Damon Runyon News

Pancreatic cancer remains unresponsive to current chemotherapy and immunotherapy treatments. However, with the recent development of mRNA vaccines and drugs that target cancer cell mutations, there is hope for a new generation of immune-based therapies. The ability of adaptive immune cells, called cytotoxic T cells, to kill cancer cells is central to anti-tumor immunity. Using mouse models of human pancreatic cancer, Dr. Fraschilla [Merck Fellow] plans to identify the flags presented by cancer cells that enable T cells to recognize them as foreign and kill them.

For gene activation, transcription factors (TFs) must bind to enhancers, often with multiple TFs binding at the same site, and recruit other proteins known as cofactors and polymerases. The interactions between TFs and cofactors are usually nonspecific, meaning the cofactors are interchangeable, which limits our understanding of precise gene activation. Dr. Chen will design new proteins that bind the cofactors with high specificity to clarify the contribution of each cofactor.

In cells, DNA wraps around a protein complex consisting of proteins called histones. Chemical modifications to histones can affect gene expression, which is key to activating or suppressing cancer progression. Histone monoaminylation, in which an amine (e.g., serotonin, dopamine, or histamine) attaches itself to a histone, is a newfound type of epigenetic modification whose role remains elusive in these processes. Dr. Zhang is using chemical biology tools to study the functions of these modifications as well as their effects on other adjacent, pre-existing cancer-associated modifications.

Epithelial to Mesenchymal Transition (EMT) is a crucial biological process that occurs during early development. It allows epithelial cells, which line the inner and outer surfaces of the body, to undergo a profound transformation in cellular identity and migrate and populate the embryo. Unfortunately, numerous cancer types exploit this mechanism, allowing cancer cells to detach from the tissue of origin and disseminate throughout the body, significantly worsening patients’ prognoses. Dr.

In many cancer types, microbiota have emerged as an influential component of the tumor environment. Dr. Dohlman [Meghan E. Raveis Fellow] studies Fusobacterium nucleatum, a bacterial species that colonizes around half of colorectal tumors. The reasons for F. nucleatum’s preferential colonization of these tissues are poorly understood, and investigating this phenomenon could lead to improvements in cancer diagnosis and treatment. To this end, Dr. Dohlman is using computational methods to study strains of cancer-associated F.

Proper cell division, including equal partitioning of DNA into two “daughter” cells, is critical for cell viability. However, many cancers continue to divide despite having atypical numbers of chromosomes and can even contain additional copies of the entire genome (polyploidy). Understanding how large increases in chromosome number affect cell division machinery has been limited by the methods used to generate polyploid cells. Serendipitously, stable polyploidy has arisen in multiple organisms, such as plants, fish, and amphibians.

Dr. Zheng [Fayez Sarofim Fellow] is dedicated to the development of technologies for studying tumor evolution within their native contexts. Understanding the complex processes of cancer growth and progression requires a deep exploration of the dynamic interactions between tumor cells and the tumor microenvironment. “Spatial-omics” technologies are powerful tools that offer direct visualization of cells and their interactions in natural contexts, enabling systematic investigation of these intricate processes. Dr.

Like changes in key genes that control the cell cycle, changes to chromosomes can result in abnormal cell function and sometimes even cancer. Recently, a new type of genetic change has been linked to diverse cancers: the formation of circular DNA molecules from chromosomes. These molecules, known as extrachromosomal DNA or ecDNA, are dangerous because they do not follow the same rules of inheritance as normal chromosomes. Understanding the behavior of ecDNA within cells may uncover strategies to eliminate ecDNA and restore cellular health. Using a model ecDNA in budding yeast, Dr.

Human cells have complex mechanisms to repair DNA damage, such as that caused by exposure to sunlight or chemical substances. If DNA is not properly repaired, however, it can lead to cancer. In fact, faulty DNA repair has been associated with the initiation and progression of all types of cancer and is often targeted in cancer treatment to stop uncontrolled cell growth. A better understanding of how cells naturally defend against DNA damage will allow for the development of better drugs to treat cancer. Dr.

Dr. Vardhana [Gordon Family Clinical Investigator] is exploring the hypothesis that gastric cancers create an inhospitable environment for immune T-cells by limiting the availability of essential nutrients needed by T-cells to produce the cytotoxic proteins that, when released, kill cancer cells. There is evidence that T-cells lose the ability to produce cytotoxic proteins within gastric tumors, while gastric tumors take up and sequester amino acids—the building blocks of all proteins, including cytotoxic proteins—such that they cannot be accessed by T-cells within tumors.