Project description:HeLa cells were labelled with lysosomally localized photocrosslinkable and clickable probes for sphingosine and cholesterol. Upon photocrosslinking and cell lysis, the protein-lipid complexes were clicked to biotin azide and enriched via Streptavidin-immunoprecipitation. Enriched protein-lipid complexes were then analyzed by LC-MS/MS to identify proteins interacting with sphingosine and cholesterol, respectively.

Project description:17-Hydroxydocosahexaenoic acid (17-HDHA), an oxidative metabolite of the fish oil constituent docosahexaenoic acid (DHA, 22:6 n-3), is a signaling lipid with anti-inflammatory properties. The molecular mechanisms underlying the biological effect of 17-HDHA are poorly understood. Here, we report the design, synthesis and application of a complementary pair of bioorthogonal photoreactive probes based on the polyunsaturated scaffold of 17-HDHA and DHA. In these probes, an alkyne serves as a handle to introduce a fluorescent reporter group or a biotin-affinity tag via copper(I)-catalyzed azide-alkyne cycloaddition. This pair of chemical probes was used to map specific protein interaction partners of 17-HDHA in primary human macrophages, which led to the identification of prostaglandin reductase 1 (PTGR1) as a target of 17-HDHA, but not DHA. Ensuing biochemical studies revealed that PTGR1 converted 17-HDHA into 17-oxo-DHA, which inhibited the biosynthesis of the pro-inflammatory lipids 5-HETE and LTB4 in human macrophages and neutrophils.

Project description:Photoreactive fragment-like probes have been applied to discover target proteins that constitute novel cellular vulnerabilities and to identify viable chemical hits for drug discovery. Through forming covalent bonds, functionalized probes can achieve stronger target engagement and require less effort for on-target mechanism validation. However, the design of probe libraries, which directly affects the biological target space that is interrogated, and effective target prioritization remain critical challenges of such a chemical proteomic platform. In this study, we designed and synthesized a diverse panel of twenty fragment-based probes with privileged structural motifs containing both natural product and lead-like elements. These probes were fully functionalized with orthogonal diazirine and alkyne moieties and used for protein crosslinking in live lung cancer cells, target enrichment via “click chemistry,” and subsequent target identification through label-free quantitative LC-MS/MS analysis. Pair-wise comparison with a blunted negative control probe and stringent prioritization via individual cross-comparisons against the entire panel identified glutathione S-transferase zeta 1 (GSTZ1) as a specific and unique target candidate. DepMap database query, RNA interference-based gene silencing and proteome-wide tyrosine reactivity profiling suggested that GSTZ1 cooperated with different oncogenic alterations by supporting survival signaling in refractory NSCLC cells. This finding may form the basis for developing novel GSTZ1 inhibitors to improve the therapeutic efficacy of oncogene-directed targeted drugs. In summary, we designed a novel fragment-based probe panel and developed a target prioritization scheme with improved stringency, which allows for identification of unique target candidates, such as GSTZ1 in refractory lung cancer.

Project description:Photoreactive fragment-like probes have been applied to discover target proteins that constitute novel cellular vulnerabilities and to identify viable chemical hits for drug discovery. Through forming covalent bonds, functionalized probes can achieve stronger target engagement and require less effort for on-target mechanism validation. However, the design of probe libraries, which directly affects the biological target space that is interrogated, and effective target prioritization remain critical challenges of such a chemical proteomic platform. In this study, we designed and synthesized a diverse panel of twenty fragment-based probes containing natural product-based privileged structural motifs for small-molecule lead discovery. These probes were fully functionalized with orthogonal diazirine and alkyne moieties and used for protein crosslinking in live lung cancer cells, target enrichment via “click chemistry,” and subsequent target identification through label-free quantitative LC-MS/MS analysis. Pair-wise comparison with a blunted negative control probe and stringent prioritization via individual cross-comparisons against the entire panel identified glutathione S-transferase zeta 1 (GSTZ1) as a specific and unique target candidate. DepMap database query, RNA interference-based gene silencing and proteome-wide tyrosine reactivity profiling suggested that GSTZ1 cooperated with different oncogenic alterations by supporting survival signaling in refractory NSCLC cells. This finding may form the basis for developing novel GSTZ1 inhibitors to improve the therapeutic efficacy of oncogene-directed targeted drugs. In summary, we designed a novel fragment-based probe panel and developed a target prioritization scheme with improved stringency, which allows for the identification of unique target candidates, such as GSTZ1 in refractory lung cancer.

