitored by gas chromatography (GC) and nuclear magnetic resonance (NMR) spectroscopy. Using the method of initial rates, students have calculated the relative rates for the three alcohol substrates, noting the trend: rate of benzyl > rate of n-amyl > rate of isoamyl alcohol. In their reports, students used these rates to demonstrate how NHC catalysts are sensitive to the steric bulk of the alcohol substrates. Overall, students were exposed to all aspects of chemical catalysis: synthesis of a catalyst, collection of initial rate data, development of a steric model to explain the data, and postulation of catalyst modification for increased activity based on their model.
Abstract
Dysregulated metabolism is a feature of many diseases, including cancer. In addition to providing energy and building blocks to growing cells, altered metabolism can assist in tumor growth ...by producing “oncometabolites”. For example, in hereditary leiomyomatosis and renal cell carcinoma (HLRCC) inactivating mutations in fumarate hydratase (FH) leads to accumulation of millimolar levels of an oncometabolite, fumarate. At such high concentrations, fumarate can spontaneously react with protein cysteine residues leading to a post-translational modification (PTM) called cysteine succination. This PTM can directly stimulate tumorigenic signaling, however, current methods to study this PTM are limited. Our lab has developed chemical proteomic methods to investigate proteome-wide targets of cysteine succination. Using these methods, we have identified hundreds of targets of fumarate in normal kidney cells as well as HLRCC cells. One interesting target identified that has implications in cancer progression is SMARCC1, a core subunit of a nucleosome remodeling complex known as the SWI/SNF complex. The SWI/SNF complex is a well-known tumor suppressor and mutation of this complex leads to cancer development. We have demonstrated that excess fumarate levels result in hyper-modification of SMARCC1 and decrease in SWI/SNF complex stability. This instability also results in an increase in EZH2 expression as well as activity, and an increase in H3K27Me3. Our current efforts are aimed at understanding how fumarate affects the function of this complex in vivo and exploring the potential of using EZH2 inhibitors in the treatment of HLRCC.
Citation Format: Sarah E. Bergholtz, Chloe A. Briney, Rhushikesh A. Kulkarni, David Wei, Daniel W. Bak, Jonathan H. Shrimp, Eranthie Weerapana, W. Marston Linehan, Jordan L. Meier. Chemoproteomic profiling of the oncometabolite fumarate abstract. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 2759.
Non-steroidal anti-inflammatory drugs (NSAIDs) are well known for their effects on inflammatory gene expression. Although NSAIDs are known to impact multiple cellular signaling mechanisms, a recent ...finding is that the NSAID salicylate can disrupt histone acetylation, in part through direct inhibition of the lysine acetyltransferase (KAT) p300/CBP. While salicylate is a relatively weak KAT inhibitor, its CoA-linked metabolite is more potent; however, the ability of NSAID metabolites to inhibit KAT enzymes biochemically and in cells remains relatively unexplored. Here we define the role of metabolic and non-metabolic mechanisms in inhibition of KAT activity by NSAID chemotypes. First, we screen a small panel of NSAIDs for biochemical inhibition of the prototypical KAT p300, leading to the finding that many carboxylate-containing NSAIDs, including ibuprofen, are able to function as weak inhibitors. Assessing the inhibition of p300 by ibuprofen-CoA, a known NSAID metabolite, reveals that linkage of ibuprofen to CoA increases its biochemical potency towards p300 and other KAT enzymes. In cellular studies, we find that carboxylate-containing NSAIDs inhibit histone acetylation. Finally, we exploit the stereoselective metabolism of ibuprofen to assess the role of its acyl-CoA metabolite in regulation of histone acetylation. This unique strategy reveals that formation of ibuprofen-CoA and histone acetylation are poorly correlated, suggesting metabolism may not be required for ibuprofen to inhibit histone acetylation. Overall, these studies provide new insights into the ability of NSAIDs to alter histone acetylation, and illustrate how selective metabolism may be leveraged as a tool to explore the influence of metabolic acyl-CoAs on cellular enzyme activity.
Short chain fatty acids (SCFAs) play a central role in health and disease. One function of these signaling molecules is to serve as precursors for short chain fatty acylation, a class of ...metabolically-derived posttranslational modifications (PTMs) that are established by lysine acetyltransferases (KATs) and lysine deacetylases (KDACs).
Via
this mechanism, short chain fatty acylation serves as an integrated reporter of metabolism as well as KAT and KDAC activity, and has the potential to illuminate the role of these processes in disease. However, few methods to study short chain fatty acylation exist. Here we report a bioorthogonal pro-metabolite strategy for profiling short chain fatty acylation in living cells. Inspired by the dietary component tributyrin, we synthesized a panel of ester-caged bioorthogonal short chain fatty acids. Cellular evaluation of these agents led to the discovery of an azido-ester that is metabolized to its cognate acyl-coenzyme A (CoA) and affords robust protein labeling profiles. We comprehensively characterize the metabolic dependence, toxicity, and histone deacetylase (HDAC) inhibitor sensitivity of these bioorthogonal pro-metabolites, and apply an optimized probe to identify novel candidate protein targets of short chain fatty acids in cells. Our studies showcase the utility of bioorthogonal pro-metabolites for unbiased profiling of cellular protein acylation, and suggest new approaches for studying the signaling functions of SCFAs in differentiation and disease.
A systematically designed panel of biorthogonal pro-metabolites was synthesized and evaluated as agents for tracing cellular short chain fatty acylation.
A systematically designed panel of biorthogonal pro-metabolites was synthesized and evaluated as agents for tracing cellular short chain fatty acylation.
Short chain fatty acids (SCFAs) play a ...central role in health and disease. One function of these signaling molecules is to serve as precursors for short chain fatty acylation, a class of metabolically-derived posttranslational modifications (PTMs) that are established by lysine acetyltransferases (KATs) and lysine deacetylases (KDACs).
Via
this mechanism, short chain fatty acylation serves as an integrated reporter of metabolism as well as KAT and KDAC activity, and has the potential to illuminate the role of these processes in disease. However, few methods to study short chain fatty acylation exist. Here we report a bioorthogonal pro-metabolite strategy for profiling short chain fatty acylation in living cells. Inspired by the dietary component tributyrin, we synthesized a panel of ester-caged bioorthogonal short chain fatty acids. Cellular evaluation of these agents led to the discovery of an azido-ester that is metabolized to its cognate acyl-coenzyme A (CoA) and affords robust protein labeling profiles. We comprehensively characterize the metabolic dependence, toxicity, and histone deacetylase (HDAC) inhibitor sensitivity of these bioorthogonal pro-metabolites, and apply an optimized probe to identify novel candidate protein targets of short chain fatty acids in cells. Our studies showcase the utility of bioorthogonal pro-metabolites for unbiased profiling of cellular protein acylation, and suggest new approaches for studying the signaling functions of SCFAs in differentiation and disease.