Project description:High-grade serous ovarian cancer (HGSC), the principal cause of death from gynecological malignancies in the world, has not significantly benefited from advances in cancer immunotherapy. Although HGSC infiltration by lymphocytes correlates with superior survival, the nature of antigens that can elicit anti-HGSC immune responses is unknown. The goal of this study was to establish the global landscape of HGSC tumor-specific antigens (TSAs) using a mass spectrometry pipeline that interrogated all reading frames of all genomic regions. In 23 HGSC tumors, we identified 103 TSAs. Classic TSA discovery approaches focusing only on mutated exonic sequences would have uncovered only three of these TSAs. Other mutated TSAs resulted from out-of-frame exonic translation (n=2) or from noncoding sequences (n=7). One group of TSAs (n=91) derived from aberrantly expressed unmutated genomic sequences, which were not expressed in normal tissues. These aberrantly expressed TSAs (aeTSAs) originated primarily from non-exonic sequences, in particular intronic (29%) and intergenic (22%) sequences. Their expression was regulated at the transcriptional level by variations in gene copy number and DNA methylation. Although mutated TSAs were unique to individual tumors, aeTSAs were shared by a large proportion of HGSCs. Taking into account the frequency of aeTSA expression and HLA allele frequencies, we calculated that, in Caucasians, the median number of aeTSAs per tumor would be five. We conclude that, in view of their number and the fact that they are shared by many tumors, aeTSAs may be the most attractive targets for HGSC immunotherapy.

Project description:MHC I-associated peptides (MAPs) presented at the surface of nucleated cells play a central role in CD8 T-cell immunosurveillance. MAPs presented by mature (i.e. MHC IIhi) medullary thymic epithelial cells (mTEChi) are essential to eliminate self-reactive CD8 T cells in a process called central tolerance. On tumor cells, MAPs that do not induce tolerance (i.e. non-tolerogenic MAPs), because absent from mTEChi or any other normal cells, are referred to as tumor-specific antigens (TSAs). Despite their clinical relevance, very few have been identified, even in highly mutated tumor types. Thus, we developed a novel proteogenomic workflow able to characterize the full TSA landscape of any tumor. Briefly, using RNA-seq data, we subtracted the mTEChi from the tumor signal to generate tumor-specific protein databases enriched in non-tolerogenic sequences. Using these databases to analyze the MAP repertoire of two murine cell lines (CT26 and EL4) sequenced by mass spectrometry, we identified a total of 21 TSAs, 90% of which derived from allegedly non-coding regions. Interestingly, our results highlighted that 70% of those TSAs derived from non-mutated yet tumor-restricted sequences, e.g. endogenous retroelements. Moreover, we showed that our approach is easily amenable to analyze human primary samples as we were able to identify TSAs in three lung tumor biopsies and four B-ALL specimens. Focusing on 5 TSAs, we demonstrated that both TSA expression and TSA-specific T-cell frequency in the pre-immune repertoire influenced the overall survival of pre-immunized tumor-bearing mice. In conclusion, this proof-of-concept study demonstrates that non-coding-derived TSAs are frequent and protective in vivo, while they could be shared by several individuals. Altogether, our findings will help expand the repertoire of human TSAs and facilitate their prioritization in the clinic.

