Protein kinase C and lung carcinogenesis
Kazanietz, Marcelo Gabriel   
University of Pennsylvania, Philadelphia, PA, United States

This application focuses on the study of novel mechanisms involved in early events of lung carcinogenesis. Environmental carcinogens are major causative agents of lung cancer, as they induce genetic and epigenetic alterations that ultimately lead to the malignant transformation of lung epithelial cells. Oncogenic mutations in KRAS, a common alteration in non-small cell lung cancer (NSCLC), are induced in high frequency by lung carcinogens such as polycyclic aromatic hydrocarbons (PAHs) and many other environmental carcinogens. It has been established that protein kinase C epsilon (PKC?), a mitogenic, pro-survival, and tumorigenic kinase, is up-regulated in epithelial cancers, including NSCLC. Studies from our laboratory revealed that PKC? is an essential mediator of tumor formation, invasiveness, and metastasis of NSCLC cells. More recently, we developed a mouse model for inducible lung-specific expression of KRas in a PKC?-deficient background (LSL- K-rasG12D; PKC?-/-), and found that genetic ablation of the PKC? gene (PRKCE) markedly impairs the formation of tumors driven by the activated KRas allele. This suggests that PKC? is required for the initiation of KRas lung tumorigenesis. Moreover, in silico database analysis in KRAS mutated human lung adenocarcinomas revealed a significant association between high PKC? expression and short overall patient survival. Altogether, this led us to hypothesize that PKC? is a necessary mediator of the actions of lung carcinogens.
In Specific Aim 1 we will examine if PKC? KO mice (in A/J genetic background) are resistant to the effects of lung carcinogens known to induce mutations in KRas, including the PAH benzo[a]pyrene (B[a]P) and urethane. We will examine if a pharmacological inhibitor of PKC? (?V1-2) inhibits the formation of lung tumors induced by these carcinogens or by an activated KRas allele. Mechanistic studies will be pursued to assess if carcinogens up-regulate PKC??in lung epithelial cells.
In Specific Aim 2, we will use genetic and pharmacological approaches to determine if PKC? mediates the expansion of lung cancer progenitor cells (bronchioalveolar stem cells or BASCs) required for KRas- and carcinogen-induced tumorigenesis. To unambiguously establish a role for PKC? in initiation we will use gain-of-function approaches in cellular models as well as generate an inducible lung-specific transgenic mouse line for this kinase to determine if this leads to the formation of pre-malignant or malignant lung lesions. Finally, in Specific Aim 3 we will dissect the mechanistic basis for the functional interaction between KRas and PKC? in lung cancer, focusing on a) the analysis of elements of the Ras cascade, b) the identification of a PKC? gene signature and transcriptional networks regulated by this kinase in the context of KRas tumorigenesis, and c) the assessment of a potential role for PKC? in epithelial-mesenchymal transition (EMT), a process required for the acquisition of invasive capacity of lung cancer cells. Our studies should provide novel mechanistic insights into the molecular effects of environmental carcinogens as well as reveal important aspects of early events of lung carcinogenesis, thus impacting on our understanding of lung cancer etiology.

Public Health Relevance

This application focuses on a novel mechanism implicated in early events in carcinogenesis, specifically on the role of the kinase PKC? as a mediator of the actions of chemical/environmental carcinogens. Studies in cellular and mouse models clearly linked the actions of lung carcinogens to specific mutations in DNA, such as mutations in codon 12 in KRAS. We have strong preliminary data showing that PKC?, which is up-regulated in lung cancer, is required for the formation of Kras-driven lung tumors. Therefore, we hypothesize that environmental carcinogens such as polycyclic aromatic hydrocarbons (PAHs) require PKC? to fully achieve their carcinogenic effects. Novel mouse models will be developed to assess a potential role for PKC? in the initiation of lung cancer. Mechanistic studies will be pursued to identify a causal relationship between transformation by carcinogens and the induction of PKC? expression in lung epithelial cells. The proposed studies should reveal novel insights into the actions of lung carcinogens and have significant implications not only in translational medicine but also for our understanding of yet unidentified aspects of lung cancer etiology.