Background: High-risk human papillomaviruses (HPV) cause nearly all cases of cervical cancer, as well as many types of oral and anogenital cancer. Alternative splicing increases the capacity of the HPV genome to encode the proteins necessary for successful completion of its infectious life cycle. However, the roles of these splice variants, including E6*, the smaller splice isoform of the E6 oncogene, in carcinogenesis are not clear.
Materials and methods: SiHa (HPV16(+)) and C33A (HPV(-)) cells were transfected with the E6* plasmid, and tandem mass tag-labeled protein levels were quantified by mass spectrometry. Proteomic analyses identified pathways affected by E6* in both HPV(+) and HPV(-) cells, and pathways were validated using in vitro methods.
Results: A total of 4,300 proteins were identified and quantified in lysates of SiHa and C33A cells with and without HPV16 E6* expression. SiHa and C33A cells expressing E6* underwent changes in protein expression affecting integrin signaling and mitochondrial dysfunction pathways, respectively. Subsequent experiments were performed to validate selected E6*-mediated alterations in protein levels.
Conclusion: E6* modifies the expression of proteins involved in mitochondrial dysfunction and oxidative phosphorylation in C33A cells, and β-integrin signaling in SiHa cells.
Keywords: DNA damage; E6*; Human papillomavirus; Ingenuity Pathway Analysis; RhoA GTPase; alkaline phosphatase; alternative splicing; cell spreading; electron transport chain; glutathione; kindlin-1; mitochondrial membrane depolarization; mitochondrial membrane potential; oxidative phosphorylation; oxidative stress; β-integrin.
Copyright© 2016, International Institute of Anticancer Research (Dr. John G. Delinasios), All rights reserved.