Project description:MHC I-associated peptides (MAPs) presented at the surface of nucleated cells play a central role in CD8 T-cell immunosurveillance. MAPs presented by mature (i.e. MHC IIhi) medullary thymic epithelial cells (mTEChi) are essential to eliminate self-reactive CD8 T cells in a process called central tolerance. On tumor cells, MAPs that do not induce tolerance (i.e. non-tolerogenic MAPs), because absent from mTEChi or any other normal cells, are referred to as tumor-specific antigens (TSAs). Despite their clinical relevance, very few have been identified, even in highly mutated tumor types. Thus, we developed a novel proteogenomic workflow able to characterize the full TSA landscape of any tumor. Briefly, using RNA-seq data, we subtracted the mTEChi from the tumor signal to generate tumor-specific protein databases enriched in non-tolerogenic sequences. Using these databases to analyze the MAP repertoire of two murine cell lines (CT26 and EL4) sequenced by mass spectrometry, we identified a total of 21 TSAs, 90% of which derived from allegedly non-coding regions. Interestingly, our results highlighted that 70% of those TSAs derived from non-mutated yet tumor-restricted sequences, e.g. endogenous retroelements. Moreover, we showed that our approach is easily amenable to analyze human primary samples as we were able to identify TSAs in three lung tumor biopsies and four B-ALL specimens. Focusing on 5 TSAs, we demonstrated that both TSA expression and TSA-specific T-cell frequency in the pre-immune repertoire influenced the overall survival of pre-immunized tumor-bearing mice. In conclusion, this proof-of-concept study demonstrates that non-coding-derived TSAs are frequent and protective in vivo, while they could be shared by several individuals. Altogether, our findings will help expand the repertoire of human TSAs and facilitate their prioritization in the clinic.

Project description:MHC I-associated peptides (MAPs) presented at the surface of nucleated cells play a central role in CD8 T-cell immunosurveillance. MAPs presented by mature (i.e. MHC IIhi) medullary thymic epithelial cells (mTEChi) are essential to eliminate self-reactive CD8 T cells in a process called central tolerance. On tumor cells, MAPs that do not induce tolerance (i.e. non-tolerogenic MAPs), because absent from mTEChi or any other normal cells, are referred to as tumor-specific antigens (TSAs). Despite their clinical relevance, very few have been identified, even in highly mutated tumor types. Thus, we developed a novel proteogenomic workflow able to characterize the full TSA landscape of any tumor. Briefly, using RNA-seq data, we subtracted the mTEChi from the tumor signal to generate tumor-specific protein databases enriched in non-tolerogenic sequences. Using these databases to analyze the MAP repertoire of two murine cell lines (CT26 and EL4) sequenced by mass spectrometry, we identified a total of 21 TSAs, 90% of which derived from allegedly non-coding regions. Interestingly, our results highlighted that 70% of those TSAs derived from non-mutated yet tumor-restricted sequences, e.g. endogenous retroelements. Moreover, we showed that our approach is easily amenable to analyze human primary samples as we were able to identify TSAs in three lung tumor biopsies and four B-ALL specimens. Focusing on 5 TSAs, we demonstrated that both TSA expression and TSA-specific T-cell frequency in the pre-immune repertoire influenced the overall survival of pre-immunized tumor-bearing mice. In conclusion, this proof-of-concept study demonstrates that non-coding-derived TSAs are frequent and protective in vivo, while they could be shared by several individuals. Altogether, our findings will help expand the repertoire of human TSAs and facilitate their prioritization in the clinic.

Project description:Identification of K-Ras and B-Raf mutations in colorectal cancer (CRC) is essential to predict patients' response to anti-EGFR therapy and formulate appropriate therapeutic strategies to improve prognosis and survival. Here, we combined parallel reaction monitoring (PRM) with high-field asymmetric waveform ion mobility (FAIMS) to enhance mass spectrometry sensitivity and improve the identification of low-abundance K-Ras and B-Raf mutations in biological samples without immunoaffinity enrichment. In targeted LC-MS/MS analyses, FAIMS reduced the occurrence of interfering ions and enhanced precursor ion purity, resulting in a three-fold improvement in the detection limit for K-Ras and B-Raf mutated peptides. In addition, ion mobility separation of isomeric peptides using FAIMS facilitated the unambiguous identification of K-Ras G12D and G13D peptides. The application of targeted LC-MS/MS analyses using FAIMS is demonstrated for the detection and quantitation of B-Raf V600E, K-Ras G12D, G13D, and G12V in CRC cell lines and primary specimens.

