Microarray analysis of diurnal and circadian-regulated genes in Arabidopsis

Plants respond to day/night cycling in a number of physiological ways. At the mRNA level, the expression of some genes changes during the 24-hr period. To identify novel genes regulated in this way, we used microarrays containing 11,521 Arabidopsis expressed sequence tags, representing an estimated 7800 unique genes, to determine gene expression levels at 6-hr intervals throughout the day. Eleven percent of the genes, encompassing genes expressed at both high and low levels, showed a diurnal expression pattern. Approximately 2% cycled with a circadian rhythm. By clustering microarray data from 47 additional nonrelated experiments, we identified groups of genes regulated only by the circadian clock. These groups contained the already characterized clock-associated genes LHY, CCA1, and GI, suggesting that other key circadian clock genes might be found within these clusters.     

Expression of the Granule-Bound Starch Synthase I (Waxy) Gene from Snapdragon Is Developmentally and Circadian Clock Regulated

The granule-bound starch synthase I (GBSSI or waxy) enzyme catalyzes one of the enzymatic steps of starch synthesis. This enzyme is responsible for the synthesis of amylose and is also involved in building the final structure of amylopectin. Little is known about expression of GBSSI genes in tissues other than storage organs, such as seeds, endosperm, and tuber. We have isolated a gene encoding the GBSSI from snapdragon (Antirrhinum majus). This gene is present as a single copy in the snapdragon genome. There is a precise spatial and developmental regulation of its expression in flowers. GBSSI expression was observed in all floral whorls at early developmental stages, but it was restricted to carpel before anthesis. These results give new insights into the role of starch in later reproductive events such as seed filling. In leaves the mRNA level of GBSSI is regulated by an endogenous circadian clock, indicating that the transition from day to night may be accompanied by abolition of expression of starch synthesis genes. This mechanism does not operate in sink tissues such as roots when grown in the dark.     

Cytokinin affects circadian-clock oscillation in a phytochrome B- and Arabidopsis response regulator 4-dependent manner

In higher plants, many developmental processes, such as photomorphogenesis and flowering, are coregulated by light and the phytohormone cytokinin. Interactions between light and cytokinin pathways are presumably mediated by common signaling intermediates. However, the molecular mechanism of these interactions remains unclear. Here, we report that cytokinin specifically induces the expression of the Arabidopsis circadian oscillator genes LATE ELONGATED HYPOCOTYL ( LHY ) and CIRCADIAN CLOCK-ASSOCIATED 1 ( CCA1 ) but represses the expression of TIMING OF CAB EXPRESSION 1 in a light-dependent manner. Consistent with these observations, cytokinin causes a shifted phase of the circadian clock. Mutant studies showed that the altered clock oscillation modulated by cytokinin is dependent on phytochrome B ( PHYB ) and Arabidopsis RESPONSE REGULATOR 4 ( ARR4 ). Whereas overexpression of LHY or CCA1 renders plants slightly more sensitive to cytokinin, phyB and a lhy/cca1 double mutant are less sensitive to the hormone. These results suggest that cytokinin affects the circadian clock oscillation in a PHYB - and ARR4 -dependent manner and that cytokinin signaling is also regulated by light-signaling components, including PHYB , LHY and CCA1 . Therefore, phyB, ARR4 and the circadian oscillator may function as signaling intermediates to integrate light and cytokinin pathways.     

A complex genetic interaction between Arabidopsis thaliana TOC1 and CCA1/LHY in driving the circadian clock and in output regulation

It has been proposed that CIRCADIAN CLOCK ASSOCIATED 1 (CCA1) and LATE ELONGATED HYPOCOTYL (LHY) together with TIMING OF CAB EXPRESSION 1 (TOC1) make up the central oscillator of the Arabidopsis thaliana circadian clock. These genes thus drive rhythmic outputs, including seasonal control of flowering and photomorphogenesis. To test various clock models and to disclose the genetic relationship between TOC1 and CCA1/LHY in floral induction and photomorphogenesis, we constructed the cca1 lhy toc1 triple mutant and cca1 toc1 and lhy toc1 double mutants and tested various rhythmic responses and circadian output regulation. Here we report that rhythmic activity was dramatically attenuated in cca1 lhy toc1. Interestingly, we also found that TOC1 regulates the floral transition in a CCA1/LHY-dependent manner while CCA1/LHY functions upstream of TOC1 in regulating a photomorphogenic process. This suggests to us that TOC1 and CCA1/LHY participate in these two processes through different strategies. Collectively, we have used genetics to provide direct experimental support of previous modeling efforts where CCA1/LHY, along with TOC1, drives the circadian oscillator and have shown that this clock is essential for correct output regulation.     

Circadian expression of clock genes in the rat eye and brain

The light sensing system in the eye directly affects the circadian oscillator in the mammalian suprachiasmatic nucleus (SCN). To investigate this relationship in the rat, we examined the circadian expression of clock genes in the SCN and eye tissue during a 24 h day/night cycle. In the SCN, rPer1 and rPer2 mRNAs were expressed in a clear circadian rhythm like rCry1 and rCry2 mRNAs, whereas the level of BMAL1 and CLOCK mRNAs decreased during the day and increased during the night with a relatively low amplitude. It seems that the clock genes of the SCN may function in response to a master clock oscillation in the rat. In the eye, the rCry1 and rCry2 were expressed in a circadian rhythm with an increase during subjective day and a decrease during subjective night. However, the expression of Opn4 mRNA did not exhibit a clear circadian pattern, although its expression was higher in daytime than at night. This suggests that cryptochromes located in the eye, rather than melanopsin, are the major photoreceptive system for synchronizing the circadian rhythm of the SCN in the rat.