Project description:Head and neck squamous cell carcinoma (HNSCC) is a deadly and disfiguring disease for which better systemic therapy is desperately needed. The development of new therapies for HNSCC and the understanding of its biology both depend upon clinically relevant animal models. An increasingly promising xenograft model, the patient derived xenograft (PDX), is developed by surgically implanting tumor tissue directly from a patient into an immunocompromised mouse. We transplanted 30 HNSCC primary tumors directly into mice. The histology and stromal components were analyzed using immunohistochemistry. Gene expression analysis with Affymetrix U133A-microarrays was conducted on patient tumors, including third generation and one tenth generation PDX; one PDX-derived cell line; and 2 established HNSCC cell lines. Five of 30 (17%) transplanted tumors could be serially passaged and used for therapeutic and mechanistic studies. One cell line has been established from a tongue primary. The tumors maintained the histologic appearance of the parent tumor although human stromal components were lost upon engraftment. One PDX model was derived from an HPV-positive tumor. From the >54,000 probes tested, there were widespread differences in gene expression between the tumors growing in mice vs. the corresponding human tumors from which they were derived. For genes differing between parent tumors and human cell lines in culture, the PDXs’ expression pattern was very similar to that of the parent tumors. There were also widespread expression differences between the human tumors that subsequently grew in mice vs. those that did not - suggesting that this model enriches for cancers with distinct biological features. Our results demonstrate the feasibility of a PDX model of HNSCC. Gene expression patterns suggest that the PDX more closely recapitulated the parental tumor than do cells in culture. The histology of the tumors in mice is similar to that of the same tumor in humans. Additionally, gene expression patterns and histology are stable over multiple generations.

Project description:This study represents a proteomic resource for HNSCC and SQCLC with quantitative protein expression data for 7800 proteins and provides a proteomic diagnostic signature for classification for undetermined secondary lung tumors in HNSCC patients. By quantitative mass-spectrometry-based proteomics, we characterized a cohort of 63 squamous cell carcinomas of the lung (SQCLC), 49 of the head and neck region (HNSCC) and 51 HNSCC-correlated lung tumors with squamous cell histology that evolved in the course of the disease.

Project description:Osteosarcoma (OS) and Ewing’s sarcoma (EW) are the two most common pediatric solid tumors, after brain tumors. Multimodal treatments have significantly improved prognosis in localized disease but outcome is still poor in metastatic patients, for whom therapeutic options are often inadequate. Preclinical drug testing to identify promising treatment options that match the molecular make-up of these tumors is hampered by the lack of appropriate and molecularly well-characterized patient-derived models. To address this need, a panel of patient-derived xenografts (PDX) was established by subcutaneous implantation of fresh, surgically resected OS and EW tumors in NSG mice. Tumors were re-transplanted to next mice generations and fragments were collected for histopathological and molecular characterization. A model was considered established after observing stable histological and molecular features for at least three passages. To evaluate the similarity of the model with primary tumor, we performed a global gene expression profiling and tissue microarrays (TMA), to assess tumor specific biomarkers on tissues from OS/EW tumors and their PDXs (1st and 3rd passage). Moreover, we verified the feasibility of these models for preclinical drug testing. We implanted 61 OS and 29 EW samples: 14/38 (37%) primary OS and 9/23 (39%) OS lung metastases successfully engrafted; while among EW, 5/26 (19%) primary samples and 1/3 (33%) metastases were established. Comparison between patient samples and PDXs, highlighted that histology and genetic characteristics of PDXs were stable and maintained over passages. In particular, correlative analysis between OS and EW samples and their PDXs was extremely high (Pearson’s r range r=0.94-0.96), while patient-derived primary cultures displayed reduced correlation with human samples (r=0.90-0.93), indicating that in vitro adaptation superimpose molecular alterations that create genetic diversion from original tumors. No significant differentially expressed gene profile was observed from the comparison between EW samples and PDXs (fold change > 2, adjusted p <0.05 at paired t-test). In OS, the comparison between OS patient-derived tumors and PDX indicated differences in 397 genes, mostly belonging to immune system functional category. This is in line with the idea that human immune cells are gradually replaced by murine counterparts upon engraftment in the mouse. As proof-of concept, two EW PDX and one OS PDX have been treated with conventional and innovated drugs to test their value in terms of drug-sensitivity prediction. Overall, our study indicated that PDX models maintained the histological and genetic markers of the tumor samples and represent reliable models to test sensitivity to novel drug associations.

