Transgenic rats expressing dominant negative BMAL1 showed circadian clock amplitude reduction and rapid recovery from jet lag

The circadian rhythms are endogenous rhythms of about 24 h, and are driven by the circadian clock. The clock centre locates in the suprachiasmatic nucleus. Light signals from the retina shift the circadian rhythm in the suprachiasmatic nucleus, but there is a robust part of the suprachiasmatic nucleus that causes jet lag after an abrupt shift of the environmental lighting condition. To examine the effect of attenuated circadian rhythm on the duration of jet lag, we established a transgenic rat expressing BMAL1 dominant negative form under control by mouse Prnp‐based transcriptional regulation cassette [BMAL1 DN (+)]. The transgenic rats became active earlier than controls, just after light offset. Compared to control rats, BMAL1 DN (+) rats showed smaller circadian rhythm amplitudes in both behavioural and Per2 promoter driven luciferase activity rhythms. A light pulse during the night resulted in a larger phase shift of behavioural rhythm. Furthermore, at an abrupt shift of the light‐dark cycle, BMAL1 DN (+) rat showed faster entrainment to the new light‐dark cycle compared to controls. The circadian rhythm has been regarded as a limit cycle phenomenon, and our results support the hypothesis that modification of the amplitude of the circadian limit cycle leads to alteration in the length of the phase shift. To examine the effect of attenuated circadian rhythm on the length of phase shift and duration of jet lag, we established a transgenic rat expressing BMAL1 dominant negative form. The transgenic rat showed smaller circadian rhythm amplitudes and a larger phase shifts of behavioural rhythm after a light pulse during the night. Furthermore, after an abrupt shift of the light‐dark cycle, the transgenic rat showed faster entrainment to the new light‐dark cycle with a short duration of jet lag.