The role of ROC75 as a daytime component of the circadian oscillator in Chlamydomonas reinhardtii

Authors: Takuya Matsuo ^aff001; Takahiro Iida ^aff001; Ayumi Ohmura ^aff001; Malavika Gururaj ^aff001; Daisaku Kato ^aff001; Risa Mutoh ^aff001; Kunio Ihara ^aff001; Masahiro Ishiura ^aff001
Authors place of work: Center for Gene Research, Nagoya University, Furo-cho, Chikusa-ku, Nagoya, Japan ^aff001; Graduate School of Science, Nagoya University, Furo-cho, Chikusa-ku, Nagoya, Japan ^aff002
Published in the journal: The role of ROC75 as a daytime component of the circadian oscillator in Chlamydomonas reinhardtii. PLoS Genet 16(6): e32767. doi:10.1371/journal.pgen.1008814
Category: Research Article
doi: https://doi.org/10.1371/journal.pgen.1008814

Summary

The circadian clocks in chlorophyte algae have been studied in two model organisms, Chlamydomonas reinhardtii and Ostreococcus tauri. These studies revealed that the chlorophyte clocks include some genes that are homologous to those of the angiosperm circadian clock. However, the genetic network architectures of the chlorophyte clocks are largely unknown, especially in C. reinhardtii. In this study, using C. reinhardtii as a model, we characterized RHYTHM OF CHLOROPLAST (ROC) 75, a clock gene encoding a putative GARP DNA-binding transcription factor similar to the clock proteins LUX ARRHYTHMO (LUX, also called PHYTOCLOCK 1 [PCL1]) and BROTHER OF LUX ARRHYTHMO (BOA, also called NOX) of the angiosperm Arabidopsis thaliana. We observed that ROC75 is a day/subjective day-phase-expressed nuclear-localized protein that associates with some night-phased clock genes and represses their expression. This repression may be essential for the gating of reaccumulation of the other clock-related GARP protein, ROC15, after its light-dependent degradation. The restoration of ROC75 function in an arrhythmic roc75 mutant under constant darkness leads to the resumption of circadian oscillation from the subjective dawn, suggesting that the ROC75 restoration acts as a morning cue for the C. reinhardtii clock. Our study reveals a part of the genetic network of C. reinhardtii clock that could be considerably different from that of A. thaliana.

Keywords:

Sequence motif analysis – Transcription factors – Graphs – Circadian rhythms – Arabidopsis thaliana – Circadian oscillators – Bioluminescence – Chlamydomonas reinhardtii

Introduction

Circadian clocks are self-sustained oscillators that confer adaptive advantages to organisms [1,2]. A transcriptional/translational autoregulatory feedback loop mechanism consisting of some specific genes, called the “clock genes,” plays a crucial role in the central oscillatory mechanism of these clocks [3]. Although the basic properties of circadian clocks are common among all model organisms that have been studied, the primary sequences of clock genes/proteins are not conserved across the kingdoms of life [3]. In addition, even within the organisms that have the same set of clock genes, the roles of some clock genes differ from those of others (for example, the roles of cryptochromes in mammalian and insect clocks are different) [3]. Although the clock genes and their genetic network architectures are quite variable, the evolutionary aspects of circadian clocks remain poorly understood.

Several studies, mainly on Arabidopsis thaliana, have revealed a complicated network architecture of the feedback loop mechanisms of clock genes in angiosperms [4,5]. At the core of the network, is a mutual genetic interaction between two dawn-phased MYB transcription factor genes, CIRCADIAN CLOCK ASSOCIATED 1 (CCA1)/LATE ELONGATED HYPOCOTYL (LHY) and an evening-phased pseudo response regulator (PRR) gene called TIMING OF CAB EXPRESSION 1 (TOC1) [6–9]. In addition, another evening-phased gene, LUX (also called PCL1), encoding a GARP DNA-binding transcription factor interacts with the core loop [10,11]. The LUX (PCL1) protein acts as a night-time repressor by forming a protein complex with EARLY FLOWERING (ELF) 3 and ELF4 [12,13], and represses PRR9 whose product, in turn, represses CCA1/LHY [12,14]. LUX (PCL1) is thus an indirect activator of CCA1/LHY. BROTHER OF LUX ARRHYTHMO (BOA, also called NOX) is the other evening-phased clock-related GARP transcription factor that also forms a complex with ELF3 and ELF4 and promotes CCA1 expression [13,15].

Green plants consist of two main clades: the Streptophyta (include the angiosperm A. thaliana), and the Chlorophyta [16]. In recent years, clock genes have been identified in two chlorophyte species, Chlamydomonas reinhardtii (Chlorophyceae) and Ostreococcus tauri (Prasinophyceae), and it was revealed that their circadian clocks include genes that are homologous to those of the A. thaliana clock [17–21]. In O. tauri, CCA1 and TOC1 homologs form a transcriptional circuit which can generate a robust circadian oscillation [22–24]. Therefore, the core transcriptional circuit of the O. tauri clock is likely to be a simplified version of that of the A. thaliana clock [20,21]. On the other hand, in C. reinhardtii, homologous genes have been identified using a forward genetic screen [25]. ROC15 and ROC75 (ROC stands for “rhythm of chloroplast bioluminescence,” used as an indicator for the forward genetic screen) encode LUX (PCL1)/BOA (NOX)-like GARP proteins. ROC40 encodes a CCA1/LHY-like MYB protein. However, their expression phases or phase relationships do not correspond exactly to those of the A. thaliana homologs [18,19,25]. Moreover, ROC66, encoding a CONSTANS-like (COL) protein, has a considerable impact on the C. reinhardtii clock [25] whereas only a limited effect has been reported by the misexpression of a COL family gene in the A. thaliana clock [26]. Collectively, it seems to be difficult to apply the A. thaliana model directly to the C. reinhardtii clock [18,19].

In addition, a considerable number of genes, which are not conserved in the A. thaliana genome or are conserved but have not been described as a clock component, are known to be involved in the circadian clock of O. tauri and C. reinhardtii. These genes include LOV-HK and CPF1 of O. tauri [27,28], as well as ROC55, ROC59, ROC114, NAT3, XRN1 (ROC86), C1, C3, and pCRY of C. reinhardtii [25,29–32]. It is noteworthy that cryptochrome genes (CPF1 and pCRY) have a critical role in the circadian oscillators of these alga [27,32]. Cryptochromes are the core components of the mammalian circadian oscillator [3]. While mammalian cryptochromes and CPF1 belong to a phylogenetic clade called “animal-CRY,” pCRY belongs to “plant-CRY” with the A. thaliana cryptochromes, CRY1 and CRY2, which are involved in the input of light information to the circadian oscillator but not in the oscillator itself [33,34]. Taken together, it is likely that the chlorophyte algae have developed their own mechanisms different from angiosperms to adapt to their environment during evolution.

Here, we investigated the network architecture of the circadian transcriptional loop of C. reinhardtii to shed some light on the evolution of circadian clocks in green plants. We focused on the GARP protein gene, ROC75, in C. reinhardtii. ROC75 shows daytime mRNA expression [25], whereas ROC15, the other clock-related GARP protein gene in C. reinhardtii, shows nighttime mRNA (and protein) expression [35] similar to LUX (PCL1)/BOA (NOX) in A.thaliana [10,11].

Results

roc75 is a conditional mutant

Previously, we had isolated roc75, which shows arrhythmicity under constant darkness (DD) [25] in the bioluminescence rhythm derived from the tufA-lucCP reporter gene introduced into the chloroplast genome [36]. Here, we tested the bioluminescence reporter rhythm under continuous light (LL) conditions using various light intensities (50, 10, and 2 μmol/m²/s) and in a light/dark (LD; 12-h light:12-h dark) cycle. Under the LL conditions, roc75 showed bioluminescence rhythms with lower amplitudes than those of the wild-type (WT) strain at all the light intensities tested (Fig 1A and 1D), indicating that ROC75 is required for the normal rhythmicity of the reporter under LL conditions, as well. However, roc75 showed rhythmicity under the LL conditions unlike the arrhythmicity it showed under the DD conditions (Fig 1B and 1D). In addition, a diurnal bioluminescence rhythm, which appeared normal, was detected in roc75 under the LD condition (Fig 1C and 1D). This rhythm cannot be explained by a simple light/dark response of the reporter, since another arrhythmic mutant roc114 [25] showed a lower amplitude of the bioluminescence rhythm under the same condition (S1A and S1B Fig). Taken together, these results indicate that ROC75 is indispensable for circadian rhythmicity under DD conditions but not in the presence of light. This implies that the function of ROC75 is compensated by light to some extent.

