UVR8-mediated inhibition of shade avoidance involves HFR1 stabilization in Arabidopsis

Authors: Eleni Tavridou ^aff001; Emanuel Schmid-Siegert ^aff003; Christian Fankhauser ^aff004; Roman Ulm ^aff001
Authors place of work: Department of Botany and Plant Biology, Section of Biology, Faculty of Science, University of Geneva, CH, Geneva, Switzerland ^aff001; Institute of Genetics and Genomics of Geneva (iGE3), University of Geneva, Geneva, Switzerland ^aff002; SIB-Swiss Institute of Bioinformatics, University of Lausanne, CH, Lausanne, Switzerland ^aff003; Center for Integrative Genomics, Faculty of Biology and Medicine, University of Lausanne, CH, Lausanne, Switzerland ^aff004
Published in the journal: UVR8-mediated inhibition of shade avoidance involves HFR1 stabilization in Arabidopsis. PLoS Genet 16(5): e32767. doi:10.1371/journal.pgen.1008797
Category: Research Article
doi: https://doi.org/10.1371/journal.pgen.1008797

Summary

Sun-loving plants perceive the proximity of potential light-competing neighboring plants as a reduction in the red:far-red ratio (R:FR), which elicits a suite of responses called the “shade avoidance syndrome” (SAS). Changes in R:FR are primarily perceived by phytochrome B (phyB), whereas UV-B perceived by UV RESISTANCE LOCUS 8 (UVR8) elicits opposing responses to provide a counterbalance to SAS, including reduced shade-induced hypocotyl and petiole elongation. Here we show at the genome-wide level that UVR8 broadly suppresses shade-induced gene expression. A subset of this gene regulation is dependent on the UVR8-stabilized atypical bHLH transcription regulator LONG HYPOCOTYL IN FAR-RED 1 (HFR1), which functions in part redundantly with PHYTOCHROME INTERACTING FACTOR 3-LIKE 1 (PIL1). In parallel, UVR8 signaling decreases protein levels of the key positive regulators of SAS, namely the bHLH transcription factors PHYTOCHROME INTERACTING FACTOR 4 (PIF4) and PIF5, in a COP1-dependent but HFR1-independent manner. We propose that UV-B antagonizes SAS via two mechanisms: degradation of PIF4 and PIF5, and HFR1- and PIL1-mediated inhibition of PIF4 and PIF5 function. This work highlights the importance of typical and atypical bHLH transcription regulators for the integration of light signals from different photoreceptors and provides further mechanistic insight into the crosstalk of UVR8 signaling and SAS.

Keywords:

Gene expression – Seedlings – Transcriptional control – Hypocotyl – Regulator genes – White light – Marker genes – Ultraviolet B

Introduction

Plants have evolved sophisticated sensory systems to respond and adapt appropriately to the environment. Light, in addition to being an energy source, is an important source of information about the environment for plants. Specific photoreceptors allow the detection of changes in light quality, duration, direction, and intensity, which is crucial to optimize photosynthesis, growth, and development, as well as to cope with light stress [1,2]. For example, plants growing in close proximity to their neighbors are able to sense that light resources may become limiting and preemptively elicit a suite of responses to avoid future shading, collectively known as shade avoidance syndrome (SAS) [3,4]. SAS promotes petiole and stem elongation so that a plant can outcompete its neighbors for light. SAS can be triggered in high PAR (photosynthetically active radiation) conditions through alterations in spectral composition and due to foliage properties. Photosynthetic pigments strongly absorb red (R) and blue (B) light and preferentially reflect or transmit far-red (FR) light. Thus, plants perceive a reduction in R:FR due to the scattering of FR from non-shading neighbors and initiate SAS [3,5].

Changes in R:FR are perceived by phytochrome B (phyB), which interconverts between an inactive (PrB) and an active (PfrB) state. Under high R:FR, the phyB photoequilibrium is shifted towards the active PfrB conformer that interacts with bHLH transcription factors of the Phytochrome Interacting Factor (PIF) family, including PIF4 and PIF5 that play a major role in shade responses [4,6,7]. Upon interaction with active PfrB, PIF4 and PIF5 are phosphorylated and targeted for proteasomal degradation, hence reducing the expression of shade response-associated genes [8,9]. However, under low R:FR, phyB is primarily in the inactive PrB state and unable to interact with and repress PIFs, thus allowing PIF-mediated activation of shade-response genes [8]. PIFs’ main targets are other transcription regulators mainly involved in auxin signaling and cell elongation [10] as well as additional bHLH transcription regulators including PHYTOCHROME INTERACTING FACTOR 3-LIKE 1 (PIL1) and LONG HYPOCOTYL IN FAR-RED1 (HFR1). HFR1 provides a negative feedback loop by interacting with PIF4 and PIF5 and forming non-functional heterodimers that can no longer bind to DNA, thus preventing an exaggerated shade response [11].

