Jozef Madzo, Ph.D.
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Assistant Professor, Genome Regulation and Cell Signaling Program, Ellen and Ronald Caplan Cancer Center
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Scientific Director, Bioinformatics Facility
Madzo is interested in approaches to cancer research informed by computational biology, particularly in the areas of DNA methylation drift during normal aging; disease-driven inflammation; and neoplastic transformation.
Dr. Madzo has a Ph.D. in Biomedicine from Charles University in the Czech Republic and a Professional Science Master’s degree in Bioinformatics from Temple University. He joined The Wistar Institute’s Genome Regulation and Cell Signaling Program as an assistant professor in 2024.
The Madzo Laboratory
The Madzo Laboratory
The Madzo lab focuses on computational biology, particularly on understanding DNA methylation drift during normal aging, disease-driven inflammation, and neoplastic transformation. Previous work has shown that cells exhibit changes in DNA methylation patterns during aging. Notably, diet and calorie restriction have been found to slow down age- or inflammation-related DNA methylation drift. Interestingly, cells undergoing malignant transformation display similar DNA methylation drift, suggesting that cancer cells exhibit a phenotype akin to accelerated aging.
Research
Epigenetic Regulation of Repetitive Elements
We are particularly focused on utilizing epigenetic drugs, such as inhibitors of DNA methyltransferases, to reactivate silenced repetitive elements in cancer cells. Reactivation of these elements leads to an inflammation-like phenotype, making the cancer cells more immunogenic and sensitized to immunotherapy.
We are working on multiple projects related to epigenetic changes during aging and cancer development. Our projects involve the integrated analysis of multiple sequencing datasets, including RNAseq, ATACseq, and scRNA-seq, to uncover the mechanisms involved in the genetic and epigenetic regulation of repetitive DNA.
A substantial part of our work involves querying high-dimensional data from publicly available sources such as TCGA, ENCODE, and GEO portals. We utilize existing open-source bioinformatics tools along with custom Python and R scripts. In our data analysis, we apply statistical methods such as permutation, multivariate analysis, and machine learning techniques like random forest, XGBoost, and stochastic gradient descent.
Madzo Lab in the News
Selected Publications
DREAM: A Simple Method for DNA Methylation Profiling by High-throughput Sequencing
Jelinek, J., & Madzo, J. (2016). DREAM: A Simple Method for DNA Methylation Profiling by High-throughput Sequencing. Methods in molecular biology (Clifton, N.J.), 1465, 111–127.
DNA methylation entropy as a measure of stem cell replication and aging
Vaidya, H., Jeong, H. S., Keith, K., Maegawa, S., Calendo, G., Madzo, J., Jelinek, J., & Issa, J. J. (2023). DNA methylation entropy as a measure of stem cell replication and aging. Genome biology, 24(1), 27.
Non-pathogenic microbiota accelerate age-related CpG Island methylation in colonic mucosa
Sun, A., Park, P., Cole, L., Vaidya, H., Maegawa, S., Keith, K., Calendo, G., Madzo, J., Jelinek, J., Jobin, C., & Issa, J. J. (2023). Non-pathogenic microbiota accelerate age-related CpG Island methylation in colonic mucosa. Epigenetics, 18(1), 2160568.
Promoter-independent synthesis of chemically modified RNA by human DNA polymerase θ variants
Tredinnick, T., Kent, T., Minakhin, L., Li, Z., Madzo, J., Chen, X. S., & Pomerantz, R. T. (2023). Promoter-independent synthesis of chemically modified RNA by human DNA polymerase θ variants. RNA (New York, N.Y.), 29(8), 1288–1300.
The three-dimensional structure of Epstein-Barr virus genome varies by latency type and is regulated by PARP1 enzymatic activity
Morgan, S. M., Tanizawa, H., Caruso, L. B., Hulse, M., Kossenkov, A., Madzo, J., Keith, K., Tan, Y., Boyle, S., Lieberman, P. M., & Tempera, I. (2022). The three-dimensional structure of Epstein-Barr virus genome varies by latency type and is regulated by PARP1 enzymatic activity. Nature communications, 13(1), 187.