Alexander M. Mazo, PhD
Professor
Contact
1020 Locust Street
JAH, Rm. 485
Philadelphia, PA 19107
215-503-4785
215-923-7144 fax
Alexander M. Mazo, PhD
Professor
Expertise & Research Interests
Epigenetics mainly addresses maintenance of gene expression patterns by the structure of chromatin and modifications of DNA. Chromatin-related epigenetic mechanisms of maintenance of gene expression in daughter cells are essential for normal development, and their alterations cause numerous diseases including cancer. Research in my lab focuses on understanding several key epigenetic issues: how gene expression patterns are maintained during DNA replication and mitosis, how they are changed during development and cell differentiation, and how they are altered in cancer and other diseases.
The nature of epigenetic bookmarking is currently unclear, since it is not known how the process of DNA replication in eukaryotes affects association of chromosomal and transcriptional proteins with DNA. It is also not known whether nascent RNAs are dissociated from DNA and when the new round of transcription is initiated after replication. We found previously that in differentiating cells, numerous chromatin-modifying proteins are associated with DNA during DNA replication. However, major modified histone isoforms, the generally accepted epigenetic bookmarks, are detected on nascent DNA only some time after replication, implying that the widely accepted model for epigenetic bookmarking has to be re-examined. Using a number of recently developed techniques that allow detecting association of RNA and proteins with nascent DNA, we are currently investigating the fate of the RNA-transcriptional complex in epigenetic bookmarking. These studies may help to develop new models for epigenetic marking during DNA replication.
While gene expression patterns and thus epigenetic maintenance change during development, the mechanisms that allow these changes to occur are not clear. We recently discovered that differentiation of stem/progenitor cells of multiple origins requires transient de-condensation of post-replicative, nascent chromatin at repressed genes. This facilitates binding of lineage-specific transcription factors with their binding sites on nascent DNA and leads to changes in transcriptional and epigenetic programs of induced cells. These mechanisms are common in all tested differentiating cells, human and mouse embryonic stem cells, blood progenitor cells, and even during differentiation of more specialized cells, like T-cells and myofibroblsts. These findings may have a number of disease-related implications. On one hand, the knowledge of these mechanisms may create essential tools of manipulating the structure of nascent chromatin that may prevent major differentiation-related diseases like fibrosis. On the other hand, this creates a number of possibilities to prevent proliferation and survival of different types of cancer cells. Thus, the knowledge of the basic epigenetic mechanisms may help in devising new strategies of preventing differentiation-related diseases and in creating new tools in cancer treatment.
Education
PhD, Molecular Biology, Russian Academy of Science, Moscow, Russia
BS, MS, Moscow State University, Moscow, Russia
Most Recent Peer-Reviewed Publications
- An emerging paradigm in epigenetic marking: coordination of transcription and replication
- RNA polymerase II associates with active genes during DNA replication
- Changes in nascent chromatin structure regulate activation of the pro-fibrotic transcriptome and myofibroblast emergence in organ fibrosis
- Fibrosis—the tale of H3K27 histone methyltransferases and demethylases
- Targeting Chemotherapy to Decondensed H3K27me3-Marked Chromatin of AML Cells Enhances Leukemia Suppression
Awards
- Kimmel Cancer Center Award for the Best Achievements in Basic Research
- Kimmel Cancer Center Discovery of the Year Award
- Sidney Kimmel Medical College Faculty Research Career Achievement Award
- Sidney Kimmel Medical College Faculty Team Achievement Award
- Michael and Melina Pellini Award for Innovation in the Biomedical Sciences