Bioluminescence rhythms of the <i>roc75</i> mutant. — **Fig. 1. Bioluminescence rhythms of the *roc75* mutant.**
(A, B, C) Bioluminescence rhythm assay for the *tufA-lucCP* reporter gene introduced into the chloroplast genome under LL, DD, and LD conditions. Three representative bioluminescence traces of the WT and *roc75* cells are shown. White and black bars on the top of graphs represent light and dark conditions, respectively. **(D)** Amplitude of the rhythm. Bars represent means ± standard deviation (SD) of 6–18 biologically independent measurements. The asterisks indicate statistically significant differences (Student t-test; P < 0.001).

ROC75 is a day/subjective day-phase-expressed nuclear-localized protein

We analyzed the temporal and spatial expression profiles of ROC75. As reported in a previous study [25], the expression of ROC75 mRNA was high during the early subjective day under LL conditions (Fig 2A). A similar circadian profile was observed under DD conditions (Fig 2A). Under the LD cycle, the ROC75 mRNA showed a sharp peak at dawn (Fig 2A). The acute decline after the peak was due to a downregulation by light (Fig 2B). These mRNA rhythms were blunted for the mutated ROC75 mRNA (having a large insertion of the aph7" gene [25]) in roc75 (Fig 2A).

Expression analyses of <i>ROC75</i> gene. — **Fig. 2. Expression analyses of *ROC75* gene.**
**(A)** RT-qPCR analysis of the *ROC75* mRNA rhythm under LL, DD, LD conditions. The cells from the batch HS cultures were used. **(B)** RT-qPCR analysis of the *ROC75* mRNA in response to light. The cells from the LD-entrained batch HS cultures were harvested at 1, 2, and 4 h after switching-on the lights. The relative values with respect to the dark control cells at each time point are shown. **(C)** Western blot analysis of the ROC75-HA protein. Total protein samples were extracted from a continuous culture of ROC75-HA strain exposed to LL conditions. Western blot of α-tubulin is shown as a loading control. The lysate of the WT strain (W) was used as a negative control. **(D)** Bioluminescence rhythm assay of the ROC75-LUC protein fusion reporter. The traces represent means ± SD of more than five biological replicates. **(E)** Immunocytochemical staining of ROC75-HA. The cells were harvested from batch TAP cultures of the ROC75-HA strain at L4 (4 h after switching-on the lights). Counterstaining with the NPC antibody and merged images are indicated. **(F)** YFP fluorescence of ROC75-YFP. Batch TAP cultures of the ROC75-YFP strain were transferred to DD conditions, and YFP fluorescence was observed at 18 h after the transfer (subjective midday). White and black bars above the graphs represent the light and dark conditions, respectively. The shaded areas in the main body of the graphs represent the dark period under the LD condition or the time of day corresponding to the dark period for synchronization before the exposure to LL and DD conditions. Representative results are shown (A-F). The reproducibility was confirmed by performing at least two independent experiments (A-F) and by using more than two independent transgenic lines (C-F).

To analyze the expression of the ROC75 protein, we introduced a codon-adapted hemagglutinin (HA) epitope tag sequence [35] at the end of the coding sequence of a genomic DNA fragment of ROC75 locus, and roc75 mutant was transformed with the DNA fragment (S2A Fig). The tagged gene fully complemented the arrhythmicity of roc75 under DD conditions, indicating that the HA-tagged ROC75 was functional (S2B Fig). The ROC75-HA protein showed a rhythm, peaking at the subjective day under LL conditions (Fig 2C). Furthermore, bioluminescence assay by using a luciferase reporter translationally fused to the C-terminal of full length ROC75 protein (ROC75-LUC) [35] and the luciferin analog AkaLumine (see Materials and Methods) also indicated diurnal/circadian rhythms peaking at the day/subjective day under LL, DD, and LD conditions (Fig 2D). These results suggest that ROC75 is a day/subjective day-phase-expressed protein. In addition, because ROC75-LUC complemented the arrhythmicity of roc75, the ROC75-LUC fusion protein is probably functional as a clock component (S3 Fig).

To determine the intracellular localization of ROC75, we performed immunocytochemical staining of ROC75-HA. The ROC75-HA signal was detected just inside of the nuclear envelope, which was counterstained with an antibody for the nuclear pore complex (NPC) (Fig 2E). In addition, we detected similar nuclear signals from the ROC75-YFP fusion protein expressed using the same strategy that was employed for ROC75-HA (Fig 2F, S2 Fig). Taken together, these results suggest that ROC75 is a day/subjective day-phase-expressed nuclear-localized protein.

ROC75 associates with the rhythmic circadian clock genes

Because ROC75 has a GARP DNA-binding motif [25], we investigated its association with DNA using chromatin immunoprecipitation followed by deep sequencing (ChIP-seq). We could detect 81 peaks of ROC75-HA associated DNA fragments on the nuclear genome (S1 Table). Most of the peaks were located in the upstream region (36/81) and in the 5′-untranslated region (UTR) (31/81) of the target genes (S1 Table, S4A Fig). A consensus motif search for the sequences around the 81 peaks identified “GATTYKV” (S4B Fig), which is a close match to the consensus motif of A. thaliana LUX (PCL1) (GATWCC, [12]). The peaks were detected on the clock genes (ROC15, ROC40, ROC66, and ROC75 itself) (Fig 3) that are known to show circadian rhythms in their mRNA levels [25]. On the other hand, peaks were not detected on non-rhythmic ROC genes (ROC55 and ROC114 [25]) (Fig 3). The ChIP-seq peak on the ROC40 gene was confirmed by ChIP followed by quantitative PCR (ChIP-qPCR) (S5 Fig). A peak was also detected on ROC59 (S1 Table, Peak No. 5), which is another ROC gene that was identified as the gene responsible for a mutant that showed “long-period” and “delayed-phase” circadian phenotypes [25]. In addition, a peak was detected on CrPRR1, a PRR-like gene encoding a protein similar to the A. thaliana TOC1 [37], but has not yet been described as a clock component in C. reinhardtii (S1 Table, Peak No. 23).

**Fig. 3. ChIP-Seq analysis of ROC75-HA.**
The ROC75-HA cells were harvested from batch TAP cultures at L4 (4 h after switching-on the lights). Data shown are histograms of the number of mapped sequence tags around the clock genes. The results for the input DNA are shown as negative control.

The number of peaks detected was relatively low, probably because of technical reasons. We consider that our ChIP-seq assay covered only highly specific- but not the entire-fraction of ROC75 targets. Therefore, in this study, we focused only on the clock and putative clock genes that were detected.

We tested the DNA-binding activity of the GARP motif of ROC75 by electrophoresis mobility shift assay (EMSA). We used a GST-tagged GARP DNA-binding domain protein of ROC75 (GST-GARP) purified from Escherichia coli (S6A Fig) and a 26-bp DNA fragment from the amplicon 3 of ROC40 (S5 Fig) containing the ChIP-seq consensus sequence, GATTYKV (S4B Fig). A mobility shift was observed in the WT DNA fragment (S6B Fig, aGATTTTCt). This binding was weakened by a mutation in the first GAT (S6B Fig, aCCCTTTTCt) but not by a mutation in its neighboring nucleotides (S6B Fig, cGATCTTCt), and was abrogated by a mutation in both of them (S6B Fig, cCCCCTTCt). This result indicates that the GARP domain of ROC75 can bind to DNA directly in a sequence-specific manner.