Project description:Mass spectrometry profiling of orthotopically transplanted breast cancer patient-derived xenograft (PDX) tumors prior to chemotherapy treatment.

Project description:Personalized cancer immunotherapy targeting patient-specific cancer/testis (CTA) antigens and neoantigens may benefit from large-scale tumor HLA peptidome (immunopeptidome) analysis, which aims to accurately identify antigens presented by tumor cells. While significant efforts have been invested in analyzing the HLA peptidomes of fresh tumors, it is often impossible to obtain sufficient volumes of tumor tissues for comprehensive HLA peptidome characterization. This work attempted to overcome some of these obstacles by using patient-derived xenograft tumors (PDX) in mice as the tissue sources for HLA peptidome analysis. PDX tumor provide a proxy for expansion of the patient tumor by re-grafting them through several passages to immune compromised mice. The HLA peptidomes of human biopsies were compared to those derived from PDX tumors. Larger HLA peptidomes were obtained from the significantly larger PDX tumors as compared to the patient biopsies. The HLA peptidomes of different PDX tumors derived from the same source tumor biopsy were very reproducible, even following subsequent passages to new naïve mice. A large number of CTA-derived HLA peptides were discovered, as well as several neoantigens. Taken together, use of PDX tumors for HLA peptidome analysis serves as a highly expandable and stable source of reproducible and authentic peptidomes, opening up new opportunities for defining large HLA peptidomes when only small tumor biopsies are available. This approach provides a large source for tumor antigens identification potentially useful for personalized immunotherapy.

Project description:ABSTRACT Two major subgroups of head and neck squamous cell carcinomas (HNSCC) are currently distinguished based on etiology and pattern of genetic alterations; tumors with biologically active human papillomavirus (HPV) and tumors without. It is at present unclear whether additional genetically distinct subgroups exist within HPV-negative HNSCC. Aim of this study is to genetically classify HNSCC without HPV involvement and to correlate the genetically defined classes to tumor and patient characteristics. By means of array comparative genomic hybridization (aCGH) we determined DNA copy number variation in thirty-nine HPV-negative, but further unselected HNSCC. Unsupervised analysis of aCGH data distinguished two genetic groups in HPV-negative HNSCC, one characterized by a low level of chromosomal alterations (N=9), and another by a high level of chromosomal alterations (N=30). Absence of chromosomal aberrations was significantly associated with wild-type TP53, a low level of alcohol consumption, a female gender and a better prognosis. The tumors were negative for microsatellite instability. The discovery of this new class of HNSCC with unique genetic and clinical characteristics has important consequences for future basic and clinical studies. All DNAs are isolated from fresh frozen HNSCC specimen. All tissue specimens were microdissected to obtain at least 90% tumor DNA. All sampels are hybridized against a pool of reference DNA of normal individuals of the opposite gender.

Project description:Current classification of head and neck squamous cell carcinomas (HNSCC) based on anatomic site and clinical stage fails to capture biologic heterogeneity or adequately inform treatment. Here we use consensus clustering on 371 HNSCC in three cohorts, including a new cohort of 134 patients with locoregionally advanced HNSCC and 43% HPV(+) tumors to identify five HNSCC subtypes. Subtypes closely correlate with biologic processes (hypoxia, cytotoxic T-cell infiltration, copy number changes, EGFR/HER-ligand phenotype), survival, and HPV-status. Two biologically distinct HPV-associated subtypes are identified. Gene modules of candidate drivers characterize each subtype using the CONEXIC algorithm. The proposed 5-subtype classification provides a biologic basis for future clinical and preclinical studies and lays the groundwork for improved prognostication and therapy development in HNSCC. We use consensus clustering on 371 HNSCC in three cohorts, including a new cohort of 134 patients with locoregionally advanced HNSCC and 43% HPV(+) tumors to identify five HNSCC subtypes.