Ultraviolet-B (UV-B) is perceived by the UV RESISTANCE LOCUS 8 (UVR8) photoreceptor [12]. Upon UV-B exposure, UVR8 monomerises and interacts with CONSTITUTIVELY PHOTOMORPHOGENIC 1 (COP1) to trigger downstream signaling [12–14]. COP1 is an E3 ubiquitin ligase that targets for proteasomal degradation transcriptional regulators that generally promote light responses and photomorphogenesis [15–17]. Interaction of activated UVR8 with COP1 leads to COP1 inactivation and thus accumulation of COP1 target proteins, such as the bZIP transcription factor ELONGATED HYPOCOTYL 5 (HY5) [13,18,19]. Stabilized HY5 is crucial for the regulation of numerous UV-B-induced genes, including those that function in UV-B acclimation and tolerance [14,20–26]. UV-B photomorphogenesis involves the inhibition of hypocotyl elongation and in general elicits opposite responses to shade signals [13,27–31]. For example, UV-B was shown to antagonize auxin signaling and suppress shade-induced hypocotyl and petiole elongation, as well as shade marker gene induction [28,32–35]. Molecularly, UVR8 activity was associated with the degradation of PIF4 and PIF5 [27,28,32,36], the key inducers of SAS [3,8,37]. It was recently postulated that COP1 directly interacts with PIF5, causing PIF5 stabilization by an unknown mechanism [32]. Active UVR8 disrupts this stabilization through interaction with COP1, triggering PIF5 instability under UV-B [32]. In parallel, UV-B-stabilized DELLA proteins may form non-DNA-binding heterodimers with PIFs and stabilized HY5 may compete with PIFs for the same promoters [28,38–41]. Notwithstanding the abovementioned studies, the molecular mechanisms by which UVR8 signaling antagonizes SAS remain poorly understood.

Here we show that UV-B-activated UVR8 leads to the stabilization of the COP1 substrate HFR1, partially accounting for the UV-B-mediated suppression of shade marker gene induction. Furthermore, our data suggest that HFR1 acts cooperatively with PIL1 in the UV-B-mediated suppression of SAS. Moreover, PIF4 and PIF5 binding to promoters of shade-induced genes is reduced under supplemental UV-B, in agreement with the activity of HFR1 as well as the degradation of PIF4 and PIF5 under these conditions.

Results

UVR8-dependent stabilization of HFR1 suppresses induction of shade marker genes

As HFR1 is a COP1 substrate and activated UVR8 inactivates COP1 [17,18,42–45], we hypothesized that HFR1 stability is regulated by UVR8 in response to UV-B, which may contribute to the antagonistic effect of UV-B on SAS. We thus tested the effect of UV-B and low R:FR on HFR1 promoter-driven HFR1-HA protein levels in an uvr8 null mutant background compared to in a wild-type background. Seven-day-old seedlings were irradiated at Zeitgeber time ZT3 with 3-h supplemental UV-B (+UVB), 3-h supplemental FR to create low R:FR (+FR), or a combination of the two treatments (+UVB+FR), and compared to seedlings maintained in white light as control (WL; -UVB-FR). Low R:FR treatment slightly increased HFR1-HA protein level, both in the absence and presence of UVR8, whereas HFR1 exhibited greater stabilization under UV-B which was UVR8 dependent (Fig 1A). Moreover, UV-B and low R:FR stabilized HFR1 in an additive manner (Fig 1A). HFR1 accumulation was associated with only a weak transcriptional activation of HFR1 under UV-B (S1 Fig). These results indicate that active UVR8 signaling leads to post-translational HFR1 stabilization, likely through COP1 inhibition.

**Fig. 1. UVR8-dependent stabilization of HFR1 suppresses activation of shade marker genes.**
(A) Anti-HA immunoblot analysis of HFR1-HA levels in 7-day-old Col/Pro_HFR1:HFR1-3xHA (HFR1-HA) and *uvr8-6*/Pro_HFR1:HFR1-3xHA (*uvr8*/HFR1-HA) seedlings grown in long-day conditions under white light (WL) or white light supplemented at ZT3 with 3-h UV-B (+UVB), low R:FR (+FR), or a combination of both (+FR+UVB). Wild type (Col) is shown as negative control. The immunoblot was re-probed with anti-UVR8, as well as anti-actin as loading control. (B–E) RT-qPCR analysis of (B) *PIL1*, (C) *XTR7*, (D) *ATHB2*, and (E) *IAA29* expression in 7-day-old wild-type (Col), *uvr8-6*, and *hfr1-101* seedlings grown under white light and exposed to either UV-B (+UVB), low R:FR (+FR), or both (+FR+UVB) for 3 h or maintained under white light (WL). Error bars represent SEM of three biological replicates. Asterisks indicate a significant difference in transcript abundance compared to that under WL in each genotype (* p < 0.05; ** p < 0.01).

