Project description:Melanoma recurrence frequently occurs after a latency period of several years. In vivo studies demonstrated that tumor cells overcoming latency show a T cell-edited phenotype, suggesting a relevant role for CD8+ T cells in maintaining metastatic latency. Here, in a patient model of multiple recurrent lesions, we illustrate the genetic evolution of poorly immunogenic melanoma phenotypes, evolving in the presence of autologous tumor antigen-specific CD8+ T cells. Melanoma cells from two of three late recurrent metastases, developing within a 6-year latency period, lacked HLA class I expression. HLA class I-negative tumor cells became clinically apparent 1.5 and 6 years into stage IV disease. Genome profiling by SNP arrays revealed total T-cell resistance in both metastases originating from a shared chromosome 15q alteration and independently acquired focal B2M gene deletions. A third HLA class I-positive lesion developed in year 3 of stage IV disease. By HLA haplotype loss lesion-derived melanoma cells acquired resistance towards dominant T-cell clonotypes targeting early stage III tumor cells. Early disease melanoma cells showed a dedifferentiated MITFnegative phenotype, recently described to be associated with immunosuppression, in contrast to the MITFhigh phenotype of T cell-edited tumor cells from late metastases. In summary, our study demonstrates that tumor recurrences after long-term latency develop towards T-cell resistance by independent genetic events, suggesting a mechanism of T cell-driven genetic evolution of melanoma as a means to evade immune recognition and tumor immunotherapy. Genetic alterations lead to loss of tumor antigen presentation. Cell lines were generated from tumor material, differences in T cell recognition were observed and Affymetrix SNP arrays were performed according to the manufacturer's directions on DNA extracted from the cell lines. SNP analysis of different melanoma cell lines obtained from one melanoma patient (4 cell lines from different metastasis of one patient with matching germline DNA).

Project description:Uveal melanoma (UM) with an inflammatory phenotype, characterized by infiltrating leukocytes and increased human leukocyte antigen (HLA) expression, carry an increased risk of death due to metastases. These tumors shoud be ideal for T-cell based therapies, yet it is not clear why prognostically-infaust tumors have a high HLA expression. We set out to determine whether the level of HLA molecules in UM is associated with other genetic factors, HLA transcriptional regulators, or microenvironmental factors. 28 enucleated UM were used to study HLA class I and II expression, and several regulators of HLA by immunohistochemistry, PCR microarray, qPCR and chromosome SNP-array. Fresh tumor samples of eight primary UM and four metastases were compared to their corresponding xenograft in SCID mice, using a PCR microarray and SNP array. Increased expression levels of HLA class I and II showed no dosage effect of chromosome 6p, but, as expected, were associated with monosomy of chromosome 3. Increased HLA class I and II protein levels were positively associated with their gene expression and with raised levels of the peptide-loading gene TAP1, and HLA transcriptional regulators IRF1, IRF8, CIITA, and NLRC5, revealing a higher transcriptional activity in prognostically-bad tumors. Implantation of fresh human tumor samples into SCID mice led to a loss of infiltrating leukocytes, and to a decreased expression of HLA class I and II genes , and their regulators. Our data provides evidence for a proper functioning HLA regulatory system in UM, offering a target for T-cell based therapies. NB: Here we show the PCR microarray (Illumina array).

Project description:In this comprehensive study, the authors have developed concise models integrating clinical, genomic and transcriptomic features to predict intrinsic resistance to anti-PD1 Immune Checkpoint Blockade (ICB) treatment in individual tumors. It's important to note that their validation was performed in smaller, independent cohorts, constrained by data availability. The authors have developed two Logistic Regression based models for Ipilimumab treated and Ipilimumab naive patients with metastatic melanoma. The main predictive features for the Ipilimumab treated patients are MHC-II HLA, LDH at treatment initiation and the presence of lymph node metastases (LN met), chosen using forward selection methodology. The main predictive features for the Ipilimumab naive patients are tumor heterogeneity, tumor ploidy and tumor purity, chosen using forward selection methodology. Please note that in these models, the output ‘1’ means progressive disease (PD) and ‘0’ means non-PD. The original GitHub repository can be accessed at https://github.com/vanallenlab/schadendorf-pd1

Project description:Various bacterial species are known to colonize human tumors , proliferate within them and modulate immune function, ultimately affecting patient survival and response to treatment. However, it is not known whether intracellular bacterial antigens are presented by HLA-I and HLA-II molecules of tumor cells, and whether potential tumor-presented bacterial-derived antigens may elicit a tumor infiltrating T-cell immune response. Here, we used 16S rRNA gene sequencing and HLA-peptidomics to unbiasedly identify an intracellular bacterial peptide repertoire presented on HLA-I and HLA-II molecules in melanoma tumors. Our microbial analysis of 17 melanoma metastases, derived from 9 patients, revealed 248 and 38 unique HLA-I and HLA-II peptides, respectively, derived from 41 different classified bacterial species. Recurrent bacterial peptides were identified in different tumors. Our study reveals that intra-tumor intracellular bacteria can be presented by tumor cells and elicit immune-reactivity, thus providing insight into how bacteria influence immune system activation and response to therapy.

