Nuclear localization is required for function of the essential clock protein FRQ

The circadian system of Arabidopsis thaliana: forward and reverse genetic approaches

It is now widely accepted that autoregulatory circuits involving transcription/translation of clock genes form the molecular basis of the endogenous circadian clock in different organisms. In Arabidopsis thaliana, the RNA-binding protein AtGRP7 (Arabidopsis thaliana glycine-rich protein) has been identified as part of a negative-feedback loop through which AtGRP7 regulates the circadian oscillations of its own transcript. Experimental evidence indicates that this feedback loop also is influenced by another oscillator. Support for this hypothesis comes from the characterization of the clock mutant toc1 (timing of cab expression) and the recent isolation of two candidate clock molecules, LHY (late elongated hypocotyl) and CCA1 (circadian clock associated). TOC1, as well as the LHY and CCA1 oscillatory feedback loops, influence several rhythmic physiological and molecular processes in Arabidopsis, including cyclic Atgrp7 gene expression. We discuss the features of these feedback loops with relation to the organization of the circadian system in Arabidopsis.

Time at the end of the millennium: the Neurospora clock

In the past two years we have entered the log phase for unraveling the molecular clockworks. Rapid progress in understanding the Neurospora clock has been complemented by a flood of information from diverse systems including cyanobacteria, insects and mice. There are broadly conserved features in transcription/translation based feedback loops. Conservation is also found at the sequence level, from fungi to mammals, in the PAS domains of the heterodimeric partners of the transcription factors that act as the positive components of the feedback cycle. Pivotal PAS proteins from Neurospora, the WCs, provide an evolutionary link connecting the clock in insects and mammals to the fungi and to light-harvesting proteins from bacteria.

The cyanobacterial circadian system: a clock apart

Several new molecular components of the circadian clocks of animals, fungi, and bacteria have been unveiled in the past two years. Enough parts are now identified to indicate that there is more than one way to build a biological clock, although there are parallels in the cycling molecular events among disparate groups of organisms.

The Drosophila CLOCK protein undergoes daily rhythms in abundance, phosphorylation, and interactions with the PER-TIM complex

We report the in vivo characterization of the Drosophila CLOCK protein (dCLOCK), a transcription factor that is required for the expression of the circadian clock genes period (per) and timeless (tim). dCLOCK undergoes circadian fluctuations in abundance, is phosphorylated throughout a daily cycle, and interacts with PER, TIM, and/or the PER-TIM complex during the night but not during most of the day. Our results suggest that PER and TIM participate in transcriptional autoinhibition by physically interacting with dCLOCK or a dCLOCK-containing complex. Nevertheless, in the absence of PER or TIM, the levels of dCLOCK are constitutively low, indicating that PER and TIM also act as positive elements in the feedback loop by stimulating the production of dCLOCK.

Circadian regulation of a Drosophila homolog of the mammalian Clock gene: PER and TIM function as positive regulators

The Clock gene plays an essential role in the manifestation of circadian rhythms (approximately 24 h) in mice and is a member of the basic helix-loop-helix (bHLH) PER-ARNT-SIM (PAS) superfamily of transcription factors. Here we report the characterization of a novel Drosophila bHLH-PAS protein that is highly homologous to mammalian CLOCK. (Similar findings were recently described by Allada et al. Cell 93:791-804, 1998, and Darlington et al., Science 280:1599-1603, 1998.) Transcripts from this putative Clock ortholog (designated dClock) undergo daily rhythms in abundance that are antiphase to the cycling observed for the RNA products from the Drosophila melanogaster circadian clock genes period (per) and timeless (tim). Furthermore, dClock RNA cycling is abolished and the levels are at trough values in the absence of either PER or TIM, suggesting that these two proteins can function as transcriptional activators, a possibility which is in stark contrast to their previously characterized role in transcriptional autoinhibition. Finally, the temporal regulation of dClock expression is quickly perturbed by shifts in light-dark cycles, indicating that this molecular rhythm is closely connected to the photic entrainment pathway. The isolation of a Drosophila homolog of Clock together with the recent discovery of mammalian homologs of per indicate that there is high structural conservation in the integral components underlying circadian oscillators in Drosophila and mammals. Nevertheless, because mammalian Clock mRNA is constitutively expressed, our findings are a further example of striking differences in the regulation of putative circadian clock orthologs in different species.

Circadian rhythms: molecular basis of the clock

Much progress has been made during the past year in the molecular dissection of the circadian clock. Recently identified circadian genes in mouse, Drosophila, and cyanobacteria demonstrate the universal nature of negative feedback regulation as a circadian mechanism; furthermore, the mouse and Drosophila genes are structurally and functionally conserved. In addition, the discovery of brain-independent clocks promises to revolutionize the study of circadian biology.

Common threads in eukaryotic circadian systems

Within the past 18 months, common regulatory patterns have emerged among eukaryotic circadian systems--extending from fungi through to mammals. Heterodimeric complexes of PAS-domain-containing transcription factors play positive roles in clock-associated feedback loops, and classic clock proteins like FREQUENCY (FRQ), PERIOD (PER), and TIMELESS (TIM) appear as negative elements. Post-transcriptional control governs the amount and type of FRQ and makes the clock responsive to temperature.