To test the contribution of HFR1 to UVR8-mediated suppression of low R:FR response, we analyzed shade-induced expression of shade marker genes PIL1, XYLOGLUCAN ENDOTRANSGLYCOSYLASE 7 (XTR7), ARABIDOPSIS THALIANA HOMEOBOX PROTEIN 2 (ATHB2), and INDOLE-3-ACETIC ACID INDUCIBLE 29 (IAA29) in uvr8 and hfr1 mutants in comparison to that in wild type. In each genotype, all four tested genes showed induced expression in response to low R:FR (+FR, shade), which was strongly suppressed by supplemental UV-B (+FR+UVB) in wild type but not in uvr8 (Fig 1B–1E). Interestingly, UV-B suppression of shade-induced PIL1 and ATHB2 expression was also absent in hfr1, comparable to that in uvr8 (Fig 1B and 1D). However, the HFR1-dependent UV-B effect was found to be gene specific, as the other tested shade marker genes XTR7 and IAA29 were repressed by UV-B in hfr1 (Fig 1C and 1E). These data show that HFR1 is required to repress a subset of shade-induced genes in response to UV-B.

UVR8 broadly suppresses shade gene induction

To investigate the extent of UVR8- and HFR1-dependent UV-B repression of shade-induced gene expression at the genome-wide level, we performed an RNA-Seq analysis comparing uvr8 and hfr1 transcriptomes with that of wild type under WL, +FR, +UVB, and +FR+UVB conditions. Shade significantly induced 315, 330, and 365 genes in wild type, uvr8, and hfr1, respectively (fold change > 2 and p < 0.05, with FDR 5%), with an overlap of 204 robustly shade-induced genes (Fig 2A and 2B, S1A–S1C and S2 Tables). The shade induction of 77% of the shade-induced genes (+FR versus WL) was repressed by supplemental UV-B in wild type (i.e. no or less induction under +FR+UVB versus +FR) (Fig 2A). This repression by UV-B was UVR8 dependent, as a minimal proportion of shade-induced genes was UV-B suppressed in uvr8 mutants (<2%) (Fig 2A). In hfr1, 58% of the shade-induced genes were repressed by UV-B treatment, which is significantly less than in wild type (Fig 2A). Indeed, among the 204 shade-induced genes common to all three genotypes, a cluster of 44 genes was found to be similarly regulated as PIL1: shade induced and UVB suppressed in wild type, but not in uvr8 and hfr1 (herein referred to as the PIL1-like cluster) (Fig 2C, S3 Table). In two independent hfr1 mutant lines, reverse transcription quantitative PCR (RT-qPCR) analysis of two selected genes from the PIL1-like cluster, SULFOTRANSFERASE 2A (ST2A) and FLOWERING PROMOTING FACTOR 1-LIKE PROTEIN 1 (FLP1), supported an essential role of HFR1 in the UV-B-repressive effect on their shade-induced expression (Fig 2D and 2E). Our data suggest that the antagonizing effect of UV-B on shade-responsive gene expression is broad at the genome-wide level, fully dependent on UVR8, and dependent on HFR1 for a subset of genes.

**Fig. 2. UV-B-activated UVR8 broadly suppresses shade-responsive gene expression.**
(A) Pie charts showing the percentage and number of shade-induced genes that are repressed by UV-B (FC > 2, adjusted pvalue < 0.05) in wild type (Col), *uvr8-6*, and *hfr1-101* seedlings. (B) Venn diagram representing the intersection between shade-induced genes in wild type (Col +FR/WL ↑), *uvr8-6* (*uvr8* +FR/WL↑), and *hfr1-101* (*hfr1* +FR/WL ↑) seedlings (FC > 2, adjusted pvalue < 0.05). (C) Venn diagram representing the intersection between shade-induced genes that are repressed by UV-B in a UVR8-dependent manner in wild type (Col) but not in *hfr1-101* (FC > 2, adjusted pvalue < 0.05). The intersection of 44 genes is referred to as the *PIL1* cluster. (D, E) RT-qPCR analysis of (D) *ST2A* and (E) *FLP1* expression in 7-day-old Col, *hfr1-101*, and *hfr1-4* seedlings grown under the indicated light conditions for 3 h. Error bars represent SEM of three biological replicates. Asterisks indicate a significant difference compared to that under WL in each genotype (* p < 0.05; ** p < 0.01).

HFR1 and PIL1 act redundantly in UV-B suppression of shade-induced gene expression

Similar to HFR1, PIL1 is a negative regulator of shade responses and targeted for proteasomal degradation by COP1 [46,47]. As PIL1 is not UV-B repressed in hfr1 mutants, we tested whether PIL1 plays a redundant role with HFR1, particularly in the regulation of the subset of genes that are UV-B repressed in an HFR1-independent manner, as exemplified by the FAR-RED-ELONGATED HYPOCOTYL1-LIKE (FHL) gene. In agreement with the RNA-Seq data, FHL expression was induced under +FR and this expression induction was repressed by UV-B under +FR+UVB in wild type as well as in pil1 and hfr1 single mutants, although to a reduced extent in the latter (Fig 3A). By contrast, however, FHL shade-induced expression was not reduced by UV-B in the hfr1 pil1 double mutant (Fig 3A). This was observed to a much lesser extent for two further HFR1-independent marker genes, YUCCA8 (YUC8) and GH3.3 (S2A and S2B Fig). PIL2, a marker gene for which the UV-B-repressive effect on its shade-induced expression depends on HFR1, was typically repressed in the pil1 single mutant but hyper-induced in the hfr1 pil1 double mutant under +FR+UVB (Fig 3B). These results show that HFR1 and PIL1 play a redundant role in the UV-B repression of, at least, shade-induced FHL expression.

