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Induction of Two Mammalian PER Proteins is Insufficient to Cause Phase Shifting of the Peripheral Circadian Clock  

Lee, Joon-Woo (Department of Life Science, College of Sciences, Yonsei University)
Cho, Sang-Gil (Department of Life Science, College of Sciences, Yonsei University)
Cho, Jun-Hyung (Department of Life Science, College of Sciences, Yonsei University)
Kim, Han-Gyu (Department of Life Science, College of Sciences, Yonsei University)
Bae, Ki-Ho (Department of Life Science, College of Sciences, Yonsei University)
Publication Information
Animal cells and systems / v.9, no.3, 2005 , pp. 153-160 More about this Journal
Abstract
Most living organisms exhibit the circadian rhythm in their physiology and behavior. Recent identification of several clock genes in mammals has led to the molecular understanding of how these components generate and maintain the circadian rhythm. Many reports have implicated the photic induction of either mPer1 or mPer2 in the hypothalamic region called the suprachiasmatic nucleus (SCN) to phase shift the brain clock. It is now established that peripheral tissues other than the brain also express these clock genes and that the clock machinery in these tissues work in a similar way to the SCN clock. To determine the role of the two canonical clock genes, mPer1 and mPer2, in the peripheral clock shift, stable HEK293EcR cell lines that can be induced and stably express these proteins were prepared. By regulating the expression of these proteins, it could be shown that induction of the clock genes, either mPer1 or mPer2 alone is not sufficient to cause clock phase shifting in these cells. Our real-time PCR analysis on these cells indicates that the induction of mPER proteins dampens the expression of the clock-specific transcription factor mBmal1. Altogether, our present data suggest that mPer1 and mPer2 may not function in clock shift or take part in differential roles on the peripheral circadian clock.
Keywords
Circadian clock; mPer; mBmal1; HEK293EcR cells; real-time PCR;
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