Project description:The small molecule YC-1 was identified as identified as a selectively active agent against subsets of the two major live cancer subtypes, intrahepatic cholangiocarcinoma and hepatocellular carcinoma. Response to YC-1 is dependent on the expression of the sulfotransferase SULT1A1, which activates YC-1 through sulfonation. The contributions of mass spectrometry to the study were: (i) identifying SULT1A1 as the key player in YC-1 response through observing the protein in a cell line with acquired resistance to the small molecule treatment, (ii) corroborating the role of SULT1A1 in the YC-1 activity by correlating protein expression profiles and drug responses across 37 biliary cancer cell lines, (iii) showing that SULT1A1 expression was associated with IDH mutations, FGFR2 fusion, and BAP1 loss in vivo studying patient-derived xenograft (PDX) models, and (iv) identifying protein targets in a protein enrichment experiment with an immobilized drug. (iii) PDX samples were analyzed using TMT multiplexing on an Orbitrap Fusion mass spectrometer using the SPS-MS3 method. Prior to analysis, samples were fractionated offline using high pH reversed chromatography (12 fractions per TMT set). Three TMT sets were analyzed (ShiBardeesy_PDX_TMT1, ShiBardeesy_PDX_TMT2, and ShiBardeesy_PDX_TMT3), and samples were labeled as follows with channel (bridge channel, 130c): ShiBardeesy_PDX_TMT1: SS101 (126), MG12 (127c), SS106 (127n), MG62 (128c), MG26 (128n), LCCH13 (129c), LCCH3 (129n), Q12050 (130n). ShiBardeesy_PDX_TMT2: SS102 (126), SS110 (127n), MG34 (128c), MG17 (128n), LCCH4 (129c), MG68 (129n), HBT110 (130n). ShiBardeesy_PDX_TMT3: SS103 (126), MG10 (127n), MG59 (128c), MG25 (128n), LCCH10 (129c), MG73 (129n), HBT211 (130n). (iv) Samples from experiments using immobilized small molecules to determine direct interactors of YC-1 were performed using TMT10-barcoding and the SPS-MS3 method on an Orbitrap Lumos mass spectrometer. No off-line fraction was performed. Samples were grouped into two TMT sets (ShiBardeesy_ImmobilizedDrug_TMT1 and ShiBardeesy_ImmobilizedDrug_TMT2). Channel 131N was used as the bridge channel. Samples were labeled as follows: ShiBardeesy_ImmobilizedDrug_TMT1: immobilized_inactiveYC-1_rep_1 (126), immobilized_inactiveYC-1_rep_2 (128n), immobilized_inactiveYC-1_rep_3 (128c), immobilized_YC-1_rep_1 (129n), immobilized_YC-1_plus_soluble_YC-1_competitor_rep_1 (130c). ShiBardeesy_ImmobilizedDrug_TMT2: immobilized_YC-1_rep_2 (127n), immobilized_YC-1_plus_soluble_YC-1_competitor_rep_2 (128n), immobilized_YC-1_plus_soluble_YC-1_competitor_rep_3 (129c), immobilized_YC-1_rep_3 (130c).

Project description:The transplanted mature hepatocytes were found to dedifferentiate into hepatic progenitor cells (HPCs), which proliferate and then convert back to mature state at the completion of liver repopulation. The combination of two small molecules Y-27632 (Y, Rock inhibitor) and CHIR99021 (C, Wnt agonist) could convert mouse primary hepatocytes into HPCs, which could be passaged for more than 30 passages in vitro. Moreover, YC could stimulate the proliferation of transplanted hepatocytes in Fah-/- liver by promoting the conversion into HPCs. Netarsudil (N) and LY2090314 (L), two clinically used drugs which target the same pathways as YC, could also promote hepatocytes proliferation in vitro and in vivo, by facilitating HPC conversion.