PIL1 and HFR1 act redundantly in UVR8-mediated repression of shade-induced <i>FHL</i> and <i>PIL2</i> expression. — **Fig. 3. PIL1 and HFR1 act redundantly in UVR8-mediated repression of shade-induced *FHL* and *PIL2* expression.**
(A, B) RT-qPCR analysis of (A) *FHL* and (B) *PIL2* expression in 7-day-old seedlings of wild type (Col), *hfr1-101*, *pil1-6*, and *hfr1-101 pil1-6* grown under constant white light (WL) and transferred to the indicated experimental light conditions for 3 h. Error bars represent SEM obtained from three biological replicates. Asterisks indicate the statistical significance compared to WL in each genotype (* p < 0.05; ** p < 0.01).

UVR8 negatively regulates PIF4 and PIF5 levels and chromatin association

In order to understand how activated UVR8 may affect the key shade-response regulators PIF4 and PIF5, we tested the effect of UV-B on protein levels of PIF4-HA and PIF5-HA expressed under the constitutive CaMV 35S-promoter. In agreement with previous data [8,28], PIF4-HA and PIF5-HA accumulated under low R:FR (+FR) and UV-B severely decreased their protein abundances under +FR+UVB conditions (Fig 4A and 4B). UV-B-induced PIF4 and PIF5 degradation was shown to be UVR8 dependent, as their levels were not reduced in the absence of UVR8 (Fig 4A and 4B).

**Fig. 4. UVR8 induces PIF4 and PIF5 degradation in response to UV-B, independently of BOP2.**
Anti-HA immunoblot analysis of HA-tagged PIF4 and PIF5 proteins in 7-day-old seedlings grown in long-day conditions under white light and exposed to low R:FR with (+) or without (-) 3-h supplemental narrowband UV-B at ZT3. Wild type (Col) is shown as negative control. (A) PIF4-HA protein levels were analyzed in Col/Pro_PIF4:PIF4-3xHA (PIF4-HA) and *uvr8-6*/Pro_PIF4:PIF4-3xHA (*uvr8*/PIF4-HA). (B) PIF5-HA protein levels were analyzed in Col/Pro_PIF5:PIF5-3xHA (PIF5-HA) and *uvr8-6*/Pro_PIF5:PIF5-3xHA (*uvr8*/PIF5-HA). (C) PIF4-HA protein levels were analyzed in *pif4-101*/Pro_PIF4:PIF4-3xHA (*pif4*/PIF4-HA) and *pif4-101 bop2-2*/Pro_PIF4:PIF4-3xHA (*pif4 bop2*/PIF4-HA). (D) PIF4-HA protein levels were analyzed in Col/Pro_PIF4:PIF4-3xHA (PIF4-HA) and *cop1-4*/Pro_PIF4:PIF4-3xHA (*cop1-4*/PIF4-HA). Blots were re-probed with anti-UVR8 (A and B) as well as anti-actin as loading control (A–D). Numbers under lanes indicate relative band intensities.

We used pif4/PIF4-HA and pif4 bop2/PIF4-HA lines to determine whether the BOP2 E3 ubiquitin ligase [48] was involved in UV-B-induced PIF4 degradation. However, although higher levels of PIF4-HA were detected in the absence of BOP2 under +FR conditions as expected, supplemental UV-B severely decreased PIF4-HA levels in both the bop2 and wild-type backgrounds (Fig 4C). Moreover, PIF4-HA levels were reduced in cop1-4 mutants compared to that in a wild-type background under +FR, but no UV-B effect could be detected in cop1-4 in agreement with the role of COP1 in UV-B signaling (Fig 4D) [14]. Furthermore, PIF4 and PIF5 expression levels were found to be downregulated by UV-B in a UVR8-dependent but HFR1-independent manner (S3A and S3B Fig). Our data suggest that activated UVR8 is responsible for the decrease in PIF4 and PIF5 levels under +FR+UVB conditions, which, at least in the case of PIF4, is independent of the E3 ubiquitin ligase BOP2.

In response to shade, PIF4 and PIF5 are known to directly bind to G-boxes in the promoters of shade-regulated genes. PIL1 and XTR7 are among those genes known to be direct targets of PIF4 and PIF5 [11,49,50]. Chromatin immunoprecipitation (ChIP) assays showed that UV-B, in a UVR8-dependent manner, abolished PIF4 and PIF5 association with regions of the PIL1, XTR7 and HFR1 promoters that contain G-boxes (Fig 5 and S4 Fig). Collectively, our data suggest that UVR8 signaling impairs PIF4 and PIF5 activities by eliciting their degradation.

