Dr. Maria Bonsack

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Identification of naturally processed and presented HPV epitopes on cancer cells for therapeutic vaccine design

Several malignancies, most importantly cervical cancer, are caused by persistent infections with high-risk human papillomaviruses (HPV). For clearance of HPV infections, effective T cell-mediated responses are needed. These can be triggered in a targeted manner by vaccination with T cell epitopes derived from HPV proteins. Due to viral evasion mechanisms, only some viral epitopes are presented to the immune system on the surface of HPV-infected or -transformed cells.
The main focus of this project is to validate HPV-16-derived T cell epitopes for the major HLA supertypes. Epitopes are predicted in silico, HLA binding is verified experimentally, and immunogenicity and functional assays are applied in order to identify suitable vaccine candidates. Further, samples of HPV-16-transformed cells are analyzed for epitope presence by our highly specific mass spectrometry approach.

 

Characterization of Human Papillomavirus-derived epitopes in acidic tumor milieu and implications for therapeutic HPV vaccine design

This project aims to explore the influence of TME acidification on peptide HLA presentation and resulting implications for immunotherapies. Competitive cellular binding assays are used to assess pH-dependent HLA binding affinity of peptides derived from the HPV16 oncoproteins E6 and E7. This data can be used to classify subsets of acid-labile and acid-stable peptide:HLA complexes based on decreasing and stable binding affinity, respectively. Further, established workflows of immunopeptidomics and functional T cell assays targeting HPV-derived epitopes will compare the presentation and recognition of identified acid-labile and acid-stable epitopes. The identification of pH-dependent HPV epitopes and related peptide motifs will improve the selection of potent epitopes for effective targeted immunotherapies. Furthermore, this approach could reveal p:HLA acid-instability as a new immune evasion mechanism, explaining failure of some immunotherapeutics.

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Since Oct 2023
Principal Investigator, Project: "Characterization of Human Papillomavirus-derived epitopes in acidic tumor milieu and implications for therapeutic HPV vaccine design" (Stipend for Women after Maternity Leave or Child Care Times), German Center for Infection Research (DZIF), Heidelberg
Postdoctoral Scientist and Scientific Project Management, Immunotherapy and Immunoprevention, DKFZ, Heidelberg

Since Jan 2023
Postdoctoral Scientist and Scientific Project Management, Immunotherapy and Immunoprevention, DKFZ, Heidelberg

Since Jan 2019
Postdoctoral scientist, Immunotherapy and Immunoprevention, DKFZ, Heidelberg

2016 - 2019
PhD student, Junior Research Group Immunotherapy and Immunoprevention, DKFZ, Heidelberg

2013 - 2015  
MSc Regenerative Biology and Medicine, Center for Regenerative Therapies of the Dresden University of Technology, Dresden

2010 - 2013
BSc Molecular Biotechnology, Dresden University of Technology, Dresden