Damon Runyon News

When an organism is developing, it must correct mistakes that might occur at the level of individual cells or tissues. Dr. Triandafillou [National Mah Jongg League Fellow] wants to better understand how error correction systems work, and why they might not work in cases like cancer. To explore these developmental questions, Dr. Triandafillou uses what are called gastruloids, 3D clusters of stem cells that can organize themselves and transform into the basic building blocks of an organism.

On the cellular level, aging manifests as cellular senescence—when cells permanently stop multiplying but do not die. Aberrant accumulation of senescent cells is thought to be a major contributor to age-dependent tissue degeneration and its associated pathologies. Elimination of senescent cells has been shown to improve age-associated tissue damage pathologies and extend healthy lifespan in mice. Senescent cells undergo extensive remodeling on their surface, including increased production of many surface proteins. Dr.

Dr. Woida studies the foodborne pathogens Listeria monocytogenes and Shigella flexneri that enter and replicate within human cells. These bacteria also directly infect neighboring cells by pushing against the host cell membrane to form long membrane protrusions that extend and eventually release the bacteria into the new cell. This process of cell-to-cell spread requires the bacteria to hijack intercellular signaling pathways to reshape the host cell membrane.

Cell division is often described in terms of the inheritance of DNA. An equally important but less understood task of cell division is the distribution of cellular machineries responsible for decoding the genome. Dr. Tran studies how the cell’s major protein manufacturing factory, the endoplasmic reticulum (ER), is passed down through the germ cells that give rise to sperm and eggs. She is investigating whether ER inheritance plays a role in endowing germ cells with their unique properties, such as immortality and the ability to generate a new organism.

Dr. Li [The Mark Foundation for Cancer Research Fellow] studies signaling events regulating the competition between cells carrying cancer-causing mutations and normal cells during cancer initiation. Previous studies have shown that intercellular signaling between mutant and normal cells could regulate the proliferation of these cells and shape the outcome of cancer initiation. Dr. Li is adapting novel tools to identify what molecular cues are mediating this crosstalk and how they contribute to cancer growth in mouse skin.

Cells are compartmentalized into membrane-bound and membrane-less organelles, providing spatial structure to the cell’s concentration of proteins and nucleic acids. Dr. Kilgore’s research aims to understand the environment inside different organelles and apply this knowledge to the development of targeted cancer therapies, as better targeting within the cell will improve drug efficacy, increase potency, and decrease side effects. Using both live cells and reductionist models, he will investigate how molecules distribute themselves within the cell as a function of their chemical properties.

Immune checkpoint inhibitors, a type of cancer treatment that helps immune cells identify and kill tumor cells, have been a major breakthrough in the treatment of many cancer types. Unfortunately, not all patients respond to this immunotherapy. Dr. Hughes [Robert Black Fellow] is studying how gut microbes improve response to immune checkpoint inhibitors. The bacterium Akkermansia muciniphila lives in the gastrointestinal tract and has been shown to improve response to immune checkpoint inhibitors via poorly understood mechanisms. Dr. Hughes aims to discover how A.

Macrophages are specialized immune cells responsible for “eating” harmful cells, presenting antigens to T cells, and initiating inflammation by releasing signaling molecules called cytokines. Macrophages could potentially be activated to attack tumor cells, but for reasons that are currently unclear, they instead signal for the tumor to grow faster and become more invasive. Dr.

Dietary interventions such as caloric restriction (CR) and ketogenic diet (KD) are reported to limit tumor growth partially by modulating stem cell function. The intestine functions as the main organ of nutrient absorption and, due to rapid tissue renewal via intestinal stem cells (ISCs), is sensitive to shifts in the body’s metabolic state before and after eating. Both CR and KD conditions dramatically enhance the activity of an enzyme in ISCs known as HMGCS2.

Evidence that aging is driven by defined, regulated processes (rather than simple “wear and tear”) has sparked hope that we might target these processes to fight age-related diseases. A particularly exciting example is the regulation of protein homeostasis, or the balance between protein synthesis, folding, and degradation. Protein homeostasis is deregulated in both cancer and normal aging, but the underlying mechanisms remain elusive. Dr.