**Fig. 5. UV-B impairs PIF4 binding to shade marker genes’ promoters in a UVR8-dependent manner.**
(A) Schematic representation of *PIL1* and *XTR7* with G-boxes and regions amplified in ChIP-qPCR indicated. (B, C) PIF4-HA chromatin association in Col/Pro_PIF4:PIF4-3xHA (PIF4-HA) and *uvr8-6*/Pro_PIF4:PIF4-3xHA (*uvr8*/PIF4-HA). Ten-day-old seedlings were grown in long-day conditions under white light and exposed to low R:FR with (+) or without (-) 3-h supplemental narrowband UV-B at ZT3. ChIP-qPCR was performed for (B) *PIL1* and (C) *XTR7* promoters. ChIP data are presented as the percentage recovered from the total input DNA (% Input). Data shown are representative of three independent biological replicates (see *S5A–S5D Fig*). Error bars represent SD of three technical replicates. Immunoprecipitated DNA was quantified by qPCR using primers in the promoter regions containing G-boxes (region 1, Pro_{PIL1_-1417}; region 3, Pro_{XTR7_-197}) or control regions without G-boxes (region 2, Pro_{PIL1_+1816}; region 4, Pro_{XTR7_-664}).

HFR1 is not involved in the UV-B-mediated downregulation of PIF4 and PIF5

We further tested whether HFR1 could affect the regulation of PIF4 and/or PIF5 protein levels, similar to what has been previously suggested for PIF1 and HFR1 [51]. However, in an hfr1 background, PIF4-HA accumulation under +FR and degradation under +FR+UVB were comparable to that in the wild-type background (Fig 6A and 6B). In agreement, ChIP experiments showed that PIF4-HA chromatin association was reduced in both the hfr1 and wild-type backgrounds under +FR+UVB compared to that under +FR (Fig 6C). Although the effect seems reduced in hfr1 mutants, which would be in agreement with the known activity of HFR1 heterodimerizing with PIF4 and PIF5 [11], this has only been clearly observed in two out of three independent repetitions (Fig 6C, and S5E and S5F Fig). Notwithstanding this, these results illustrate that HFR1 is not required for the UVR8-mediated destabilization of PIF4 and PIF5. Thus, the absence of a UV-B effect on the shade-induced expression of PIL1 in hfr1 implies that the transcriptional regulation of PIL1 and likely PIL1-like cluster genes involves additional molecular players.

**Fig. 6. UV-B-induced PIF4 degradation and reduced association with shade marker genes’ promoters is independent of HFR1.**
(A) Anti-HA immunoblot analysis of PIF4-HA in 7-day-old seedlings grown in long-day conditions under white light and exposed to 3-h low R:FR (+FR) at ZT3 in the presence (+UVB) or absence of supplemental UV-B (-UVB). Wild type (Col) treated with low R:FR is shown as negative control. PIF4-HA protein levels were analyzed in Col/Pro_PIF4:PIF4-3xHA (PIF4-HA) and *hfr1-101*/Pro_PIF4:PIF4-3xHA (*hfr1*/PIF4-HA). Blot was re-probed with anti-actin as loading control. (B) Quantification of the immunoblot shown in (A). Error bars represent SD of three biological replicates. (C) Chromatin association of PIF4-HA in 10-day-old Col/Pro_PIF4:PIF4-3xHA (PIF4-HA) and *hfr1-101*/Pro_PIF4:PIF4-3xHA (*hfr1*/PIF4-HA) seedlings grown in long-day conditions under white light and exposed at ZT3 to 3-h low R:FR with (+) or without (-) supplemental UV-B. Col was included as negative control. ChIP-qPCR was performed for the *PIL1* promoter. ChIP of DNA associated with PIF4-HA is presented as the percentage recovered from the total input DNA (% Input). Data shown are representative of two independent biological replicates (see *S5E and S5F Fig*). Error bars represent SD of three technical replicates. Immunoprecipitated DNA was quantified by qPCR using primers in the promoter region containing a G-box (region 1, Pro_{PIL1_-1417}) or control region without a G-box (region 2, Pro_{PIL1_+1816}). (D) Schematic representation of *PIL1* with G-boxes and regions amplified in ChIP-qPCR indicated.

Discussion

UV-B provides an unequivocal signal for sunlight exposure that inhibits SAS, which is applicable such as upon emergence of plant tissues from a canopy. UV-B perceived by UVR8 broadly suppresses shade-induced gene expression, and inhibits shade-induced hypocotyl and petiole elongation [28,33, and this work]. This study further shows that UVR8-mediated inhibition of the E3 ubiquitin ligase COP1 results in the stabilization of its target protein HFR1, a negative regulator of PIF4 and PIF5 transcription factors. In addition to PIF4 and PIF5 degradation, this mechanism involving HFR1 strongly contributes to UV-B-mediated SAS suppression. Our observations thus identify HFR1 as a molecular effector of UVR8 photoreceptor signaling to antagonize plant shade avoidance.