ROC75 represses the clock-related genes

We tested the effect of roc75 mutation on the expression of the target genes identified by ChIP-seq analysis at the mRNA level. As described previously [25], the mRNA levels of ROC15, ROC40, and ROC66 showed robust circadian rhythms, peaking at the subjective night under LL conditions in the WT strain (Fig 4A–4C, LL). Essentially the same rhythmic expression patterns were observed under DD and LD conditions (Fig 4A–4C, DD and LD). In the roc75 mutant, the downregulation of the expression of these genes during the day/subjective day was weak or was almost abolished under all the conditions tested (Fig 4A–4C). These results suggest that ROC75 acts as a repressor of these genes during the day/subjective day. In the case of ROC66, however, the mRNA level was notably low in the mutant during the night/subjective night, especially under LL and LD conditions (Fig 4C), suggesting the lack of an activation mechanism or suggesting the involvement of additional repressor(s) other than ROC75.

**Fig. 4. The mRNA rhythm of clock-related genes.**
**(A-E)** RT-qPCR analysis of the mRNA rhythm of the clock-related genes. The cells were harvested from batch HS cultures exposed to LL, DD, and LD conditions. White and black bars above the graphs represent the light and dark conditions, respectively. The shaded areas in the main body of the graphs represent the dark period under the LD condition or the time of day corresponding to the dark period for synchronization before the exposure to LL and DD conditions. The magnified trace of *ROC59* expression in WT under the LD condition is shown in blue, and its y-axis is shown on the right (D). Representative results are shown. The reproducibility was confirmed by performing at least two independent experiments.

The expression of ROC59 was highly dependent on the light conditions. The expression under DD conditions was one order of magnitude lower than that under the LL conditions, and no rhythmicity was detected both in the WT strain and the roc75 mutant (Fig 4D, DD). Under the LD condition, a peak was observed in the day, and the peak expression level was high in the roc75 mutant (Fig 4D, LD), suggesting that ROC75 acts as a repressor of the light-dependent expression of ROC59 during the day. Under LL conditions, the expression level was high in both the WT strain and roc75 mutant, and the downregulation during subjective day was abolished in the roc75 mutant (Fig 4D, LL). These results suggest that ROC75 acts as a repressor of the light-dependent expression of ROC59.

The expression of CrPRR1 in the WT strain showed a circadian rhythm, peaking in the evening, under the LD condition and in the early subjective night under LL and DD conditions (Fig 4E). In the roc75 mutant, the expression during the day/subjective day under LD and LL conditions was higher than in the WT strain (Fig 4E, LD and LL), again suggesting a repressor function of ROC75 during the day/subjective day. Also, the lower expression level in roc75 during the subjective night under LL conditions suggests the involvement of other regulation mechanisms as in the case of ROC66. Interestingly, however, the expression of CrPRR1 was very weak in the roc75 mutant under DD conditions and during the dark phase under the LD condition (Fig 4E, DD and LD). This indicates that ROC75 is required for the activation of CrPRR1 expression in the dark.

Acute downregulation of ROC15 and ROC40 mRNAs by light is independent of ROC75

In addition to endogenous oscillations, the ROC15 and ROC40 mRNAs show an acute decline after exposure to light [35,38,39]. To investigate this light response in roc75 to light, cells in the late night phase were exposed to light for 1 h. An acute decline in the expression of these mRNAs was observed in the roc75 mutant as well as in the WT strain (Fig 5A). The acute decline also occurred after the dawn under the LD condition but the levels of these mRNAs were recovered in the roc75 mutant (Fig 5B). These results indicate that ROC75 is not essential for the acute downregulation of ROC15 and ROC40 mRNAs by light, but has a role in preventing their reaccumulation during the day.

Light response of <i>ROC15</i> and <i>ROC40</i> mRNAs. — **Fig. 5. Light response of *ROC15* and *ROC40* mRNAs.**
**(A)** RT-qPCR analysis of the acute light response. LD-synchronized batch HS cultures were exposed to light (30 μmol/m²/s) at the late night (ZT22, 2 h before dawn). One hour after the switching-on of lights, the cells were harvested along with the control cells that were not exposed to light. Data indicate means ± SD of three biological replicates. The asterisks indicate statistically significant differences (Student t-test; P < 0.001). **(B)** RT-qPCR analysis of the light response at dawn. LD-synchronized batch HS cultures were harvested at 0 (dark), 1, 2, and 4 h after light onset. Data shown are the relative values with respect to dark controls that were kept under dark conditions. White and black bars above the graphs represent the light and dark conditions, respectively. Representative results are shown. The reproducibility was confirmed by performing at least two independent experiments.

Rhythms of clock proteins are abolished by roc75 mutation under DD but not under LL and LD conditions

To assess the effect of the roc75 mutation on the rhythms of clock proteins, we measured the bioluminescence rhythms of luciferase reporters translationally fused to ROC15, ROC40, and ROC66 proteins (ROC15-LUC, ROC40-LUC, and ROC66-LUC respectively [35]). Under the LD condition, in sharp contrast to the mRNA data, the bioluminescence rhythms of these reporters were similar to that of WT in the roc75 mutant (Fig 6A). Under LL conditions, although the rhythm patterns were disturbed in the roc75 mutant, these reporter signals were still rhythmic (Fig 6B). Under DD conditions, however, these reporter signals were completely arrhythmic in the roc75 mutant, and the bioluminescence levels of ROC15-LUC and ROC40-LUC were constantly high (Fig 6C). These results suggest that the deregulation of the rhythms of clock mRNAs in the roc75 mutant were reflected in the rhythms of their respective proteins under DD but not under LL and LD conditions. This result is in good agreement with the conditional arrhythmicity of the bioluminescence rhythm in chloroplast reporter strain (Fig 1).

**Fig. 6. Rhythms of clock-related proteins.**
**(A-C)** Bioluminescence rhythm assay of the ROC15-LUC, ROC40-LUC, and ROC66-LUC protein fusion reporters under LD (A), LL (B), and DD (C) conditions. The reporters having *roc75* mutation were obtained by genetic crosses between the mating type (mt)⁺ reporter strains and mt^- strain of the *roc75* mutant. The result from two mutant progenies and parental WT reporter strains are shown. The traces represent the means ± SD of at least five biological replicates. The insets are magnified graphs. White and black bars above the graphs represent the light and dark conditions, respectively. The shaded areas in the main body of the graphs represent the dark period under the LD condition or the time of day corresponding to the dark period for synchronization before the exposure to LL and DD conditions.

Essentially same results were obtained in an in vitro luciferase assay using crude extracts of the reporter cells under DD conditions (S7 Fig), ruling out the possibilities that the results of the in vivo bioluminescence assay were because of the changes in the availability of intracellular ATP, luciferin, magnesium ion, and/or oxygen in this mutant.

Loss of circadian gating of ROC15 reaccumulation in the roc75 mutant

It is obvious that the light-induced acute degradation of ROC15 at dawn occurred normally in the roc75 mutant (Fig 6A, ROC15-LUC), indicating that ROC75 is not involved in this process. Previously, we demonstrated that the recovery of the ROC15 level after degradation was restricted to the subjective night [35]. Interestingly, the recovery was observed throughout the circadian cycle in the roc75 mutant (Fig 7A). In addition, the roc75 mutant failed to keep low ROC15-LUC bioluminescence level during the subjective day when the cells were exposed to a premature darkness (Fig 7B). These results suggest that ROC75 contributes to the circadian gating of ROC15 reaccumulation.

**Fig. 7. Light response of the ROC15 protein.**
**(A)** Bioluminescence assay of ROC15-LUC for recovery after exposure to a light pulse. The ROC15-LUC reporter was exposed to a light pulse (5 min, 10 μmol/m²/s) at the time-points indicated under DD conditions. **(B)** Bioluminescence assay of ROC15-LUC for response to a premature darkness. The LD-synchronized ROC15-LUC reporter strains were exposed to 6-h premature darkness. The traces represent means ± SD of at least five biological replicates (A, B). White and black bars above the graphs represent the light and dark conditions, respectively. The shaded areas in the main body of the graphs represent the time of day corresponding to the dark period for synchronization before the exposure to DD conditions (A) and the dark period (B).

