In mammals, the circadian clock controls most cellular processes in vivo including cell proliferation. Disruption of circadian rhythms leads to increased tumor development in animal models as well as in humans. The mammalian circadian clock is operated by the feedback loops of the circadian genes and is composed of a central clock in hypothalamus, the circadian input and output pathways, and peripheral clocks in all tissues studied. We have reported previously that the expression of c-myc and p53 follows a circadian rhythm in vivo and loss of function in the circadian genes, Period1 and 2, leads to neoplastic growth and deregulated DNA damage response in mice. Recently, we discovered that the central clock can entrain cell cycle and peripheral clocks by controlling the circadian rhythmicity of the sympathetic nervous system that simultaneously activates peripheral clock, cell cycle clock and p53 via activating Period1 and 2, Ap1-myc and ATM-p53 signaling. Disruption of circadian behavioral rhythm desynchronizes the central and peripheral clocks and uncouples p53 and Myc signaling resulting in oncogenic Myc activation, uncontrolled cell proliferation, and increased tumor development. In this application, we propose to study the mechanism and biological significance of circadian control of ATM-p53 signaling using a combination of molecular, cellular and genetic approaches. Specifically, we will focus on defining 1) the direct and indirect role of the peripheral clock in controlling ATM activation in response to sympathetic signaling;2) the role of the sympathetic signaling as a circadian time cue to activate peripheral clock and ATM via controlling interacting signaling pathways;and 3) the mechanism of deregulation of ATM-p53 signaling by disruption of circadian behavioral rhythm and the possibility of reducing radiation- induced host tissue damage by circadian gating ATM-p53 activation at a specific time of a day.

Public Health Relevance

In industrialized societies, changes in lifestyles lead to frequent disruption of endogenous circadian rhythm in about 50% of the human population, which contributes to increased cancer development world-wide. We plan to investigate how the clock controls the expression of the tumor suppressor p53, which is deregulated or mutated in most of types of human cancers. Our studies will lead to a better understanding of the mechanism of cancer and to the development of novel therapeutic strategies for cancer prevention and treatment. In industrialized societies, changes in lifestyles lead to frequent disruption of endogenous circadian rhythm in about 50% of the human population, which contributes to increased cancer development world-wide. We plan to investigate how the clock controls the expression of the tumor suppressor p53, which is deregulated or mutated in most of types of human cancers. Our studies will lead to a better understanding of the mechanism of cancer and to the development of novel therapeutic strategies for cancer prevention and treatment.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA137019-05
Application #
8704353
Study Section
Cellular Signaling and Regulatory Systems Study Section (CSRS)
Program Officer
Watson, Joanna M
Project Start
2010-09-01
Project End
2015-07-31
Budget Start
2014-08-01
Budget End
2015-07-31
Support Year
5
Fiscal Year
2014
Total Cost
Indirect Cost
Name
Baylor College of Medicine
Department
Pediatrics
Type
Schools of Medicine
DUNS #
City
Houston
State
TX
Country
United States
Zip Code
77030
Kettner, Nicole M; Voicu, Horatio; Finegold, Milton J et al. (2016) Circadian Homeostasis of Liver Metabolism Suppresses Hepatocarcinogenesis. Cancer Cell 30:909-924
Wu, Nan; Kim, Kang Ho; Zhou, Ying et al. (2016) Small Heterodimer Partner (NR0B2) Coordinates Nutrient Signaling and the Circadian Clock in Mice. Mol Endocrinol 30:988-95
Fleet, Tiffany; Stashi, Erin; Zhu, Bokai et al. (2016) Genetic and Environmental Models of Circadian Disruption Link SRC-2 Function to Hepatic Pathology. J Biol Rhythms 31:443-60
Kettner, Nicole M; Mayo, Sara A; Hua, Jack et al. (2015) Circadian Dysfunction Induces Leptin Resistance in Mice. Cell Metab 22:448-59
Kettner, Nicole M; Katchy, Chinenye A; Fu, Loning (2014) Circadian gene variants in cancer. Ann Med 46:208-20
Stashi, Erin; Lanz, Rainer B; Mao, Jianqiang et al. (2014) SRC-2 is an essential coactivator for orchestrating metabolism and circadian rhythm. Cell Rep 6:633-45
Fu, Loning; Kettner, Nicole M (2013) The circadian clock in cancer development and therapy. Prog Mol Biol Transl Sci 119:221-82
Lee, Jeongkyung; Kim, Mi-Sun; Li, Rongying et al. (2011) Loss of Bmal1 leads to uncoupling and impaired glucose-stimulated insulin secretion in ?-cells. Islets 3:381-8