PIF4 and PIF5 are key bHLH proteins for elongation growth, particularly in response to elevated temperature and shade [4,6,52,53]. The regulation of PIF4 and PIF5 includes their direct interaction with phytochrome and cryptochrome photoreceptors, as well as their light-dependent degradation [8,9,54–56]. Recently, the CUL3^BOP2 E3 ubiquitin ligase complex was shown to ubiquitinate PIF4, thus targeting it for proteasomal degradation [48]. PIF5, on the other hand, has recently been shown to be stabilized by the CUL4^COP1-SPA E3 ubiquitin ligase complex in the dark and in shade, whereas CUL4^COP1-SPA promotes PIF5 ubiquitination in response to red light [32,57]. Interestingly, activated UVR8 was found to disrupt COP1 stabilization of PIF5 in shade, which contributes to PIF5 ubiquitination and degradation under UV-B [27,28,32]. In contrast to phytochrome and cryptochrome mechanisms involving direct protein-protein interactions with PIF4 and PIF5, no direct interaction has been detected between these transcription factors and UVR8 [28,32]. Moreover, whereas UVR8 is known to interact with and inhibit COP1 in response to UV-B [13,17,18], which is linked to PIF5 destabilization [32], our data suggest that PIF4 degradation under UV-B is independent of BOP2, despite clear stabilization of PIF4-HA in the bop2 background under our growth conditions that is in agreement with previously published data [48]. As PIF4 levels are also reduced in cop1-4 mutants and no additional UV-B-mediated degradation is detectable in the absence of functional COP1, COP1-mediated stabilization of PIF4 may be similarly disrupted by activated UVR8, as previously suggested for PIF5 [32]. It is interesting to note that UV-B-mediated degradation of PIF4 is temperature dependent in that it was observed at 20°C but not at the elevated temperature of 28°C in previous work [36]. Notwithstanding this, the E3 ubiquitin ligase for PIF4 and PIF5 ubiquitination and proteasomal degradation under UV-B remains to be identified.

The UVR8 photoreceptor contains a functionally relevant C-terminal domain with a domain that mimics the COP1 interaction domains of COP1 substrates, including that of HFR1 [18,45,58]. Activation of UVR8 results in high-affinity cooperative binding of COP1 through its VP motif and its photosensory domain, which prevents binding of COP1 to HFR1 and thus results in HFR1 stabilization under UV-B [18]. Stabilized HFR1 inhibits the remaining non-degraded PIF4 and PIF5 pool under UV-B through heterodimer formation and inhibition of their binding to DNA [11], thus contributing to the antagonizing effect of UVR8 on both thermomorphogenesis as well as shade responses [36, and this work]. In addition to the two post-translational mechanisms of regulating PIF4 and PIF5 activities, namely degradation and stabilization of the negative regulator HFR1, PIF4 and PIF5 are also transcriptionally repressed by UVR8 and COP1 in response to UV-B [28,32,36] (S3 Fig). The resulting repression of PIF4 and PIF5 activities results in repression of auxin synthesis and responses causing reduced hypocotyl and petiole elongation, thus underlying how UV-B strongly antagonizing SAS and thermomorphogenesis [7,28,34,36].

PIL1 is an early shade-responsive gene encoding the bHLH transcription factor PIL1, which is also targeted for ubiquitination and degradation by COP1 [11,47,59]. Although PIL1 is a well-established negative regulator of SAS, its mechanism of action remains poorly understood. PIL1 was found to interact with PIF5 and to form a negative feedback loop regulating the activity of its own promoter [46]. However, whether PIL1 competes with PIFs for binding to the same G-boxes or forms non-DNA-binding heterodimers, similar to HFR1, remains elusive [46,47]. Independent of the mechanistic aspects, we show that shade-induced PIL1 expression is UV-B repressed in the absence of HFR1. Interestingly, we find that PIL1 acts in partial redundancy with HFR1 to repress shade marker genes in the presence of UV-B (Fig 3). Additional atypical bHLH transcription regulators could be involved in the UV-B suppression of shade responses, such as PHYTOCHROME RAPIDLY REGULATED 1 (PAR1) and PAR2, which are negative regulators of SAS with similar activities as HFR1 [60–62].

Collectively, we show that activated UVR8 broadly represses SAS, and that this is associated with negative regulation of PIF4 and PIF5 protein levels and activities, the latter likely involving HFR1 and PIL1 as inhibitors of PIF4 and PIF5. The involvement of additional PIF4 and/or PIF5 inhibitors in UVR8 repression of SAS remains to be investigated. In addition to the exposure of plants to full sunlight, SAS is also inhibited by sunflecks through phytochrome-, cryptochrome- and UVR8-mediated induction of the bZIP transcription factors HY5 and HYH [63,64]. The involvement of PIF4 and PIF5, as well as HFR1, under such conditions remains to be investigated and will contribute to our mechanistic understanding of SAS repression by a complex photoreceptor and signaling network.