Repression- but not activation-domain fusion is compatible with ROC75

To investigate the molecular function of ROC75, we tested the compatibility of ROC75 with repression- and activation-domain fusion. Fusion to a domain, having the same transcriptional function (repression or activation) as ROC75, is expected to enhance or not interfere with its function. Conversely, fusion to a domain having an opposite function is expected to interfere with it. We employed the strong repression domain SRDX [40] and the strong activation domain VP64 [41]. Codon-adapted sequences of the domains for the C. reinhardtii nuclear genome (S8 Fig) were inserted at the end of the coding sequence of the ROC75 genomic DNA fragment to express the C-terminally-tagged version of ROC75 (ROC75-SRDX and ROC75-VP64) (Fig 8A). ROC75-SRDX complemented the arrhythmicity of roc75 mutant at a rate comparable to that of ROC75-HA and ROC75-YFP (Fig 8B, S2 Fig). On the contrary, no transformant with ROC75-VP64 showed restoration of circadian rhythmicity even in transformants expressing the fusion protein at a similar level to ROC75-SRDX (Fig 8B and 8C). Furthermore, upregulation of ROC15 and ROC40 mRNAs was observed in ROC75-VP64 transformants in the day phase (Fig 8D), suggesting that the VP64 domain fusion is functional in C. reinhardtii. These results suggest that ROC75 acts as a transcriptional repressor.

**Fig. 8. Fusion of repression and activation domains to ROC75.**
**(A)** A schematic representation of the ROC75-SRDX and ROC75-VP64 transgenes. White boxes represent exons. The positions of the 5′- and 3′-ends of the transcript are based on the latest genome annotation (*Chlamydomonas reinhardtii* v5.6, Phytozome 13, https://phytozome-next.jgi.doe.gov/). **(B)** Bioluminescence rhythm assay of the *tufA-lucCP* reporter in ROC75-SRDX and ROC75-VP64 strains. Each trace represents the average bioluminescence level of two biological replicates. The number in the graph legend represents complemented-transformant/total-transformant-tested. **(C)** Western blot analysis of the ROC75-SRDX and ROC75-VP64 proteins. The cells were harvested from batch TAP cultures at dawn, α-tubulin is shown as a loading control. Anti-FLAG antibody was used to detect these proteins. **(D)** RT-qPCR analysis of *ROC15* and *ROC40*. The cells were harvested from batch TAP cultures at L4 (4 h after switching-on the lights). Data indicate means ± SD of three biological replicates.

Restoration of ROC75 function resumes the circadian oscillation from subjective dawn

We examined the effect of timing of restoration of ROC75 function in the arrhythmic roc75 mutant in DD. For this purpose, we took advantage of the glucocorticoid receptor (GR) system to control the activity of ROC75. The GR system has been developed to regulate the activity of transcription factors in A. thaliana. Transcription factors fused to the 287-aminio-acid hormone binding domain of GR cannot regulate transcription in the absence of the steroid ligand because of association with a heat-shock protein 90 complex, but the transcriptional activity is restored by adding the ligand dexamethasone (DEX), which induces a conformational change in GR, subsequently releasing the fusion protein from the complex [42].

A codon-adapted sequence of the hormone binding domain of rat GR for the C. reinhardtii nuclear genome (S9 Fig) was inserted at the end of the coding sequence of the ROC75 genomic DNA fragment to express the C-terminally tagged version of ROC75 (ROC75-GR) (Fig 9A). ROC75-GR complemented the roc75 mutant phenotype in the presence of DEX but not in the absence of DEX (Fig 9B). The restoration of the amplitude of bioluminescence rhythm was dependent on the dose of DEX (Fig 9C). These results indicate that the GR system can regulate the activity of ROC75 in C. reinhardtii.

**Fig. 9. Restoration of ROC75 function by the GR-system.**
**(A)** A schematic view of the ROC75-GR transgene. White boxes represent exons. The positions of the 5′- and 3′-ends of the transcript are based on the latest genome annotation (*Chlamydomonas reinhardtii* v5.6, Phytozome 13, https://phytozome-next.jgi.doe.gov/). **(B)** Bioluminescence rhythm assay of the *tufA-lucCP* reporter in ROC75-GR strain. DEX was added to a final concentration of 2 μM just before synchronization. The DEX- control was treated with the same concentration of the solvent (EtOH). **(C)** Amplitude of the bioluminescence rhythm. Each bar represents the mean ± SD of six biological replicates. **(D)** A representative trace of the bioluminescence of the ROC75-GR strain before and after DEX addition. DEX (final concentration: 2 μM) was added at the 84-h time-point under DD conditions. **(E)** The phase of ROC75-GR bioluminescence rhythm after DEX addition. The peaks of each bioluminescence trace of ROC75-GR (duplicate cultures of four independent transgenic lines) and WT (2–4 cultures) were plotted on the graph. The arrows indicate the timing of DEX addition (final concentration: 2 μM). All representative traces are shown in *S10 Fig*. **(F)** Peak phase relative to the DEX-addition and light-on. The phase in circadian time (CT) was calculated against the timing of DEX-addition (left) and switching-on of the light in LD cycle preceding the exposure to DD condition (right). Data points represent means ± SD of four and six to eight biological replicates of the WT and ROC75-GR (from four independent transgenic lines), respectively. White and black bars above the graphs represent light and dark conditions, respectively (B, D, E).

By adding DEX to arrhythmic ROC75-GR cultures under DD conditions, the bioluminescence rhythms were restored (Fig 9D). We added DEX at various times under the DD conditions, and analyzed the circadian phase of the recovered bioluminescence rhythm (Fig 9E, S10 Fig). The results were different between the first day and the second or later days under DD conditions. When DEX was added on the first day, the restored rhythms showed phases relatively close to those of the WT rhythms (Fig 9E and 9F). In other words, the phase was mostly dependent upon the LD cycle before transfer to DD conditions, indicating that the previous light/dark cue is dominant to the ROC75 restoration during this period. In contrast, when DEX was added on the second or later days, the phase of the restored rhythms was dependent upon the timing of DEX addition (Fig 9E and 9F). The peak phase relative to DEX addition was 8–10 h (Fig 9F, left), which was comparable to that relative to the light-on in the WT strain (Fig 9F, right), suggesting that DEX acts as a morning cue in this system.

Discussion

Roles of ROC75 in the C. reinhardtii circadian clock

In the roc75 mutant under DD conditions, the expression of ROC15 and ROC40 was almost constantly high (Fig 4A and 4B, DD; Fig 6C), similar to their expression state just before the subjective dawn in the WT cells. This suggests that the circadian clock in the roc75 mutant is arrested before the subjective dawn because of the loss of downregulation of these genes by ROC75. This hypothesis is consistent with the result of DEX acting as a morning cue (Fig 9E and 9F, after the second day under DD conditions). These results suggest that one of the roles of ROC75 is its involvement in the progression of the circadian clock from the subjective night to the subjective day under DD conditions. In addition, the loss of circadian gating of ROC15 reaccumulation (Fig 7) suggests that another role of ROC75 is the maintenance of the "subjective day state" of the circadian clock by preventing reaccumulation of the nighttime clock protein ROC15. This gating might be supported, at least in part, by the repression at the mRNA level by ROC75 (Fig 4A, DD).

In contrast to DD conditions, the circadian rhythms of clock proteins were robust in the LD condition in the roc75 mutant (Fig 6A). It is possible that the acute downregulations in ROC15 and ROC40 mRNAs and ROC15 protein by light (Figs 5 and 7), which are independent of ROC75, generate the robust oscillation of the clock proteins, and compensate the ROC75 functions. Since the mRNA oscillations in the LD condition were weak or not detectable in the roc75 mutant (Fig 4A and 4B, LD) probably due to their rapid recovery after transition to the day phase (Fig 5B), the contribution of the mRNA rhythms on the protein rhythms would be limited. Translational/posttranslational regulations, such as light-dependent degradation of ROC15, probably contribute more to the robust protein oscillations (Fig 6A). However, it is obvious that ROC75 has a role to keep ROC15 and ROC40 mRNA levels low during the day phase after their light-dependent downregulations at dawn (Figs 4A and 4B, 5B). This role is likely to contribute to prevent ROC15 protein accumulation in premature dark conditions (Fig 7B), suggesting that the second role of ROC75, i.e. maintenance of the subjective day state, is significant for the circadian clock even in the LD condition. In natural LD cycles, the light period is often disturbed by darkness due to cloudiness or shade. ROC75 may contribute to keeping time by preventing unexpected ROC15 accumulation in such situations.