Project description:Rat has been treated with different compounds with the purpose of investigating toxicological mechanisms. But toxic and non-toxic compounds has been administered. 3 toxic (ANIT, DMN, NMF) 3 non-tox (Caerulein, dinitrophenol(DNP), Rosiglitazone) in 5-plicates (30 arrays in all) and 9 untreated (control), 39 samples in all. The array data was used to identify genes with biomarker potential for detecting toxic properties of compounds. Keywords: other Rats was treated with different compounds and RNA from liver was extracyed after 48 hours. Microarrays (GeneChip Rat230 version 2) was run on the RNA

Project description:Glycolysis is the core metabolic pathway supplying energy to cells. Whereas the vast majority of studies focus on specific aspects of the process, global analyses characterizing simultaneously all enzymes involved in the process are scarce. Here we demonstrate that quantitative label- and standard-free proteomics allows accurate determination of titers of metabolic enzymes and enables simultaneous measurements of titers and maximal enzymatic activities (Amax)c of all glycolytic enzymes and the gluconeogenic fructose 1,6-bisphosphatase in mouse brain, liver and muscle. Despite occurrence of tissue-specific isoenzymes bearing different kinetic properties, the enzyme titers often correlated well with the Amax values. To provide a more general picture of energy metabolism we analyzed titers of the enzymes in additional 7 mouse organs and in human cells. Across the analyzed samples we identified two basic profiles: a 'fast glucose uptake' one in brain and heart, and a 'gluconeogenic rich' one occurring in liver. In skeletal muscles and other organs, we found intermediate profiles. Obtained data highlighted the glucose-flux-limiting role of hexokinase which activity was always 10-100-fold lower than the average activity of all other glycolytic enzymes. A parallel determination of enzyme titers and maximal enzymatic activities allowed determination of kcat values without enzyme purification. Results of our in-depth proteomic analysis of the mouse organs did not support the concepts of regulation of glycolysis by lysine acetylation.

Project description:mRNA array analysis was carried out using total RNA of skin biopsies from lesional and non-lesional skin of three atopic dermatitits patients and four healthy individuals.

Project description:Purpose: Tumor-specific antigens (TSAs) represent ideal targets for cancer immunotherapy, but very few of them have been identified. Therefore, the goal of this study was to develop a novel approach, combining RNA-Sequencing and mass spectrometry, to enlarge the landscape of actionable TSAs in seven human primary samples, namely 4 B-ALL and 3 lung tumor biopsies. Methods: We performed RNA-Sequencing on each primary tumor sample (unreplicated) with the Illumina HiSeq2000. Using those RNA-Sequencing data to build a global cancer database for each sample, we performed a transcriptomic-informed mass spectrometry analysis of their MHC I-associated peptides to identify TSAs. Results: We identified a total of 30 TSAs, 90% of which derived from allegedly non-coding regions and would have been missed by standard approaches. Moreover, most of these TSAs derived from non-mutated yet cancer-restricted transcripts that can be shared by multiple tumors. Conclusions: In conclusion, the strategy reported herein is readily applicable to human tumors and should considerably enlarge the landscape of actionable TSAs.

Project description:Purpose: Tumor-specific antigens (TSAs) represent ideal targets for cancer immunotherapy, but very few of them have been identified. Therefore, the goal of this study was to develop a novel approach, combining RNA-Sequencing and mass spectrometry, to enlarge the landscape of actionable TSAs in seven human primary samples, namely 4 B-ALL and 3 lung tumor biopsies.  Methods: We performed RNA-Sequencing on each primary tumor sample (unreplicated) with the Illumina HiSeq200. Using those RNA-Sequencing data to build a global cancer database for each sample, we performed a transcriptomic-informed mass spectrometry analysis of their MHC I-associated peptides to identify TSAs. Results: We identified a total of 30 TSAs, 90% of which derived from allegedly non-coding regions and would have been missed by standard approaches. Moreover, most of these TSAs derived from non-mutated yet cancer-restricted transcripts that can be shared by multiple tumors. Conclusions: In conclusion, the strategy reported herein is readily applicable to human tumors and should considerably enlarge the landscape of actionable TSAs.