Stem cells and their environment, the so-called niche, are critical components that sustain not only proper tissue homeostasis, but also diseased states such as cancer. The inability to follow the same cells over time in an intact animal is a bi challenge that has greatly limited our understanding of what goes awry during normal tissue homeostasis and the cellular behaviors exhibited in the initial stages of tumor growth. Specifically, this roadblock has hindered our ability to understand both the role of specific cells and how their location contributes to their growth, whether it be normal or cancerous. For the first time, we are now capable of addressing these questions since my lab has pioneered the use of live imaging in skin stem cell regeneration and established an approach that allows us to follow the same cells over time in an intact, live mouse. By these approaches we have learned that first, the location where stem cells reside influences their ability to contribute to growth. Second, as a consequence of a perturbation, such as loss of a stem cell pool, other cells can acquire a new ability to contribute to growth that they did not possess previously. Third, the induction of oncogenic mutations in clones, such as mutations that stabilize the Wnt effector ?-catenin, will drive aberrant growths ultimately leading to tumor formation through the recruitment of non cell-autonomous wild-type cells. However, it is still unclear 1) what signaling mechanisms regulate the aberrant cellular behaviors that will eventually cause tumor development, 2) whether a cell's position within a tissue influences different tumoral outcomes, and 3) what early cell behaviors are adopted by stem and other cell types that lead to tumor development. To identify the aberrant stem cell/progenitor activities that cause cancer, we are using two contrasting human skin tumors; a benign and a malignant form, which we can faithfully recapitulate in a mouse model. We plan to 1) utilize cutting-edge exome and RNA sequencing approaches to identify target gene mutations associated with tumoral epithelial and stromal cell populations and 2) to assess the role of these genes towards cancer by in vivo overexpression and shRNA knockdown in the mouse via in utero injection and subsequent functional validation using our in vivo imaging approach. Together, these approaches will allow us to understand how novel and established target genes alter stem cell behaviors and identify the initial sequential steps that lead to malignant tumor growth. Understanding the mechanisms and signaling pathways underlying the role of stem cells in cancer holds great promise to transform current therapeutic strategies. Our plan aims to identify the relevant cells and genes that are responsible for skin tumor initiation, which may prove relevant for an extended application to other types of cancer.

Public Health Relevance

The proposed experiments will provide important clues towards the role of stem cells in the initiation and growth of benign and invasive skin tumors and will lead to the discovery of novel genes that can be targeted for curing not only aggressive skin tumors but other types of cancer that do not normally regress.

Agency
National Institute of Health (NIH)
Institute
National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS)
Type
Research Project (R01)
Project #
1R01AR067755-01A1
Application #
9101125
Study Section
Arthritis, Connective Tissue and Skin Study Section (ACTS)
Program Officer
Baker, Carl
Project Start
2016-05-01
Project End
2021-03-31
Budget Start
2016-05-01
Budget End
2017-03-31
Support Year
1
Fiscal Year
2016
Total Cost
Indirect Cost
Name
Yale University
Department
Genetics
Type
Schools of Medicine
DUNS #
043207562
City
New Haven
State
CT
Country
United States
Zip Code
Xin, Tianchi; Gonzalez, David; Rompolas, Panteleimon et al. (2018) Flexible fate determination ensures robust differentiation in the hair follicle. Nat Cell Biol 20:1361-1369
Mesa, Kailin R; Kawaguchi, Kyogo; Cockburn, Katie et al. (2018) Homeostatic Epidermal Stem Cell Self-Renewal Is Driven by Local Differentiation. Cell Stem Cell 23:677-686.e4
Park, Sangbum; Gonzalez, David G; Guirao, Boris et al. (2017) Tissue-scale coordination of cellular behaviour promotes epidermal wound repair in live mice. Nat Cell Biol 19:155-163
Burclaff, Joseph; Mills, Jason C (2017) Cell biology: Healthy skin rejects cancer. Nature 548:289-290
Brown, Samara; Pineda, Cristiana M; Xin, Tianchi et al. (2017) Correction of aberrant growth preserves tissue homeostasis. Nature 548:334-337
Sun, Thomas Yang; Haberman, Ann M; Greco, Valentina (2017) Preclinical Advances with Multiphoton Microscopy in Live Imaging of Skin Cancers. J Invest Dermatol 137:282-287
Rompolas, Panteleimon; Mesa, Kailin R; Kawaguchi, Kyogo et al. (2016) Spatiotemporal coordination of stem cell commitment during epidermal homeostasis. Science 352:1471-4
Park, Sangbum; Greco, Valentina; Cockburn, Katie (2016) Live imaging of stem cells: answering old questions and raising new ones. Curr Opin Cell Biol 43:30-37
Xin, Tianchi; Greco, Valentina; Myung, Peggy (2016) Hardwiring Stem Cell Communication through Tissue Structure. Cell 164:1212-1225