Project description:Cancer stem cells (CSCs) comprise a small subpopulation of undifferentiated cancer cells with the ability to self-renew and give rise to the heterogeneous cancer cell lineages that form tumorous masses. Thus, tumor eradication may be greatly improved by specifically targeting CSCs, as they exhibit resistance to conventional therapy. To gain insight into the unique biology of CSCs, we developed patient-derived xenograft (PDX) tumors from ER-negative breast cancer patient tissue from which we isolated mammospheres, a method known to enrich for cells with CSC-properties. An unbiased, comparative global proteomic analysis using label-free mass spectrometry was performed on the patient tumor tissues and corresponding PDX tumors and mammospheres. Good concordance between the proteome profiles of patient tumor tissue and corresponding PDX tumors was observed. However, lower abundance of immune- and extracellular matrix-related proteins and higher abundance of proteins associated with cell-to-cell adhesion including desmosome proteins and β-catenin were observed in PDX versus patient tumors. Interestingly, analysis of proteins elevated in mammospheres vs. PDX tumors identified an enrichment of proteins associated with de novo cholesterol synthesis. The clinical relevance of increased cholesterol biosynthesis protein expression was verified in a large gene expression data set of clinical breast cancers showing correlation with shorter relapse-free survival. RNA interference and chemical inhibition of the cholesterol biosynthesis pathway reduced mammosphere formation and growth of CSCs derived from PDX tumors and cancer cell lines. Our findings identify the cholesterol biosynthesis pathway as central for CSC growth and a potential therapeutic target for CSC as well as providing an additional mechanistic explanation for the observed benefit of statins in breast cancer treatment.

Project description:Oncogene expressing human papillomavirus type 16 (HPV16) is found in a subset of head and neck squamous cell carcinomas (HNSCC). HPV16 drives carcinogenesis by inactivating p53 and pRb with the viral oncoproteins E6 and E7, reflected by a low level of mutations in TP53 and allelic loss at 3p, 9p and 17p, genetic changes frequently found in HNSCCs of non-viral etiology. We hypothesize that two pathways to HNSCC exist: one determined by HPV16 and one by environmental carcinogens. To define the critical genetic events in these two pathways, we now present a detailed genome analysis of HNSCC with and without HPV16 involvement by employing high resolution micro-array comparative genomic hybridization. Four regions showed alterations in HPV-negative tumors that were absent in HPV-positive tumors: losses at 3p11.2-26.3, 5q11.2-35.2, 9p21.1-24, and gains/amplifications at 11q12.1-13.4. Also, HPV16-negative tumors demonstrated loss at 18q12.1-23, in contrast to gain in HPV16-positive tumors. Seven regions were altered at high frequency (>33%) in both groups: gains at 3q22.2-qter, 5p15.2-pter, 8p11.2-qter, 9q22-34.1, 20p-20q and losses at 11q14.1-qter and 13q11-33. These data show that HNSCC arising by environmental carcinogens are characterized by genetic alterations that differ from those observed in HPV16-induced HNSCC, and most likely occur early in carcinogenesis. A number of genetic changes are shared in both tumor groups and can be considered crucial in the later stages of HNSCC progression. Tumor DNA is isolated from fresh frozen tissue. Tumor DNA is enriched by microdissection. Reference DNA is isolated from blood of normal individuals of the opposit gender.

Project description:The patient-derived xenograft (PDX) model retains the heterogeneity of patient tumors, allowing a means to not only examine efficacy of a therapy across a population, but also study crucial aspects of cancer biology in response to treatment. Herein we describe the development and characterization of an ovarian-PDX model in order to study the development of chemoresistance. We demonstrate that PDX tumors are not simply composed of tumor-initiating cells, but recapitulate the original tumor’s heterogeneity, oncogene expression profiles, and clinical response to chemotherapy. Combined carboplatin/paclitaxel treatment of PDX tumors enriches the cancer stem cell populations, but persistent tumors are not entirely composed of these populations. RNA-Seq analysis of treated PDX tumors compared to untreated tumors demonstrates a consistently contrasting genetic profile after therapy, suggesting similar, but few, pathways are mediating chemoresistance. The pathways most significantly altered included Protein Kinase A signaling, GNRH signaling, and sphingosine-1-phosphate signaling. Pathways and genes identified by this methodology represent novel approaches to targeting the chemoresistant population in ovarian cancer 6 pairs of Patient-Derived Xenografts (PDX) were ananlyzed using RNA-seq for a total of 12 samples. Each pair consists of a treated and untreated PDX of ovarian cancer. Treated Ovarian cancer PDXs were treated with 4 weeks of a combination of carboplatin and taxol. RNA was isolated and converted to cDNA. RNA-seq was conductred on the Illumina HiSeq 2000 with 50 bp paired end sequencing