Possible additional components of the transcriptional loop of C. reinhardtii circadian clock

ROC59 and CrPRR1 are noteworthy among the target genes of ROC75. Although ROC59 has already been identified as a clock-related gene [25], genetic interaction with ROC75 strengthens the importance of ROC59 in the C. reinhardtii clock. ROC59 encodes a protein harboring several WD40 and tetratricopeptide repeats similar to the evolutionarily conserved antiobesity genes, ASG2 (Altered Seed Germination 2) in higher plants, ADP (antiobesity factor ADIPOSE) in flies, and WDTC1 (WD40 and TPR 1) in humans [25,43]. These genes are known to be involved in fat metabolism [43], but none of them has yet been described as a clock component. Because WDTC1 is known to regulate the transcriptional activities of the genes involved in adipogenesis through histone modifications [44,45], ROC59 might have a function in the epigenetic regulation of the circadian clock in C. reinhardtii.

The CrPRR1 gene encodes a homolog of the O. tauri and A. thaliana clock protein, TOC1 [6,22]. The expression of CrPRR1 peaked at dusk under LD condition and at early subjective night under LL and DD conditions (Fig 4E), indicating that the evening-phased expression is conserved in C. reinhardtii. Investigating whether CrPRR1 is involved in the circadian oscillator function or one of the output pathways from the oscillator in the C. reinhardtii clock would be necessary in understanding the evolutionary history of circadian clocks in green plants.

GARP transcription factors in the plant circadian clocks

In this study, we demonstrate that ROC75 is a daytime component of the C. reinhardtii clock that represses the mRNA expression of night-phased clock genes (e.g., ROC15 and ROC40). This is in contrast to the case of A. thaliana LUX (PCL1) which is a nighttime repressor [12]. The features of ROC75 and LUX (PCL1) are summarized in Table 1. They also show sharp contrasts in their mutant phenotypes: An arrhythmic phenotype was observed in the roc75 mutant under DD conditions (Fig 1B and 1D) [25] but in lux/pcl1 mutants, it is observed under LL conditions [10,11]. In addition, a weak rhythm phenotype was observed under LL conditions in roc75 (Fig 1A and 1D) but under DD conditions in the CCR2::LUC reporter in lux mutant [10]. On the other hand, both the mutants (roc75 and lux) showed normal rhythm under LD conditions at least in some of the processes (Figs 1C, 1D and 6A) [10]. Meanwhile, O. tauri genome [46] has GARP protein genes, and one of them encodes a LUX-like protein (ostta12g01420). Although mutant phenotypes and the effect of misexpression have not been reported to date, the mRNA expression of this gene is evening-phased under LD conditions [47], similar to that of LUX (PCL1) and BOA (NOX) [10,11,15], in contrast to that of ROC75 (Fig 2A, 2C and 2D) [25]. One possibility is that C. reinhardtii has developed a contrasting mechanism of operating the circadian clock to that of A. thaliana and O. tauri. Consistent with this notion, the effect of changes in the casein kinase 1 activity on the circadian clock also shows a sharp contrast; the circadian rhythm is shortened by an RNAi-mediated knockdown in C. reinhardtii [48], whereas it is lengthened by specific inhibitor treatments or misexpression in A. thaliana and O. tauri [49,50].

**Tab. 1. Comparison of ROC75 and LUX (PCL1).**

It is still unclear to what extent the C. reinhardtii clock is similar to the other plant clocks in the network architectures of the circadian transcriptional loops. This study indicates that at least the relationship between GARP proteins (ROC75 and LUX [PCL1]) and MYB transcription factor genes (ROC40 and CCA1/LHY) is different between C. reinhardtii and A. thaliana. In C. reinhardtii, ROC40 is a direct target of ROC75, and therefore, its expression is constantly high in the roc75 mutant (Fig 4B). In contrast in A. thaliana, the expression of CCA1/LHY is indirectly regulated by LUX (PCL1) via PRR9 [12]. Since PRR9 is a transcriptional repressor [14], LUX (PCL1) act as an indirect activator of CCA1/LHY. The expression of CCA1/LHY is, therefore, constantly low in lux/pcl1 mutants [10,11].

Since Prasinophyceae is an early-diverging class within the green plant lineage [16], the reduced circadian system in O. tauri [20,21] seems to have retained the primitive features of plant circadian clocks. The evening-loop may be the original position of GARP transcription factor in the plant circadian clocks, and the day-loop, such as ROC75, may be a newly acquired loop in the Chlorophyceae, including C. reinhardtii. Further comparative analyses among the three models, C. reinhardtii, O. tauri and A. thaliana, will provide insight into the evolution of the circadian clocks in the green plant lineage.

Materials and methods

Strains and transformation

In this study, we used the following C. reinhardtii strains: CBR (WT strain) [25], roc75 and roc114 (clock mutants [25]), ROC15-LUC, ROC40-LUC, ROC66-LUC, and ROC75-LUC (reporter strains expressing clock protein-luciferase fusion protein [35]). The CBR, roc75, and roc114 strains have the tufA-lucCP reporter gene in their chloroplast genome [36]. The strains were maintained on agar plates of Tris-acetate-phosphate (TAP) medium [51] under constant illumination (10 μmol/m²/s).

The ROC75-HA, ROC75-YFP, ROC75-SRDX, ROC75-VP64 and ROC75-GR strains were generated by transformation of the roc75 mutant. To generate transforming DNAs, artificially synthesized DNA fragments encoding HA, YFP, SRDX, VP64, and GR were cloned into the FseI site of the pSI103PL/ROC75 plasmid [25] via ligation or In-Fusion assembly. The plasmids were digested with PacI, and the fragments containing the tagged ROC75 gene and the aphVIII selectable marker gene were used for transformation. The transformation was performed as described previously [35,52,53].

Bioluminescence rhythm assay

The bioluminescence rhythm of spot cultures of reporter cells in white 96-well plates was monitored as described previously [25] except for the experiment in Fig 8B where we used spot cultures in black 24-well plates and a bioluminescence monitoring apparatus CL24-LIC (Churitsu Electric Corp., Nagoya, Japan). The circadian parameters (period, phase, and amplitude) were calculated by the cosinor method of the Rhythm Analyzing Program [54]. The amplitude was estimated from the overall average best-fitting cosinor curves between the second and the fifth day of bioluminescence monitoring. To monitor the clock protein-luciferase fusion reporters (Figs 2D, 6 and 7 and S3 Fig), we used AkaLumine-HCl (FUJIFILM Wako Pure Chemical Corporation, Osaka, Japan) [55] as the substrate because the bioluminescence rhythm was more stable against environmental disturbances (e.g., light on/off, drying of agar, vibration of culture plates).

Genetic crosses

Genetic crosses were carried out as described previously [25]. The progeny were screened by bioluminescence and antibiotic resistance, and the genotype was confirmed by genomic PCR.

Culture conditions

1) Batch TAP culture:

Cells were inoculated in TAP medium at a concentration of 1 × 10⁵ cells/mL and incubated at 24°C under LD conditions (12-h light:12-h dark; 30 μmol/m²/s) for 2–3 days.

2) Batch HS culture:

Two flasks of cells that were 12-h out-of-phase were prepared. The light and temperature schedules for LL, DD, and LD conditions are summarized in S11A–S11C Fig. The cells were inoculated into high-salt (HS) medium [56] at a concentration of 2 × 10⁵ cells/mL and incubated at 24°C under LL conditions (30 μmol/m²/s) for 3 days. After synchronization of the circadian clock employing both a temperature shift to 17°C and a 12-h dark exposure, the cultures were kept under the LL, DD, or LD condition. The cells were harvested at the indicated time points (24 to 72 h). The overlapping time points between the two flasks (36, 48, and 60 h) were used to validate the flask-to-flask variation. The sample collection during the dark period was done under safe, very low-intensity (less than 0.01 μmol/m²/s) blue LED light. Air was bubbled through the cultures exposed to the DD condition to ensure a stable circadian rhythm. No growth was observed even in the LL cultures (S11D Fig), ruling out the possibility of cell cycle-dependent rhythms.

3) Continuous culture:

The continuous culture was carried out as described previously [25].

Western blot

Continuous culture (5 mL, 1-2x10⁷ cells) was harvested by centrifugation. Protein extraction and Western blot were carried out as described previously [39].