Materials and methods

Plant material and generation of transgenic lines

The uvr8-6 [13], cop1-4 [65], hfr1-101 (formerly rsf1) [66], hfr1-4 [67], and pil1-6 [46] mutants are in the Columbia (Col) accession. The hfr1-101 pil1-6 double mutant was generated by genetic crossing followed by PCR genotyping of F2 plants (S4 Table).

hfr1-101/Pro_HFR1:HFR1-3xHA, pif5-1/Pro_PIF5:PIF5-3xHA, pif4-101/Pro_PIF4:PIF4-3xHA, and pif4-101 bop2-2/Pro_PIF4:PIF4-3xHA transgenic lines were described before [36, 48, 68]. cop1-4/Pro_PIF4:PIF4-3xHA, uvr8-6/Pro_PIF4:PIF4-3xHA, and uvr8-6/Pro_PIF5:PIF5-3xHA were generated by genetic crossing.

Growth conditions and light treatments

Arabidopsis seeds were surface sterilized with sodium hypochlorite and grown on half-strength Murashige and Skoog basal salt medium (MS; Duchefa) containing 1% (wt/vol) phytagel (Sigma) and 1% (wt/vol) sucrose in either a 16-h/8-h light/dark cycle or continuous light, as indicated.

For gene expression analysis, seeds were stratified for at least 2 days at 4°C and were germinated at 22°C in a standard growth chamber (Percival Scientific) that contains LED lampbanks (CLF floralLED series, CLF Plant Climatics) under constant white light (R:FR = 4.7) of 60 μmol m^-2 s^-1 overall intensity measured using a LI-COR 250A light meter (LI-COR Biosciences). For low R:FR treatments, PAR remained constant with enrichment in FR provided by supplementary FR LEDs resulting in a R:FR ratio of 0.05. Supplementary UV-B was provided by Philips TL20W/01RS narrowband tubes (0.06 mW cm⁻² s^-1; measured with a VLX-3W Ultraviolet Light Meter equipped with a CX-312 sensor, Vilber Lourmat). The UV-B range was modulated by the use of 3-mm transmission cut-off filters of the WG series (Schott Glaswerke).

For immunoblot analysis and ChIP assays, seeds were stratified for at least 2 days at 4°C and were germinated at 22°C in a standard growth chamber (MLR-350, Sanyo, Gunma, Japan) with 60 μmol m^-2 s^-1 white light and a 16-h/18-h light/dark cycle for 7 and 10 days, respectively. On day 7 or 10 at Zeitgeber Time 3 (ZT3), seedlings were transferred into a Percival growth chamber for a 3-h treatment under low R:FR (0.05) with or without supplemental UV-B (0.06 mW cm⁻² s^-1).

Hypocotyl length measurements

Measurement of hypocotyl length was performed by ImageJ software (https://imagej.nih.gov/ij/). A minimum of 40 seedlings were measured per treatment and genotype, with at least two independent experimental repetitions. For each experiment, ANOVA type I statistical analysis was performed followed by Tukey HSD’s post-hoc test. Letters were assigned to each statistically similar group with p > 0.05.

Protein extraction and immunoblot analysis

Total proteins were extracted from Arabidopsis seedlings in extraction buffer (50mM Tris-HCl pH 7.6, 150mM NaCl, 5mM MgCl₂, 30% (v/v) glycerol, 10μM MG132, 10μM 3,4-dichloroisocoumarin, 1% (v/v) Sigma protease inhibitor cocktail, 0.1% (v/v) Igepal). Total protein was quantified by Bio-Rad Protein Assay (Bio-rad). Proteins were separated by SDS-PAGE and transferred to PVDF membranes according to the manufacturer’s instructions (Bio-rad). Anti-HA (HA.11, Covance), anti-actin (Sigma-Aldrich), and anti-UVR8^(426–440) [13] were used as primary antibodies, with horseradish peroxidase (HRP)-conjugated anti-mouse and anti-rabbit immunoglobulins used as secondary antibodies. Chemiluminescent signals were generated by using an Amersham ECL Select Western Blotting Detection Reagent kit (GE Healthcare, Little Chalfont, UK) and detected with an ImageQuant LAS 4000 mini CCD camera system (GE Healthcare).

Reverse transcription quantitative PCR

Arabidopsis total RNA was isolated with Plant RNeasy kit (Qiagen) and treated with DNaseI according to the manufacturer’s instructions. cDNA synthesis and quantitative PCR (qPCR) using PowerUpSYBR Green Master Mix reagents (Applied Biosystems) and a QuantStudio 5 real-time PCR system (Thermo Fisher Scientific) were performed as previously described [69]. Gene-specific primers used for PIL1, XTR7, ATHB2, IAA29, ST2A, FLP1, FHL, PIL2, HFR1, GH3.3, YUC8, PIF4, PIF5, and PP2A (reference gene) are listed in S4 Table. Expression values were calculated using the ΔΔCt method [70] and normalized to that in the wild type. Each reaction was performed in technical triplicates; data shown are from three independent biological repetitions.