Project description:The small molecule YC-1 was identified as identified as a selectively active agent against subsets of the two major live cancer subtypes, intrahepatic cholangiocarcinoma and hepatocellular carcinoma. Response to YC-1 is dependent on the expression of the sulfotransferase SULT1A1, which activates YC-1 through sulfonation. The contributions of mass spectrometry to the study were: (i) identifying SULT1A1 as the key player in YC-1 response through observing the protein in a cell line with acquired resistance to the small molecule treatment, (ii) corroborating the role of SULT1A1 in the YC-1 activity by correlating protein expression profiles and drug responses across 37 biliary cancer cell lines, (iii) showing that SULT1A1 expression was associated with IDH mutations, FGFR2 fusion, and BAP1 loss in vivo studying patient-derived xenograft (PDX) models, and (iv) identifying protein targets in a protein enrichment experiment with an immobilized drug. (i) and (ii): Cell line samples from datasets (i) and (ii) were analyzed together in a set of 12 TMT sets (ShiBardeesy_CellLines_TMT1 to TMT12) using TMT11-barcoding. The samples were analyzed on an Orbitrap Lumos mass spectrometer using the SPS-MS3 method. Prior to analysis, samples were fractionated offline using high pH reversed chromatography (12 fractions per TMT set). Across all TMT sets, channel 131c was used as the bridge channel (pooled digests of all samples). Samples were labeled as follows (rep = replicate: (i) Cell lines samples with acquired resistance to YC-1 treatment: ShiBardeesy_CellLines_TMT1: RBE_rep_1 (126), RBE YC1 Resistant 6_rep_1 (129c). ShiBardeesy_CellLines_TMT2: RBE YC1 Resistant 3_rep_1 (129n), RBE YC1 Resistant 1_rep_1 (130n). ShiBardeesy_CellLines_TMT3: RBE YC1 Resistant 2_rep_1 (126), RBE YC1 Resistant 5_rep_1 (130c). ShiBardeesy_CellLines_TMT4: RBE YC1 Resistant 4_rep_1 (126). ShiBardeesy_CellLines_TMT5: RBE YC1 Resistant 1_rep_2 (127n), RBE YC1 Resistant 4_rep_2 (128c), RBE YC1 Resistant 3_rep_2 (130c). ShiBardeesy_CellLines_TMT6: RBE YC1 Resistant 2_rep_2 (126), RBE YC1 Resistant 6_rep_2 (127c). ShiBardeesy_CellLines_TMT7: RBE_rep_2 (128n), RBE YC1 Resistant 5_rep_2 (130n). (ii) Proteomes of untreated biliary cell lines (baseline): ShiBardeesy_CellLines_TMT1: RBE_rep_1 (126), GB2_rep_1 (127n), HuCCT1_rep_1 (127c), ECC3_rep_1 (128n), ICC10_rep_1 (128c), KMCH-1_rep_1 (129n), SNU-1196_rep_1 (130n). ShiBardeesy_CellLines_TMT2: ICC13-7_rep_1 (126), ICC8_rep_1 (127n), ICC9_rep_1 (127c), SNU-478_rep_1 (128n), CC-SW-1_rep_1 (128c), CC-LP-1_rep_1 (129c), SSP-25_rep_1 (130c), ICC10-8_rep_1 (131n) ShiBardeesy_CellLines_TMT3: SNU-1079_rep_1 (127n), ICC5_rep_1 (127c), ICC7_rep_1 (128c), COR-L105_rep_1 (129n), ICC17_rep_1 (129c), GBC1_rep_1 (131n). ShiBardeesy_CellLines_TMT4: ICC3_rep_1 (127n), ICC2_rep_1 (127c), ICC106_rep_1 (128n), ICC11_rep_1 (128c), HKGZ-CC_rep_1 (129n), SNU-869_rep_1 (129c), HuH28_rep_1 (130n), ICC12_rep_1 (130c), SNU-308_rep_1 (131n). ShiBardeesy_CellLines_TMT5: ICC2_rep_2 (126), ECC3_rep_2 (127c), GB2_rep_2 (128n), ICC11_rep_2 (129n), ICC7_rep_2 (129c), SNU-869_rep_2 (130n), SSP-25_rep_2 (131n). ShiBardeesy_CellLines_TMT6: CC-LP-1_rep_2 (127n), COR-L105_rep_2 (128n), HuCCT1_rep_2 (129n), ICC12_rep_2 (129c), ICC3_rep_2 (131n), ICC5_rep_2 (130n), SNU-478_rep_2 (130c). ShiBardeesy_CellLines_TMT7: ICC10_rep_2 (126), ICC10-6_rep_2 (127n), ICC10-8_rep_2 (127c), RBE_rep_2 (128n), ICC9_rep_2 (128c), ICC17_rep_2 (129n), ICC8_rep_2 (129c), CC-SW-1_rep_2 (130c), GBC1_rep_2 (131n). ShiBardeesy_CellLines_TMT8: ICC13-7_rep_2 (127c), HuH28_rep_2 (128n), HKGZ-CC_rep_2 (128c), SNU-1079_rep_2 (129n), KMCH-1_rep_2 (129c), SNU-1196_rep_2 (130n), SNU-308_rep_2 (131n). ShiBardeesy_CellLines_TMT9: SG231_rep_1 (126), KKU-100_rep_1 (127n), YSCCC_rep_1 (127c), ICC4_rep_1 (128n), TKKK_rep_1 (128c), ECC2_rep_1 (129n), KKU-M213/M214 (129c). ShiBardeesy_CellLines_TMT10: YSCCC_rep_2 (126), KKU-M213/M214_rep_2 (127n), SG231_rep_2 (127c), TKKK_rep_2 (129n), ECC2_rep_2 (129c), ICC4_rep_2 (130n), KKU-100_rep_2 (131n). ShiBardeesy_CellLines_TMT11: ICC13-7_rep_1 (129n). ShiBardeesy_CellLines_TMT12: ICC13-7_rep2 (131n)