Project description:We have previously shown that within tumors, recombinant interleukin-2 (rIL-2, Aldesleukin) consistently activates tumor-associated macrophages and up-regulates interferon stimulated genes (ISGs) while inducing minimal migration, activation or proliferation of T-cells. These effects are independent of tumor response to treatment. Here, we prospectively evaluated transcriptional alterations induced by rIL-2 in peripheral blood mononuclear cells (PBMCs) and within melanoma metastases by serially comparing pre- to post-treatment samples in 13 patients. We also compared transcriptional differences among lesions displaying different responsiveness to therapy, focusing on 2 lesions decreasing in size and 2 remaining stable (responding lesions) compared to non-responding ones. As previously described, the effects of rIL-2 were dramatic within PBMC, while effects within the tumor microenvironment were lesion-specific and limited. However, distinct signatures specific to response could be observed in responding lesions pre-treatment that were amplified following rIL-2 administration. These signatures match the functional profile observed in other human or experimental models in which immune-mediated tissue-specific destruction (TSD) occurs underlying a common pathways leading to rejection. Moreover, the signatures observed in pre-treatment lesions were qualitatively similar to those associated with TSD underlining a determinism to immune responsiveness that depends upon the genetic background of the host or the intrinsic genetic makeup of individual tumors. This is the first prospectively collected insight on global transcriptional events occurring during high-dose rIL-2 therapy in melanoma metastases responding to treatment. Evaluated transcriptional alterations induced by rIL-2 in peripheral blood mononuclear cells (PBMCs) (n=34) and within melanoma metastases (n=30) by serially comparing pre- (n=34) to post-treatment (n=30) samples in 13 patients.

Project description:PURPOSE: To assess the role of Apollon in melanoma resistance to intrinsic and extrinsic pathways of apoptosis and to identify strategies to reduce its expression. EXPERIMENTAL DESIGN: Expression of Apollon was assessed in melanoma cell lines and in surgical specimens.Gene expression profiling, mitochondrial depolarization, caspases activation and apoptosis assays were used to test the effect of Apollon silencing, by siRNA, on melanoma response to different anti-tumor agents. Levels of expression of Apollon and melanoma apoptosis were assessed after tumor treatment with the combination of MEK- and mTOR- inhibitors, or of anti-HLA class II mAbs and anti-tumor agents. RESULTS: Melanoma cells constitutively expressed Apollon, in-vitro and in-vivo. Extent of melanoma apoptosis correlated significantly with Apollon downmodulation upon treatment with a MEK inhibitor, a BRAFV600E-specific inhibitor or the nitrosourea fotemustine. Apollon silencing enhanced melanoma apoptosis in response to the cytotoxic drugs camptothecin, celecoxib, fotemustine and temozolomide, to MEK- and BRAFV600E-specific inhibitors, and to soluble or membrane-bound TRAIL. Mechanistically, Apollon silencing in melanoma cells promoted mitochondrial depolarization, caspase-2, -8, -9 and -3 activation and alteration in the expression of genes related to different cellular functions in response to different anti-tumor agents. Treatment of melanoma cells with combination of MEK and of mTOR inhibitors, or of HLA class II antigen-specific mAb and anti-tumor agents, promoted Apollon downmodulation, associated with enhanced apoptotic responses. CONCLUSIONS: The results suggest that Apollon is a relevant molecule in melanoma resistance to apoptosis, and that strategies aimed at downmodulating Apollon protein may improve melanoma cell death in response to anti-tumor agents that trigger the intrinsic or the extrinsic apoptosis pathways.

Project description:Immune checkpoint inhibitor and adoptive lymphocyte transfer-based therapies have shown great therapeutic potential for cancers with high tumor mutation burden (TMB). Here, we employed mass spectrometry (MS)-based proteogenomic large-scale profiling to identify potential immunogenic human leukocyte antigen (HLA) Class ǀ-presented peptides in both melanoma, a “hot tumor” with high TMB, and EGFR mutant lung adenocarcinoma, a “cold tumor” with low TMB. We used cell line and patient-specific databases constructed using variants identified from whole-exome sequencing, as well as a de novo search algorithm from the PEAKS search algorithm to interrogate the mass spectrometry data of the Class I immunopeptidome. We identified 12 mutant neoantigens. Several classes of tumor-associated antigen-derived peptides were also identified. We constructed a cancer germline (CG) antigen database with 285 antigens and identified 42 Class I-presented CG antigens. We identified more than 1000 post-translationally modified (PTM) peptides representing 58 different PTMs. Our results suggest that PTMs play a critical role impacting HLA-binding affinity dramatically. Finally, leveraging de novo search and an annotated lncRNA database, we developed a novel non-canonical peptide discovery pipeline to identify 44 lncRNA-derived peptides that are presented by Class I. We validated MS/MS spectra of select peptides using synthetic peptides and performed HLA Class I binding assays to demonstrate binding of select neo-peptides and lncRNA-derived peptides to Class I proteins. In summary, we provide direct evidence of HLA Class I presentation of a large number of mutant and tumor-associated peptides for potential use as vaccine or adoptive cell therapy in melanoma and EGFR mutant lung cancer.