Immunocytochemical staining

Batch TAP culture (1 mL, 0.5-1x10⁷ cells) was harvested by centrifugation. Immunocytochemical staining were carried out as described previously [39].

RT-qPCR

Batch HS culture (5 mL, 1-2x10⁷ cells) was harvested by centrifugation. RNA extraction and RT-qPCR was carried out as described previously [39]. Data were normalized with respect to the expression level of RCK1. The sequences of primers used in the study are provided in S2 Table.

YFP fluorescence imaging

A small aliquot (few microliters) of the batch TAP culture was dropped onto a cover slip and the drop was covered with a small piece (approximately 10 mm × 10 mm) of plastic wrap. C. reinhardtii cells were concentrated and immobilized in the wrinkles formed in the plastic wrap. The YFP fluorescence of the immobilized cells was observed with an inverted fluorescence microscope (IX70, Olympus) equipped with a CCD camera (DS-5M, Nikon).

ChIP-seq and ChIP-qPCR

Cells (2.5x10⁸) were harvested from batch TAP culture by centrifugation. The cells were cross-linked for 5 min with 1% formaldehyde and then quenched by adding glycine to a concentration of 0.15 M. The cells were washed once with Tris-buffered saline and then lysed in ChIP lysis buffer (50 mM Tris-HCl pH 8.0, 10 mM EDTA, 1% SDS, 0.5 mM phenylmethylsulfonyl fluoride, 10 μL/mL of plant protease inhibitor cocktail [Sigma-Aldrich]). The chromatin was sheared by a sonicator (Bioruptor [CosmoBio, Tokyo, Japan]) at the maximum output for 30 sec for 30 cycles. The sonicated lysates were diluted ten times with ChIP dilution buffer (50 mM Tris-HCl pH 8.0, 167 mM NaCl, 1.1% Triton X-100, 0.11% sodium deoxycholate, 0.5 mM phenylmethylsulfonyl fluoride, 10 μL/mL of plant protease inhibitor cocktail [Sigma-Aldrich]). The HA-tagged protein-DNA complexes were precipitated with protein-G coupled magnetic beads (Dynabeads, Thermo Fisher Scientific) coated with an anti-HA antibody (MBL, Nagoya, Japan; 561–5, rabbit polyclonal). The precipitants were washed once with ChIP wash buffer I (50 mM Tris-HCl pH 8.0, 150 mM NaCl, 1 mM EDTA, 1% Triton X-100, 0.1% SDS, 0.1% sodium deoxycholate), once with ChIP wash buffer II (50 mM Tris-HCl pH 8.0, 500 mM NaCl, 1 mM EDTA, 1% Triton X-100, 0.1% SDS, 0.1% sodium deoxycholate), once with ChIP LiCl wash buffer (10 mM Tris-HCl pH 8.0, 0.25 M LiCl, 1 mM EDTA, 0.5% NP-40, 0.5% sodium deoxycholate), and twice with TE buffer (10 mM Tris-HCl pH 8.0, 1 mM EDTA), and then eluted with ChIP direct elution buffer (10 mM Tris-HCl pH 8.0, 300 mM NaCl, 5 mM EDTA, 0.5% SDS). After reversal of the cross-links by incubation at 65°C for 4 h, RNA digestion using RNaseA (20 μg/mL), and protein digestion using proteinase K (50 μg/mL), the DNA fragments were purified by phenol-chloroform extraction and ethanol precipitation.

The fragment libraries were constructed using the SOLiD fragment library construction kit (Thermo Fisher Scientific) according to the manufacture’s protocol, except for the purification steps that were carried out using the Agencourt AMPure XP Kit (Beckman Coulter). The pooled library was sequenced by multiplex paired-end sequencing on a flow cell using the 5500xl SOLiD system (Life Technologies, Waltham, MA, USA). The sequence reads were mapped to the reference genome of C. reinhardtii v 5.5 (Joint Genome Institute) [57] using Bioscope (version 1.2, Applied Biosystems SOLiD System). The total number of reads and mapped reads in each experiment are summarized in S3 Table. Mapping data has been registered in the DDBJ Sequence Read Archive (https://www.ddbj.nig.ac.jp/dra/index.html) under the accession numbers from DRR203090 to DRR203093. Peaks were detected by the peak calling algorithm for ChIP-seq analysis of CLC Genomics Workbench (version 7.5.1, Qiagen). To confirm the specificity of the detected peaks, we selected the peaks that were common in two biological replicates, and all the selected peaks were visually confirmed by comparing with the input DNA controls.

Quantitative PCR of ChIP DNA was performed using Fast SYBR Green I Master Mix (Thermo Fisher Scientific) and StepOnePlus (Thermo Fisher Scientific) according to the manufacture’s procedure. The primers used are provided in S2 Table.

Preparation of the Glutathione-S-transferase (GST)-GARP protein and EMSA

The GST-GARP protein was expressed in the E. coli strain BL21 (DE3) cultured in LB and Terrific Broth media, supplemented with ampicillin (50 μg/mL). The cells were harvested by centrifugation, resuspended in 50 mM Tris-HCl buffer (pH 8.0) containing 50 mM NaCl, 1 mM EDTA, and 1 mM dithiothreitol (DTT), and disrupted by sonication. The lysates were clarified by centrifugation, and a GST-fused form of GARP was prepared from the lysates using Glutathione Sepharose 4B (GE Healthcare) and dialyzed for 12 h against 1 L of 20 mM Tris-HCl buffer (pH 8.0) containing 10 mM NaCl, 0.5 mM EDTA, and 1 mM DTT. The dialysates were applied to a Hitrap DEAE FF column (GE Healthcare) to purify the GST-GARP, and the proteins were further purified by ion-exchange chromatography on a MonoQ HR 5/5 column (GE Healthcare). The GST-GARP was then applied to a Hiload Superdex 75 10/300 GL column (GE Healthcare), equilibrated with 20 mM Tris-HCl (pH 7.5) containing 150 mM NaCl and 1 mM DTT. The concentration of proteins was determined using the Bio-Rad Protein Assay (Bio-Rad Laboratories); bovine serum albumin was used as a standard.

DNA and GST-GARP protein were incubated in Binding buffer (10 mM Tris pH 7.5, 0.1 mM EDTA, 100 mM NaCl, 0.1 mM dithiothreitol), and separated by non-denaturing polyacrylamide (5%) gel electrophoresis in 0.5X Tris-borate EDTA buffer. The DNA bands were stained with SYBR Green I (TaKaRa), and detected using Typhoon FLA9000 (GE Healthcare).

In vitro luciferase assay

The cells were prepared in the same way as described for the bioluminescence rhythm assay. The cell spot on agar piece was flash frozen in liquid nitrogen in a 1.5-mL tube and stored at -80°C. The cell spots were lysed by adding 150 μL of Steady-Glo Luciferase Assay Reagent (Promega) and vortexed for 10 min. After the agar piece settled down, 80 μL of the supernatant was used for monitoring the luminescence in a multilabel plate reader (ARVO X4, PerkinElmer).

Supporting information

S1 Fig [a]
Bioluminescence rhythms of the mutant.

S2 Fig [a]
Generation of the ROC75-HA and ROC75-YFP strains.

S3 Fig [eps]
Complementation of arrhythmicity by the ROC75-LUC gene.

S4 Fig [a]
Location of peaks and the consensus motif of the ROC75-HA targets.

S5 Fig [eps]
ChIP-qPCR analysis of ROC75-HA.

S6 Fig [a]
EMSA of the ROC75 GARP domain.

S7 Fig [eps]
luciferase assay of the ROC15-LUC and ROC40-LUC strains.

S8 Fig [a]
Codon-adapted sequences of SRDX and VP64 for the nuclear genome.

S9 Fig [eps]
A codon-adapted sequence of the hormone-binding domain of rat GR for the nuclear genome.

S10 Fig [eps]
Representative traces of the bioluminescence rhythm of the reporter in ROC75-GR strain.

S11 Fig [a]
Light and temperature schedules of batch HS culture for rhythm analysis.

S1 Table [xlsx]
List of detected genes by ChIP-seq analysis.

S2 Table [xlsx]
List of primers.

S3 Table [xlsx]
Number of sequence reads of ChIP-seq analysis.

