A relationship between adenosine 3'-5'-cyclic monophosphate levels and deoxyribonucleic acid synthesis in Euglena

Circadian clock regulation of the bimodal rhythm of cyclic AMP in wild-type Euglena

Cell-cycle traverse is associated with fluctuations in the cellular content of cAMP; artificial alterations of these levels phase-shift cell division in free-running cultures of achlorophyllous Euglena maintained in constant darkness (DD). The phase shifts observed, however, are only transient: the cell division rhythm rephases to that of unperturbed controls. This implies that the second messenger functions downstream of the circadian oscillator. Further, the level of cAMP is known to indicate carbon nutrient status and the competency of cells to traverse various restriction points in the cell cycle of other eukaryotes. We wished to determine the profile of cAMP content in free-running, dividing and non-dividing cultures of green, wild-type cells, which survive well during prolonged growth arrest. We monitored cAMP content in photoautothropic cultures of E. gracilis (strain Z) at 25 degrees C under either an entraining light-dark cycle comprising 12 h of light and 12 h of darkness (LD:12,12) or free-running (LD:1/2,1/2) regimes. cAMP content in rhythmically dividing, light-phased or free-running cells exhibited bimodality [peaks at CT (circadian time) 9-14 and CT 19-22). Expression of cAMP content on a per milligram total cellular protein basis caused the day trough (CT 1-3) to be even more distinct. Non-dividing, free-running, photoautotrophic cultures displayed a similarly phased bimodality in cAMP content. These findings in wild-type Euglena confirm that the bimodal rhythm of cAMP content is regulated by the circadian oscillator that underlies division rhythmicity but is not dependent on the cell division cycle. We will now determine the effect of the fluctuating cAMP levels on the phosphorylation status and activity of cell-cycle regulatory proteins.

Circadian rhythm of cell division

The existence of circadian oscillations in the level of hormones, in numerous physiological parameters, in toxicity and in behavior is now fully recognized in all living organisms. In contrast, the synchronisation and regulation of cell proliferation by circadian rhythms in vivo is only starting to be appreciated. This article reviews the experimental evidence for circadian synchronisation of cell division in different mammalian tissues (mainly the gastro-intestinal tract and hemapoietic system), including tumoral tissues. The possible causes of this coupling of the cell cycle phases to the circadian rhythm are discussed. Testing of novel antitumour agents using murine models should take into consideration the temporal difference between murine and human circadian control of proliferation (the peak of DNA synthesis occurs during the activity period, i.e. during daytime in man, and at night-time in mice and rats). Experimental and clinical data clearly support the important implications of the circadian control of the cell cycle in the optimisation of cancer chemotherapy, both for reducing toxicity and increasing the antitumour effects.

Oscillator control of cell division in Euglena: cyclic AMP oscillations mediate the phasing of the cell division cycle by the circadian clock

The achlorophyllous ZC strain of Euglena gracilis exhibits a circadian rhythm of cell division in constant darkness (DD). Mitosis occurs during a restricted part of the circadian cycle, corresponding to the dark intervals in a light-dark cycle comprising 12 h of light and 12 h of darkness. We have demonstrated that division-phased cultures also exhibit bimodal, circadian changes of cyclic AMP level. Maximum cyclic AMP levels occurred at the beginning of the light period (CT (circadian time) 00–02), and at the beginning of darkness (CT 12–14). These variations persisted in cultures that had been transferred into DD and appeared to be under the control of the circadian oscillator rather than to be cell division cycle (CDC)-dependent, since they continued in cultures that had reached the stationary phase of growth. In the experiments reported in this paper, we tested for the possible role of this periodic cyclic AMP signal in the generation of cell division rhythmicity by examining the effects of exogenous cyclic AMP signals and of forskolin, which permanently increased the cyclic AMP level, on the cell division rhythm. Perturbations of the cyclic AMP oscillation by exogenous cyclic AMP resulted in the temporary uncoupling of the CDC from the circadian timer. The addition of cyclic AMP during the subjective day resulted in delays (up to 9 h) of the next synchronous division step. In contrast, mitosis was stimulated when cyclic AMP was administered in the middle of the subjective night. Measurement of the DNA content of cells by flow cytometry indicated that cyclic AMP injected at CT 06–08 delayed progression through S phase, and perhaps also through mitosis. When added at CT 18–20, cyclic AMP accelerated the G2/M transition. The circadian oscillator was not perturbed by the addition of exogenous cyclic AMP: the division rhythm soon returned to its original phase. On the other hand, the permanent elevation of cyclic AMP levels in the presence of forskolin induced a rapid loss of cell division rhythmicity. These findings are consistent with the hypothesis that cyclic AMP acts downstream from the oscillator and that the cyclic AMP oscillation is an essential component of the signaling pathway for the control of the CDC by the circadian oscillator. The receptors for cyclic AMP in Euglena have been shown to be two cyclic AMP-dependent kinases (cPKA and cPKB). Pharmacological studies using cyclic AMP analogs suggested that cPKA mediates cyclic AMP effects during the subjective day, and cPKB during the subjective night.(ABSTRACT TRUNCATED AT 400 WORDS)

The role of ions and second messengers in circadian clock function

The fact that single cells can exhibit circadian rhythmicity simultaneously in quite different processes, such as those of photosynthesis, bioluminescence, and cell division, suggests that membrane-bound compartmentalization is important for temporal organization. Since these rhythms, as well as others, are known to be affected by changes in the ionic environment and are probably membrane-bound systems, it is not surprising that transmembrane ion transport or flux has been proposed to be a key feature of the underlying circadian oscillator(s). Likewise, signal transduction along the entrainment pathway leading to the clock, among the elements, or "gears," of the timing loop itself, and within the output pathway between the oscillator and its "hands" likely is mediated by ions and second messengers. In this overview, we examine the theoretical and experimental evidence supporting the possible roles of intracellular free calcium and cyclic AMP in these capacities, particularly in view of the fact that oscillations in the concentrations of both species have been proposed to form the basis of pacemaker activity and other biological rhythms.