Project description:The deubiquitinating enzyme BAP1 is a tumour suppressor, amongst others involved in cholangiocarcinoma. BAP1 has many proposed molecular targets, while its Drosophila homolog is known to deubiquitinate Histone H2AK119. Here, we mutate BAP1 by CRISPR/Cas9 in normal human liver organoids. We find that BAP1 controls the expression of junctional/cytoskeleton components by regulating chromatin accessibility. Consequently, we observe loss of multiple epithelial characteristics, while motility increases. Importantly, restoring the catalytic activity of BAP1 in the nucleus rescues these cellular and molecular changes. We engineer human liver organoids to combine four common cholangiocarcinoma mutations (TP53, PTEN, SMAD4, NF1). In this genetic background, BAP1 loss results in acquisition of malignant features upon xenotransplantation. Thus, control of epithelial identity through the regulation of chromatin accessibility appears a key aspect of BAP1’s tumour suppressor function. Organoid technology combined with CRISPR/Cas9 provides an experimental platform for mechanistic studies of cancer gene function in a human context.

Project description:The increasing prevalence of obesity and related metabolic disorders represents a growing public health concern. Despite advances in other areas of medicine, a safe and effective drug treatment for obesity has been elusive. Obesity has repeatedly been linked to reorganization of the gut microbiome 1-4 , yet to this point obesity therapeutics have been targeted exclusively toward the human host. Here we show that gut microbe-targeted inhibition of the metaorganismal trimethylamine N-oxide (TMAO) pathway protects mice against the metabolic disturbances associated with diet-induced obesity (DIO) or leptin deficiency (ob/ob). Selective small molecule inhibition of the gut microbial enzyme choline TMA-lyase (CutC) does not significantly reduce food intake, but instead is associated with beneficial remodeling of the gut microbiome, improvement in glucose tolerance, and enhanced energy expenditure. Leveraging untargeted metabolomics we discovered that CutC inhibition is associated with reorganization of host circadian control of both phosphatidylcholine and energy metabolism. Collectively, this study underscores the close relationship between microbe and host metabolism, and provides evidence that gut microbe-derived trimethylamine (TMA) is a key regulator of the host circadian clock. This work also demonstrates that gut microbe-targeted enzyme inhibitors can have profound effects on host energy metabolism, and have untapped potential as anti-obesity therapeutics.

Project description:Here we analyzed mouse and human samples to characterize origin, subtypes, functions and cell-cell interactions of cancer-associated fibroblasts in cholangiocarcinoma, a highly desmoplastic tumor of the liver. Hepatic stellate cell-derived cancer-associated fibroblasts were isolated from two different models of murine intrahepatic cholangiocarcinoma, induced by overexpression of YAP+AKT or KRASG12D in combination with sg-p19, and compared by bulk RNA-sequencing to hepatic stellate cells from two models of liver fibrosis, induced by bile duct ligation or DDC diet. CAF-enriched fractions of from YAP+AKT or KRAS/sg-p19-induced intrahepatic cholangiocarcinoma, were analyzed by single-cell RNA sequencing. A cell suspension from human cholangiocarcinoma, containing all cell populations, was analyzed by single cell RNA-sequencing.

Project description:Single-cell transcriptomic profiling of liver cancer biospecimens from hepatocellular carcinoma and intrahepatic cholangiocarcinoma patients.

Project description:Single-cell transcriptome profiling of liver cancer biospecimens from nine hepatocellular carcinoma and ten intrahepatic cholangiocarcinoma patients.

Project description:A quantitative proteomics study, using iTRAQ, to identify liver protein expression changes in a hamster model of cholangiocarcinoma.

Project description:Phytosulfokine (PSK) is a plant peptide hormone that contributes to plant signaling and induced various of effects, including growth, senescence, stress tolerant and defense responses. PSK is a pentapeptide with two tyrosine sulfated by tyrosylprotein sulfotransferase (TPST) enzyme. The sulfated PSK can bind to its cell surface receptors, but the transcriptional readouts remain largely unknown. Here, we treated tpst mutant that are unable to produce native sulfated PSK with synthetic active PSK to capture concentration-sensitive readouts of PSK signaling.