Abstract
The chronic disruption of circadian rhythms has been implicated in the risk of cancer development in humans and laboratory animals. The gene product CLOCK is a core molecular component of the circadian oscillator, so that mice with a mutated Clock gene (Clk/Clk) exhibit abnormal rhythms in various physiological processes. However, we demonstrated here that Clk/Clk mice resisted chemical carcinogen-induced tumorigenesis by suppressing epidermal growth factor (EGF) receptor-mediated proliferation signals. The repetitive application of 7,12-dimethylbenz[α]anthracene (DMBA) to skin on the back resulted in the significant development of tumors in wild-type mice, whereas chemically-induced tumorigenesis was alleviated in Clk/Clk mice. Although the degree of DMBA-induced DNA damage was not significantly different between wild-type and Clk/Clk mice, EGF receptor-mediated Ras activation was not detected in DMBA-treated Clk/Clk mice. Genetic and biochemical experiments revealed that the suppression of EGF receptor-mediated signal transduction in DMBA-treated Clk/Clk mice was associated with the expression of the cellular senescence factor p16INK4a. These results suggest an uncovered role for CLOCK in the development of chemical carcinogen-induced primary tumors and offers new preventive strategies.
Highlights
In mammals, circadian rhythms in physiological functions are generated by a molecular oscillator driven by a transcriptional-translational feedback loop consisting of negative and positive regulators[1,2,3]
The numbers and sizes of tumors gradually increased during the duration of the experiment; chemical carcinogen-induced tumorigenesis was significantly alleviated in Clk/Clk mice (F1,16 = 6.302, P
Since the expression of proliferating cell nuclear antigen (PCNA) was significantly increased in the skin of DMBA-treated wild type mice (P < 0.01; Fig. 1d), application of the chemical carcinogen appears to induce the transition of skin cells into proliferative state
Summary
Circadian rhythms in physiological functions are generated by a molecular oscillator driven by a transcriptional-translational feedback loop consisting of negative and positive regulators[1,2,3]. Mouse embryonic fibroblasts prepared from animals deficient in the negative circadian clock regulators, Per[2] or Cry1/2, were susceptible to transformation induced by the co-expression of H-RasV12 and SV40 large T antigen (SV40LT). Consistent with these findings, mice with a mutated Per[2] gene (Per2m/m) were predisposed to spontaneous as well as radiation-induced tumor development[19,20,21]. The results of the present study suggest a role for CLOCK in the development of chemically-induced primary tumors and will contribute to new preventive strategies
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