Project description:The cleavage of sphingoid base phosphates by sphingosine-1-phosphate (S1P) lyase to produce phosphoethanolamine and a fatty aldehyde is the final degradative step in the sphingolipid metabolic pathway. We have studied mice with an inactive S1P lyase gene and have found that, in addition to the expected increase of sphingoid base phosphates, other sphingolipids (including sphingosine, ceramide, and sphingomyelin) were substantially elevated in the serum and /or liver of these mice. This latter increase is consistent with a reutilization of the sphingosine backbone for sphingolipid synthesis due to its inability to exit the sphingolipid metabolic pathway. Furthermore, the S1P lyase deficiency resulted in changes in the levels of serum and liver lipids not directly within the sphingolipid pathway, including phospholipids, triacyglycerol, diacylglycerol, and cholesterol. Even though lipids in serum and lipid storage were elevated in liver, adiposity was reduced in the S1P lyase-deficient mice. Microarray analysis of lipid metabolism genes in liver showed that the S1P lyase deficiency caused widespread changes in their expression pattern. These results demonstrate that S1P lyase is a key regulator of the levels of multiple sphingolipid substrates and reveal functional links between the sphingolipid metabolic pathway and other lipid metabolic pathways that may be mediated by shared lipid substrates and changes in gene expression programs. The disturbance of lipid homeostasis by altered sphingolipid levels may be relevant to metabolic diseases. Experiment Overall Design: RNA samples from liver for three sphingosine-1-phosphate lyase knock-out and three WT mice.

Project description:Pseudouridine-chemical probes-Nanopore direct RNA sequencing

Project description:Chemical proteomics (chemoproteomics) has emerged as a powerful strategy for the high-throughput annotation of protein function. This approach involves using an active site probe to capture an enzyme class of interest from cells, allowing the biological activity of multiple enzymes within that family to be assessed in parallel. Coenzyme A based chemoproteomic probes may have utility in studying the pharmacological interactions of additional enzyme classes, beyond histone acetyltransferases. However, one challenge in applying this approach is how to differentiate a ‘true hit’ from background. Many histone acetyltransferases utilize an ordered binding mechanism, with acetyl-CoA binding first, which allows their chemoproteomic capture to be competed by pre-incubating lysates with acetyl-CoA. However, for acetyltransferases that don’t exhibit this binding mode, or which bind to a different ligand, acetyl-CoA competition may not be evident, limiting our ability to discern selective chemoproteomic enrichment from noise. In this study, two physiochemically distinct capture probes were used to enrich proteins to distinguish true hits from background and identify new targets selectively enriched by CoA-based probes, thus expanding the scope of protein-ligand interactions open to chemoproteomic interrogation.

Project description:“Stress, survival and virulence: the multi-faceted host/microbial interactions.” Bacteria employ epinephrine and norepinephrine, which converge to distinct bacterial crucial processes, like survival and pathogenicity. A novel stress periplasmic membrane protein belonging to previously described BOF family, protein renamed here SrpP, and together with membrane sensor kinase QseC has an essential role in stress response and virulence of S. Typhimurium. SrpP employs its predicted binding pocket, specifically the SrpPE110 residue, and interacts with lipid A modification enzyme, LpxO dioxygenase. Upon this interaction SrpP in S. Typhimurium finely manages multiple membrane functions to culminate in survival upon stress and pathogenesis in vivo, connecting host-stress chemical signaling to cell stress in bacteria. Comparison of sensor histidine kinase qseC mutant expression levels versus wild type strain.

Project description:Chemical Genomics Profiling of Antimalarial Drugs

Project description:S. aureus and S. epidermidis were challenged with D-sphingosine, an antimicrobial lipid similar to sphingosines found in the major staphylococcal niche- human skin. Comparison of responses was used to identify resistance mechanisms and likely mode of action