Zdroje

1. Spoelstra K, Wikelski M, Daan S, Loudon ASI, Hau M. Natural selection against a circadian clock gene mutation in mice. Proc Natl Acad Sci U S A. 2016;113: 686–691. doi: 10.1073/pnas.1516442113 26715747

2. Ouyang Y, Andersson CR, Kondo T, Golden SS, Johnson CH. Resonating circadian clocks enhance fitness in cyanobacteria. Proc Natl Acad Sci. National Academy of Sciences; 1998;95: 8660–4. doi: 10.1073/pnas.95.15.8660 9671734

3. Young MW, Kay SA. Time zones: A comparative genetics of circadian clocks. Nat Rev Genet. 2001;2: 702–715. doi: 10.1038/35088576 11533719

4. Hsu PY, Harmer SL. Wheels within wheels: The plant circadian system. Trends in Plant Science. 2014. pp. 240–249. doi: 10.1016/j.tplants.2013.11.007 24373845

5. Nohales MA, Kay SA. Molecular mechanisms at the core of the plant circadian oscillator. Nature Structural and Molecular Biology. Nature Publishing Group; 2016. pp. 1061–1069. doi: 10.1038/nsmb.3327 27922614

6. Strayer C, Oyama T, Schultz TF, Raman R, Somers DE, Mas P, et al. Cloning of the Arabidopsis clock gene TOC1, an autoregulatory response regulator homolog. Science (80-). 2000;289: 768–771. doi: 10.1126/science.289.5480.768 10926537

7. Alabadí D, Oyama T, Yanovsky MJ, Harmon FG, Más P, Kay SA. Reciprocal regulation between TOC1 and LHY/CCA1 within the Arabidopsis circadian clock. Science (80-). 2001;293: 880–883. doi: 10.1126/science.1061320 11486091

8. Wang ZY, Tobin EM. Constitutive expression of the CIRCADIAN CLOCK ASSOCIATED 1 (CCA1) gene disrupts circadian rhythms and suppresses its own expression. Cell. 1998;93: 1207–1217. doi: 10.1016/s0092-8674(00)81464-6 9657153

9. Schaffer R, Ramsay N, Samach A, Corden S, Putterill J, Carré IA, et al. The late elongated hypocotyl mutation of Arabidopsis disrupts circadian rhythms and the photoperiodic control of flowering. Cell. 1998;93: 1219–1229. doi: 10.1016/s0092-8674(00)81465-8 9657154

10. Hazen SP, Schultz TF, Pruneda-Paz JL, Borevitz JO, Ecker JR, Kay SA. LUX ARRHYTHMO encodes a Myb domain protein essential for circadian rhythms. Proc Natl Acad Sci U S A. 2005;102: 10387–10392. doi: 10.1073/pnas.0503029102 16006522

11. Onai K, Ishiura M. PHYTOCLOCK 1 encoding a novel GARP protein essential for the Arabidopsis circadian clock. Genes to Cells. 2005;10: 963–972. doi: 10.1111/j.1365-2443.2005.00892.x 16164597

12. Helfer A, Nusinow DA, Chow BY, Gehrke AR, Bulyk ML, Kay SA. LUX ARRHYTHMO encodes a nighttime repressor of circadian gene expression in the Arabidopsis core clock. Curr Biol. 2011;21: 126–133. doi: 10.1016/j.cub.2010.12.021 21236673

13. Nusinow DA, Helfer A, Hamilton EE, King JJ, Imaizumi T, Schultz TF, et al. The ELF4–ELF3–LUX complex links the circadian clock to diurnal control of hypocotyl growth. Nature. 2011;475: 398–402. doi: 10.1038/nature10182 21753751

14. Nakamichi N, Kiba T, Henriques R, Mizuno T, Chua NH, Sakakibara H. PSEUDO-RESPONSE ReGULATORS 9, 7, and 5 are transcriptional repressors in the Arabidopsis circadian clock. Plant Cell. 2010;22: 594–605. doi: 10.1105/tpc.109.072892 20233950

15. Dai S, Wei X, Pei L, Thompson RL, Liu Y, Heard JE, et al. BROTHER OF LUX ARRHYTHMO is a component of the Arabidopsis circadian clock. Plant Cell. 2011;23: 961–972. doi: 10.1105/tpc.111.084293 21447790

16. Lewis LA, McCourt RM. Green algae and the origin of land plants. American Journal of Botany. 2004. pp. 1535–1556. doi: 10.3732/ajb.91.10.1535 21652308

17. Schulze T, Prager K, Dathe H, Kelm J, Kiessling P, Mittag M. How the green alga Chlamydomonas reinhardtii keeps time. Protoplasma. 2010;244: 3–14. doi: 10.1007/s00709-010-0113-0 20174954

18. Matsuo T, Ishiura M. New insights into the circadian clock in Chlamydomonas. International Review of Cell and Molecular Biology. 2010.

19. Matsuo T, Ishiura M. Chlamydomonas reinhardtii as a new model system for studying the molecular basis of the circadian clock. FEBS Letters. 2011. pp. 1495–1502. doi: 10.1016/j.febslet.2011.02.025 21354416

20. Noordally ZB, Millar AJ. Clocks in algae. Biochemistry. American Chemical Society; 2015;54: 171–183. doi: 10.1021/bi501089x 25379817

21. Bouget FY, Lefranc M, Thommen Q, Pfeuty B, Lozano JC, Schatt P, et al. Transcriptional versus non-transcriptional clocks: A case study in Ostreococcus. Marine Genomics. Elsevier; 2014. pp. 17–22. doi: 10.1016/j.margen.2014.01.004 24512973

22. Corellou F, Schwartz C, Motta JP, Djouani-Tahri EB, Sanchez F, Bougeta FY. Clocks in the green lineage: Comparative functional analysis of the circadian architecture of the picoeukaryote ostreococcus. Plant Cell. 2009;21: 3436–3449. doi: 10.1105/tpc.109.068825 19948792

23. Thommen Q, Pfeuty B, Morant PE, Corellou F, Bouget FY, Lefranc M. Robustness of circadian clocks to daylight fluctuations: Hints from the picoeucaryote ostreococcus tauri. PLoS Comput Biol. 2010;6: e1000990. doi: 10.1371/journal.pcbi.1000990 21085637

24. Morant PE, Thommen Q, Pfeuty B, Vandermoere C, Corellou F, Bouget FY, et al. A robust two-gene oscillator at the core of Ostreococcus tauri circadian clock. Chaos. American Institute of Physics Inc.; 2010;20: 045108. doi: 10.1063/1.3530118 21198120

25. Matsuo T, Okamoto K, Onai K, Niwa Y, Shimogawara K, Ishiura M. A systematic forward genetic analysis identified components of the Chlamydomonas circadian system. Genes Dev. 2008;22: 918–930. doi: 10.1101/gad.1650408 18334618

26. Ledger S, Strayer C, Ashton F, Kay SA, Putterill J. Analysis of the function of two circadian-regulated CONSTANS-LIKE genes. Plant J. 2001;26: 15–22. doi: 10.1046/j.1365-313x.2001.01003.x 11359606

27. Heijde M, Zabulon G, Corellou F, Ishikawa T, Brazard J, Usman A, et al. Characterization of two members of the cryptochrome/photolyase family from Ostreococcus tauri provides insights into the origin and evolution of cryptochromes. Plant, Cell Environ. Blackwell Publishing Ltd; 2010;33: 1614–1626. doi: 10.1111/j.1365-3040.2010.02168.x 20444223

28. Djouani-Tahri EB, Christie JM, Sanchez-Ferandin S, Sanchez F, Bouget FY, Corellou F. A eukaryotic LOV-histidine kinase with circadian clock function in the picoalga Ostreococcus. Plant J. 2011;65: 578–588. doi: 10.1111/j.1365-313X.2010.04444.x 21235644

29. Iliev D, Voytsekh O, Schmidt E-M, Fiedler M, Nykytenko A, Mittag M. A heteromeric RNA-binding protein is involved in maintaining acrophase and period of the circadian clock. Plant Physiol. 2006;142: 797–806. doi: 10.1104/pp.106.085944 16920878

