• School of Medicine
• Huntsman Cancer Institute
• University of Utah
• Contact Us

• Home
• Faculty Listing
• Faculty Resources
  • Retention Promotion & Tenure
  • Tenured Faculty Review
  • Appointments
  • MBM
  • OSP
• Student Listing
  • Graduate Student List
• Student Resources
  • Curriculum
  • Department Governance
  • Graduate School Forms
  • Guidelines
  • Journal Club
  • Major Milestones and Required Documents
  • Timelines and Academic Overview
• Research Resources
  • HCI Journals
  • Marriot Library
  • Eccles Library
  • Core Facilities

• Living in Utah
• Prospective Students
• Recruitment

Quick Access

Calendars

• RIP
• HCI Seminars
• HCI Research Events
• Bioscience Calendar
• SOM Seminars
• Biochemistry Seminars
• Neurobiology & Anatomy Seminars
• Neuroscience Seminars
• Biology Seminars

Curriculum

• FY09-FY10 Course Offerings

Forms

• Graduate School Forms
• Committee Meeting Report

Journal Clubs

• Cancer Biology
• Transcription

Student Insurance

• GM Southwest Health Insurance
• VISION - Opticare of Utah
• DENTAL - Educators

Cicely Jette

Positions:
Assistant Professor - Oncological Sciences Investigator - Huntsman Cancer Institute

Phone: (801)587-5568
Lab Phone: (801)585-6111
Fax: (801)581-2175
Email: cicely.jette@hci.utah.edu
Admin. Contact: Tonya Avery (801)587-9084

Office Address:
3242 Huntsman Cancer Institute

Mailing Address:
Huntsman Cancer Institute
2000 Circle of Hope
Salt Lake City, UT 84112-5550

Research Description:

The suppression of apoptosis is thought to be a requirement for the successful generation of most, if not all, cancers. The goal of my research is to discover therapeutic targets whose inhibition restores normal cell death pathways to cancer cells that are resistant to radiation and cytotoxic drugs. Bcl-2 overexpression in cancer cells is believed to confer resistance to radiation therapy and most chemotherapies. Virtually all anti-apoptotic members of the Bcl-2 family, as well as the pro-apoptotic Bax-like members, have been implicated in carcinogenesis as either oncogenes or tumor suppressors, respectively. In mouse models, overexpression of the anti-apoptotic Bcl-2 family members, or loss of both Bax and Bak, has been shown to decrease the sensitivity of tumor cells to radiation and chemotherapies.

In my laboratory, we use the zebrafish as a model system to study apoptotic mechanisms in cancer. Zebrafish have many attributes that make it an attractive vertebrate system to study apoptosis, such as optical clarity, rapid development, and conservation of the complex mitochondrial apoptosis pathway. Using a forward genetic approach, we have identified a number of recessive mutations that give rise to radiosensitization phenotypes during zebrafish development. These mutations re-sensitize bcl-2-overexpressing cells to pro-apoptotic stimuli, and we are currently placing these genes in apoptotic and cell cycle checkpoint pathways through genetic epistasis analysis.

To investigate the mechanisms controlling Bcl-2 mediated oncogenic pathways in human cancer cells, we also study the effects of zBcl-2 in zebrafish lymphoid cells in a transgenic line in which the zebrafish rag2 promoter directs the expression of egfp-bcl-2 in T- and B-lymphoid cells. Fluorescence microscopic analysis of living rag2-egfp-bcl-2 transgenic fish reveals that their thymocytes are resistant to radiation- and dexamethasone-induced apoptosis. T-cell leukemias induced in zebrafish by the rag2-egfp-mMYC transgene are eradicated by total body irradiation, whereas in fish expressing both MYC and egfp-bcl-2, the leukemic cells demonstrate resistance to radiation. These transgenic zebrafish lines serve as models for human tumors that are resistant to mitochondrial apoptosis induced by radiotherapy and chemotherapy. Thus, we analyze our zebrafish radiosensitizing mutations in this cancer model system to determine if they re-sensitize cancer cells to apoptosis-inducing therapies in vivo. Ultimately, we employ loss-of-function approaches in mouse and human cells to determine if the mechanisms underlying the radiosensitization are conserved.

---

1. Jette, C., Flanagan, A., Pyati, U., Stewart, R., Langenau, D.M., Look, A.T., and Letai, A.G. (2008) BIM and other BCL-2 family proteins exhibit cross-species conservation of function between zebrafish and mammals. Cell Death and Diff. 15(6):1063-72.
2. Sidi, S., Kennedy, R.D., Hagen, A.T., Sanda, T., Jette, C., Hoffmans, R., Imamura, S., Kishi, S., Kanki, J.P., Green, D.R., D’Andrea, A.A., and Look, A.T. (2008) Chk1 Suppresses a Caspase-2 Apoptotic Response to DNA Damage That Bypasses p53, Bcl-2 and Caspase-3. Cell 133(5): 864-77.
3. Langenau, D.M., Jette, C., Berghmans, S., Palomero, T., Kanki, J.P., Kutok, J.L., and Look, A.T. (2005) Suppression of Apoptosis by Bcl-2-overexpression in Lymphoid Cells of Transgenic Zebrafish. Blood, 105:3278-85.
4. Berghmans, S., Jette, C., Langenau, D., Hsu, K., Stewart, R., Look, A.T., and Kanki, J.P. Making Waves in Cancer Research: New Models in the Zebrafish. (2005) Biotechniques 39:227-3.

Figure: Immunofluorescence with an antibody recognizing activated Caspase 3 reveals that the rs7 mutation radiosensitizes zebrafish neural tissue.

Research Keywords:
zebrafish, cancer, apoptosis, Bcl-2, DNA damage, radiation