A similar modification has previously been reported in MAP-induced behavioral rhythms under ad lib MAP drinking (Natsubori et al., 2013b). The phase shift was decelerated when the MAP-induced behavioral rhythm was located outside the subjective night and accelerated when it was inside. The phenomenon is called relative coordination and is taken as evidence for two interacting oscillators with different periods (Aschoff, 1965). In this respect, it is of interest to note that in the SCN-intact rats circadian
www.selleckchem.com/products/Bortezomib.html Per2 rhythms in extra-SCN brain areas were only slightly phase-shifted by R-MAP in the present study (Fig. 7B) whereas the circadian rhythms in some brain areas were markedly phase-shifted by ad lib MAP in the previous studies (Masubuchi et al., 2000; Natsubori et al., 2013b). These seemingly inconsistent results could be explained by the phase relation between the SCN circadian pacemaker and MAO. In the previous studies, MAP-induced behavioral rhythms were 180° out of the subjective night, which might reduce Gefitinib the influence of the SCN circadian pacemaker on MAO. On the other hand, the activity band of MAP-induced behavioral rhythm in the present study was located close to the subjective night (Fig. 4A), and therefore the influence of the SCN circadian pacemaker would be large. R-MAP-induced phase shifts
of Per2 rhythms depended on the brain areas examined and also on the presence or absence of the SCN circadian pacemaker (Fig. 7D). R-MAP did not affect the circadian oscillation in the SCN at all. The
phase shifts in the OB and SN were significantly larger in the absence of the SCN than in the presence. The findings indicate that the SCN circadian pacemaker exerted a strong influence on these extra-SCN oscillations even in the presence of GPX6 MAO. The extent of influence was different among the extra-SCN oscillations, the largest being on the SN oscillation and the smallest on the CPU, of those regions so far examined. Several important insights into the oscillation mechanism of MAO are provided by these findings. Firstly, the extra-SCN oscillations in certain brain areas such as OB, PC and SN are regulated by both the SCN circadian pacemaker and MAO. Many brain areas exhibit independent circadian oscillations which are usually under the control of the SCN circadian pacemaker (Abe et al., 2002; Abraham et al., 2005), and not all of them are affected by MAP (Masubuchi et al., 2000). Secondly, effects of MAP on the extra-SCN oscillations are different depending on the brain areas. The influence is large in the OB and SN and small in the CPU, and this is also supported by previous results (Natsubori et al., 2013b). In addition, the direction of phase shift of extra-SCN oscillation is different depending on the brain areas.