30. Dathe H, Prager K, Mittag M. Novel interaction of two clock-relevant RNA-binding proteins C3 and XRN1 in Chlamydomonas reinhardtii. FEBS Lett. 2012;586: 3969–73. doi: 10.1016/j.febslet.2012.09.046 23068615

31. Matsuo T, Iida T, Ishiura M. N-terminal acetyltransferase 3 gene is essential for robust circadian rhythm of bioluminescence reporter in Chlamydomonas reinhardtii. Biochem Biophys Res Commun. 2012;418: 342–346. doi: 10.1016/j.bbrc.2012.01.023 22266323

32. Müller N, Wenzel S, Zou Y, Künzel S, Sasso S, Weiß D, et al. A plant cryptochrome controls key features of the chlamydomonas circadian clock and its life cycle. Plant Physiol. American Society of Plant Biologists; 2017;174: 185–201. doi: 10.1104/pp.17.00349 28360233

33. Kottke T, Oldemeyer S, Wenzel S, Zou Y, Mittag M. Cryptochrome photoreceptors in green algae: Unexpected versatility of mechanisms and functions. Journal of Plant Physiology. Elsevier GmbH; 2017. pp. 4–14. doi: 10.1016/j.jplph.2017.05.021 28619534

34. Devlin PF, Kay SA. Cryptochromes are required for phytochrome signaling to the circadian clock but not for rhythmicity. Plant Cell. 2000;12: 2499–2509. doi: 10.1105/tpc.12.12.2499 11148293

35. Niwa Y, Matsuo T, Onai K, Kato D, Tachikawa M, Ishiura M. Phase-resetting mechanism of the circadian clock in Chlamydomonas reinhardtii. Proc Natl Acad Sci U S A. 2013;110: 13666–71. doi: 10.1073/pnas.1220004110 23898163

36. Matsuo T, Onai K, Okamoto K, Minagawa J, Ishiura M. Real-time monitoring of chloroplast gene expression by a luciferase reporter: evidence for nuclear regulation of chloroplast circadian period. Mol Cell Biol. 2006;26: 863–870. doi: 10.1128/MCB.26.3.863-870.2006 16428442

37. Satbhai SB, Yamashino T, Okada R, Nomoto Y, Mizuno T, Tezuka Y, et al. Pseudo-response regulator (PRR) homologues of the moss physcomitrella patens: Insights into the evolution of the prr family in land plants. DNA Res. 2011;18: 39–52. doi: 10.1093/dnares/dsq033 21186242

38. Beel B, Prager K, Spexard M, Sasso S, Weiss D, Müller N, et al. A flavin binding cryptochrome photoreceptor responds to both blue and red light in Chlamydomonas reinhardtii. Plant Cell. 2012;24: 2992–3008. doi: 10.1105/tpc.112.098947 22773746

39. Kinoshita A, Niwa Y, Onai K, Yamano T, Fukuzawa H, Ishiura M, et al. CSL encodes a leucine-rich-repeat protein implicated in red/violet light signaling to the circadian clock in Chlamydomonas. Dutcher SK, editor. PLoS Genet. 2017;13: e1006645. doi: 10.1371/journal.pgen.1006645 28333924

40. Hiratsu K, Matsui K, Koyama T, Ohme-Takagi M. Dominant repression of target genes by chimeric repressors that include the EAR motif, a repression domain, in Arabidopsis. Plant J. 2003;34: 733–739. doi: 10.1046/j.1365-313x.2003.01759.x 12787253

41. Beerli RR, Segal DJ, Dreier B, Barbas CF. Toward controlling gene expression at will: Specific regulation of the erbB-2/HER-2 promoter by using polydactyl zinc finger proteins constructed from modular building blocks. Proc Natl Acad Sci U S A. 1998;95: 14628–14633. doi: 10.1073/pnas.95.25.14628 9843940

42. Simon R, Igeno MI, Coupland G. Activation of floral meristem identity genes in Arabidopsis. Nature. 1996;384: 59–62. doi: 10.1038/384059a0 8900276

43. Ducos E, Vergès V, de Bernonville TD, Blanc N, Giglioli-Guivarc’h N, Dutilleul C. Remarkable evolutionary conservation of antiobesity ADIPOSE/WDTC1 homologs in animals and plants. Genetics. 2017;207: 153–162. doi: 10.1534/genetics.116.198382 28663238

44. Groh BS, Yan F, Smith MD, Yu Y, Chen X, Xiong Y. The antiobesity factor WDTC 1 suppresses adipogenesis via the CRL 4 WDTC 1 E3 ligase. EMBO Rep. 2016;17: 638–647. doi: 10.15252/embr.201540500 27113764

45. Suh JM, Zeve D, McKay R, Seo J, Salo Z, Li R, et al. Adipose Is a Conserved Dosage-Sensitive Antiobesity Gene. Cell Metab. 2007;6: 195–207. doi: 10.1016/j.cmet.2007.08.001 17767906

46. Derelle E, Ferraz C, Rombauts S, Rouzé P, Worden AZ, Robbens S, et al. Genome analysis of the smallest free-living eukaryote Ostreococcus tauri unveils many unique features. Proc Natl Acad Sci U S A. National Academy of Sciences; 2006;103: 11647–11652. doi: 10.1073/pnas.0604795103 16868079

47. Monnier A, Liverani S, Bouvet R, Jesson B, Smith JQ, Mosser J, et al. Orchestrated transcription of biological processes in the marine picoeukaryote Ostreococcus exposed to light/dark cycles. BMC Genomics. BioMed Central Ltd.; 2010;11: 192. doi: 10.1186/1471-2164-11-192 20307298

48. Schmidt M, Gessner G, Luff M, Heiland I, Wagner V, Kaminski M, et al. Proteomic analysis of the eyespot of Chlamydomonas reinhardtii provides novel insights into its components and tactic movements. Plant Cell. 2006;18: 1908–30. doi: 10.1105/tpc.106.041749 16798888

49. Uehara TN, Mizutani Y, Kuwata K, Hirota T, Sato A, Mizoi J, et al. Casein kinase 1 family regulates PRR5 and TOC1 in the Arabidopsis circadian clock. Proc Natl Acad Sci. 2019;116: 11528–11536. doi: 10.1073/pnas.1903357116 31097584

50. van Ooijen G, Hindle M, Martin SF, Barrios-Llerena M, Sanchez F, Bouget FY, et al. Functional Analysis of Casein Kinase 1 in a Minimal Circadian System. PLoS One. 2013;8: e70021. doi: 10.1371/journal.pone.0070021 23936135

51. Gorman DS, Levine RP. Cytochrome f and plastocyanin: their sequence in the photosynthetic electron transport chain of Chlamydomonas reinhardi. Proc Natl Acad Sci U S A. 1965;54: 1665–9. doi: 10.1073/pnas.54.6.1665 4379719

52. Shimogawara K, Fujiwara S, Grossman A, Usuda H. High-efficiency transformation of Chlamydomonas reinhardtii by electroporation. Genetics. 1998;148: 1821–8. 9560396

53. Yamano T, Iguchi H, Fukuzawa H. Rapid transformation of Chlamydomonas reinhardtii without cell-wall removal. J Biosci Bioeng. 2013;115: 691–694. doi: 10.1016/j.jbiosc.2012.12.020 23333644

54. Okamoto K, Onai K, Ishiura M. RAP, an integrated program for monitoring bioluminescence and analyzing circadian rhythms in real time. Anal Biochem. 2005;340: 193–200. doi: 10.1016/j.ab.2004.11.007 15840491

55. Kuchimaru T, Iwano S, Kiyama M, Mitsumata S, Kadonosono T, Niwa H, et al. A luciferin analogue generating near-infrared bioluminescence achieves highly sensitive deep-tissue imaging. Nat Commun. 2016;7: 11856. doi: 10.1038/ncomms11856 27297211

56. Sueoka N. Mitotic replication of deoxiribonucleic acid in Chlamydomonas reinhardti. Proc Natl Acad Sci U S A. 1960;46: 83–91. doi: 10.1073/pnas.46.1.83 16590601

57. Merchant SS, Prochnik SE, Vallon O, Harris EH, Karpowicz SJ, Witman GB, et al. The Chlamydomonas Genome Reveals the Evolution of Key Animal and Plant Functions. Science. 2007;318: 245–250. doi: 10.1126/science.1143609 17932292

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