Project description:PURPOSE: To assess the role of Apollon in melanoma resistance to intrinsic and extrinsic pathways of apoptosis and to identify strategies to reduce its expression. EXPERIMENTAL DESIGN: Expression of Apollon was assessed in melanoma cell lines and in surgical specimens.Gene expression profiling, mitochondrial depolarization, caspases activation and apoptosis assays were used to test the effect of Apollon silencing, by siRNA, on melanoma response to different anti-tumor agents. Levels of expression of Apollon and melanoma apoptosis were assessed after tumor treatment with the combination of MEK- and mTOR- inhibitors, or of anti-HLA class II mAbs and anti-tumor agents. RESULTS: Melanoma cells constitutively expressed Apollon, in-vitro and in-vivo. Extent of melanoma apoptosis correlated significantly with Apollon downmodulation upon treatment with a MEK inhibitor, a BRAFV600E-specific inhibitor or the nitrosourea fotemustine. Apollon silencing enhanced melanoma apoptosis in response to the cytotoxic drugs camptothecin, celecoxib, fotemustine and temozolomide, to MEK- and BRAFV600E-specific inhibitors, and to soluble or membrane-bound TRAIL. Mechanistically, Apollon silencing in melanoma cells promoted mitochondrial depolarization, caspase-2, -8, -9 and -3 activation and alteration in the expression of genes related to different cellular functions in response to different anti-tumor agents. Treatment of melanoma cells with combination of MEK and of mTOR inhibitors, or of HLA class II antigen-specific mAb and anti-tumor agents, promoted Apollon downmodulation, associated with enhanced apoptotic responses. CONCLUSIONS: The results suggest that Apollon is a relevant molecule in melanoma resistance to apoptosis, and that strategies aimed at downmodulating Apollon protein may improve melanoma cell death in response to anti-tumor agents that trigger the intrinsic or the extrinsic apoptosis pathways. The human melanoma cell line Me23682 was established in our laboratory from a surgical specimen. Cells were routinely maintained in RPMI medium 1640 (Lonza, Basel, Switzerland) supplemented with 10% FBS (Lonza) and 2 mM glutamine (Lonza). Cells were maintained at 37°C in a water-saturated atmosphere of 5% CO2 in air. 3x106 cells were seeded in 10 cm dishes; after 24 hours, cells were transfected with Apollon-specific siRNA or its unrelated control (Stealth RNAi siRNA, Invitrogen Life Technologies, Camarillo, CA) at a final concentration of 75 nmol/L and then left untreated or treated with fotemustine (Muphoran, Italfarmaco, Milan, Italy) at 150 umol/L for 6 hours, or with the BRAFV600E-specific inhibitor PLX4720 (Selleck Chemicals, Houston, TX) at 500 nmol/L for 8 hours, or with the MEK inhibitor PD0325901 (Cayman Chemicals, Ann Arbor, MI) at 5 nmol/L for 8 hours. Each treatment or combination was performed in triplicate. At the end of treatment, cells were collected and RNA extracted.

Project description:Numerous case studies have reported spontaneous regression of metastases following tumor excision, but underlying mechanisms are elusive. Here we present a model of metastases regression and latency elicited by the removal of a primary tumor, and identify underlying mechanisms. Human breast cancer cells, expressing highly sensitive luciferase, were implanted into the mammary fat-pad of mice, and the progression of early stage micrometastases, was monitored. Upon establishment of micrometastases, the primary tumor was excised, inducing a robust regression of metastatic signal, resulting in latent foci. In vivo supplementation of tumor secretome immediately upon tumor excision diminished this regression, implicating primary tumor secreted factors in promotion of metastatic growth. In vitro, cancer cell conditioned medium reduced apoptosis and enhanced adhesion of non-confluent cancer cells, and induced angiogenesis in endothelial cells. Cytokine array and proteomic analysis of cancer cells secretome identified 359 extracellular secreted factors, with significant enrichment of angiogenic factors, growth factors activity, focal adhesion, apoptosis, and metalloprotease processes. In vivo blockade of four key potential mediators of these processes, IL-8, PDGFaa, Serpin E1 (PAI-1), and MIF, arrested development of micrometastases. Moreover, high protein levels of these four factors were correlated with poor patient outcome. These results demonstrate regression and latency of metastases following tumor excision and a crucial role for primary tumor secretome in promoting early metastatic stages, suggesting novel mechanisms to control minimal residual disease.

Project description:HLA ligandome analysis of colorectal adenocarcinoma tissues obtained from liver metastases (mCRC) as well as adjacent non-malignant liver tissues was performed to characterize the natural HLA class I and class II presented ligands on both mCRC and adjacent liver tissue.