Project description:Protein Kinase C alpha (PKC) is a critical mediator of cell signaling and cancer growth. We show that PKC inhibitors decrease proliferation in squamous cell carcinoma of the head and neck (SCCHN) cells and abrogate growth of SCCHN tumors in mouse xenografts. Analysis of gene expression arrays reveals that PKC regulates cell cycle genes required for DNA synthesis. In particular, PKC increases cyclin E protein expression, cyclinE/cdk2 complex formation, and transcription of cyclin E and E2F target genes. Consistent with this mechanism, expression of cyclin E rescues the block in DNA synthesis caused by PKC inhibition. In SCCHN tissue, PKC and cyclin E expression increase progressively from normal and dysplastic to malignant human head and neck tissue. Furthermore, PKC  expression correlates with poor prognosis in SCCHN. These results demonstrate that PKC regulates growth by stimulating DNA synthesis through cyclin E and E2F and identify PKC as a therapeutic target that is highly expressed in aggressive SCCHN. Keywords: time course; dose response

Project description:Protein Kinase C alpha (PKC) is associated with progression and poor prognosis in head and neck cancer. Previous studies have demonstrated that PKC sustains the proliferative signal by increasing cyclin E expression, leading to enhanced E2F target gene transcription and DNA synthesis. Here we show that PKC increases DNA synthesis through inhibition of the microRNA, miR-15a, upregulating translation of its target cyclin E. Importantly, gene expression and qRT-PCR analysis of primary squamous cell carcinoma tumors of the head and neck (SCCHN) reveals a significant negative correlation between PKC and miR-15a levels. In contrast to normal cell cycle initiation, PKC decreases microRNA expression, leading first to increased cyclin E protein followed by enhanced transcription of cyclin E and other DNA synthesis mediators. These results identify a signaling network regulated by PKC whereby constitutive kinase activation switches the system to feed forward, overriding normal regulation of cell cycle progression through a post-transcriptional mechanism involving microRNAs. This reprogramming of the network is likely a more general phenomenon that can account for the oncogenic potency of established signaling pathways. Keywords: miRNA; dose response; cancer 6 treated samples across two time points hybridized to paired time 0, untreated controls

Project description:Protein Kinase C alpha (PKC) is associated with progression and poor prognosis in head and neck cancer. Previous studies have demonstrated that PKC sustains the proliferative signal by increasing cyclin E expression, leading to enhanced E2F target gene transcription and DNA synthesis. Here we show that PKC increases DNA synthesis through inhibition of the microRNA, miR-15a, upregulating translation of its target cyclin E. Importantly, gene expression and qRT-PCR analysis of primary squamous cell carcinoma tumors of the head and neck (SCCHN) reveals a significant negative correlation between PKC alpha and miR-15a levels. In contrast to normal cell cycle initiation, PKC decreases microRNA expression, leading first to increased cyclin E protein followed by enhanced transcription of cyclin E and other DNA synthesis mediators. These results identify a signaling network regulated by PKC whereby constitutive kinase activation switches the system to feed forward, overriding normal regulation of cell cycle progression through a post-transcriptional mechanism involving microRNAs. This reprogramming of the network is likely a more general phenomenon that can account for the oncogenic potency of established signaling pathways. Keywords: miRNA; dose response; cancer

Project description:Quantitative (iTRAQ 4-plex) proteomic analysis of progressive head and neck cancers

Project description:Sage performed on microdissection of Head and Neck tumor, and Head and Neck normal tissue comparative analysis of gene expression profiles of head and neck squamous cell carcinoma and Head and Neck normal tissue

Project description:Sage performed on microdissection of Head and Neck tumor, and Head and Neck normal tissue

Project description:This SuperSeries is composed of the following subset Series: GSE11929: Identification of a subgroup of head and neck cancers lacking numerical chromosomal aberrations GSE11931: Copy Number Alterations in HNSCC with or without Oncogene Expressing Human Papillomavirus Refer to individual Series

Project description:Head and neck cancer is a hetergeneous disease. Based on previoulsy defined molecular subtypes we associated gene expression with response to different compounds. We used microarry gene expression for molecular subtyping Cetuximab is the single targeted therapy approved for the treatment of head and neck cancer (SCCHN). Predictive biomarkers have not been established in the clinical setting and patient stratification based on molecular tumor profiles has not been possible. Since EGFR pathway activation is pronounced in basal subtype, we hypothesized this activation could be a predictive signature for an EGFR directed treatment. From our patient derived xenograft platform of head and neck cancer, 28 models were subjected to Affymetrix gene expression studies on HG U133+ 2.0. Based on the expression of 821 genes, the subtype of each of the 28 models was determined by integrating gene expression profiles through centroid-clustering with previously published gene expression data by Keck et al.,CCR 2015. Response was evaluated by comparing tumor volume at treatment initiation and after three weeks of treatment (RTV).

Project description:The differential diagnosis between head & neck squamous cell carcinomas and lung squamous cell carcinomas is often unresolved because the histologic appearance of these two tumor types is similar. In the development of a gene expression profile test (GEP-HN-LS) that distinguishes these 2 cancer types, a collection of poorly differentiated primary and metastatic tumor specimens were used. Here we describe 76 such tumor specimens that were used for validation of GEP-HN-LS. The specimens are either head & neck squamous cell carcinomas or lung squamous cell carcinomas.

Project description:The differential diagnosis between head & neck squamous cell carcinomas and lung squamous cell carcinomas is often unresolved because the histologic appearance of these two tumor types is similar. In the development of a gene expression profile test (GEP-HN-LS) that distinguishes these 2 cancer types, a collection of poorly differentiated primary and metastatic tumor specimens were used. Here we describe 76 such tumor specimens that were used for validation of GEP-HN-LS. The specimens are either head & neck squamous cell carcinomas or lung squamous cell carcinomas. All tissue specimens were formalin fixed paraffin embedded specimens. Gene expression was profiled using Affymetrix GeneChip platform.