Abstract
Inhibiting epigenetic modulators can transcriptionally reactivate transposable elements (TEs). These TE transcripts often generate unique peptides that can serve as immunogenic antigens for immunotherapy. Here, we ask whether TEs activated by epigenetic therapy could appreciably increase the antigen repertoire in glioblastoma, an aggressive brain cancer with low mutation and neoantigen burden. We treated patient-derived primary glioblastoma stem cell lines, an astrocyte cell line and primary fibroblast cell lines with epigenetic drugs, and identified treatment-induced, TE-derived transcripts that are preferentially expressed in cancer cells. We verified that these transcripts could produce human leukocyte antigen class I-presented antigens using liquid chromatography with tandem mass spectrometry pulldown experiments. Importantly, many TEs were also transcribed, even in proliferating nontumor cell lines, after epigenetic therapy, which suggests that targeted strategies like CRISPR-mediated activation could minimize potential side effects of activating unwanted genomic regions. The results highlight both the need for caution and the promise of future translational efforts in harnessing treatment-induced TE-derived antigens for targeted immunotherapy.
Overview
- The study investigates the potential of epigenetic therapy to increase the antigen repertoire in glioblastoma, a brain cancer with low mutation and neoantigen burden. The study uses patient-derived primary glioblastoma stem cell lines, an astrocyte cell line, and primary fibroblast cell lines for the experiment. The methodology involves treating the cells with epigenetic drugs and identifying treatment-induced, TE-derived transcripts that are preferentially expressed in cancer cells. The primary objective of the study is to determine whether TEs activated by epigenetic therapy could appreciably increase the antigen repertoire in glioblastoma. The study aims to answer the question of whether epigenetic therapy can be used as a targeted immunotherapy for glioblastoma.
Comparative Analysis & Findings
- The study compares the outcomes observed under different experimental conditions or interventions. The results show that many TEs were also transcribed, even in proliferating nontumor cell lines, after epigenetic therapy. This suggests that targeted strategies like CRISPR-mediated activation could minimize potential side effects of activating unwanted genomic regions. The study identifies treatment-induced, TE-derived transcripts that are preferentially expressed in cancer cells and can produce human leukocyte antigen class I-presented antigens using liquid chromatography with tandem mass spectrometry pulldown experiments. The key findings of the study are that epigenetic therapy can increase the antigen repertoire in glioblastoma and that targeted strategies like CRISPR-mediated activation could minimize potential side effects of activating unwanted genomic regions.
Implications and Future Directions
- The study's findings have significant implications for the field of research and clinical practice. The study highlights the need for caution when using epigenetic therapy as a targeted immunotherapy for glioblastoma. The study also suggests that targeted strategies like CRISPR-mediated activation could minimize potential side effects of activating unwanted genomic regions. The study identifies treatment-induced, TE-derived transcripts that can produce human leukocyte antigen class I-presented antigens, which could be used for targeted immunotherapy. The study suggests future research directions that could build on the results of the study, explore unresolved questions, or utilize novel approaches. The study suggests that future research should focus on developing targeted strategies like CRISPR-mediated activation to minimize potential side effects of activating unwanted genomic regions. The study also suggests that future research should focus on developing targeted immunotherapies that utilize treatment-induced, TE-derived antigens for glioblastoma.