RNA-seq analysis

RNA quality control, library preparation using TruSeqUD Stranded mRNA (Illumina), and sequencing on an Illumina HiSeq 2500 system using 100-bp single-end reads protocol were performed at the iGE3 genomics platform of the University of Geneva. Quality control was performed with FastQC v.0.10.2. Reads were mapped to Arabidopsis TAIR-10 genome using TopHat v2.0.13, resulting in an average alignment rate of approximately 92%. The BAM files were further processed with PicardTools v1.80 and counts obtained using HTSeq v.0.6.1. Counts were filtered for lowly expressed genes (to 20,926 genes) and normalized according to library size. Normalization and differential expression analysis was performed with the R/Bioconductor package edgeR v.3.4.2.

Differentially expressed genes were estimated using a GLM approach (General Linear Model), negative binomial distribution and a quasi-likelihood F-test. Pairwise comparisons (GLM, quasi-likelihood F-test) were performed on the filtered dataset with 2 factors defined (genotype and condition). Genes with a fold change > 2 and p < 0.05 (with FDR 5%) were considered differentially expressed. For further analysis, data sets were filtered for genes differentially expressed in response to UV-B in the wild type but not in uvr8. Venn diagrams were generated using a webtool (http://bioinformatics.psb.ugent.be/webtools/Venn/).

Chromatin immunoprecipitation (ChIP) assays

Chromatin was immunoprecipitated with polyclonal ChIP-grade anti-HA antibodies (Abcam), as previously described [23,25]. ChIP-qPCR data were obtained using PowerUP SYBR Green Master Mix Kit and a QuantStudio 5 Real-Time PCR system (Applied Biosystems), with primers as listed in S4 Table. qPCR data were analyzed according to the percentage of input method [71]. Technical error bars represent standard deviation and were calculated according to the Applied Biosystems user manual.

Supporting information

S1 Fig [a]
expression in response to UV-B.

S2 Fig [a]
PIL1 and HFR1 act redundantly in UVR8-mediated repression of shade-induced and . expression.

S3 Fig [a]
HFR1 does not play a role in UVR8-dependent transcriptional repression of and under UV-B.

S4 Fig [a]
UV-B represses PIF5 binding to promoters of shade marker genes.

S5 Fig [pdf]
Independent repetitions of ChIP data related to and .

S1 Table [xlsx]

S2 Table [xlsx]
Genes upregulated by low R:FR in Col wild type, , and (lists corresponding to ).

S3 Table [xlsx]
Intersection of genes upregulated by low R:FR and repressed by UV-B in wild type and genes upregulated by low R:FR and not repressed by UV-B in mutant (lists corresponding to ).

S4 Table [xlsx]
Oligonucleotide sequences used in this study.

Zdroje

1. Galvao VC, Fankhauser C. Sensing the light environment in plants: photoreceptors and early signaling steps. Curr Opin Neurobiol. 2015; 34: 46–53. doi: 10.1016/j.conb.2015.01.013 25638281

2. Demarsy E, Goldschmidt-Clermont M, Ulm R. Coping with 'dark sides of the sun' through photoreceptor signaling. Trends Plant Sci. 2018; 23: 260–271. doi: 10.1016/j.tplants.2017.11.007 29233601

3. Casal JJ. Shade avoidance. Arabidopsis Book. 2012; 10: e0157. doi: 10.1199/tab.0157 22582029

4. Fiorucci AS, Fankhauser C. Plant strategies for enhancing access to sunlight. Curr Biol. 2017; 27: R931–R40. doi: 10.1016/j.cub.2017.05.085 28898666

5. Ballare CL, Pierik R. The shade-avoidance syndrome: multiple signals and ecological consequences. Plant Cell Environ. 2017; 40: 2530–2543. doi: 10.1111/pce.12914 28102548

6. Casal JJ. Photoreceptor signaling networks in plant responses to shade. Annu Rev Plant Biol. 2013; 64: 403–427. doi: 10.1146/annurev-arplant-050312-120221 23373700

7. Fraser DP, Hayes S, Franklin KA. Photoreceptor crosstalk in shade avoidance. Curr Opin Plant Biol. 2016; 33: 1–7. doi: 10.1016/j.pbi.2016.03.008 27060719

8. Lorrain S, Allen T, Duek PD, Whitelam GC, Fankhauser C. Phytochrome-mediated inhibition of shade avoidance involves degradation of growth-promoting bHLH transcription factors. Plant J. 2008; 53: 312–323. doi: 10.1111/j.1365-313X.2007.03341.x 18047474

9. Shen Y, Khanna R, Carle CM, Quail PH. Phytochrome induces rapid PIF5 phosphorylation and degradation in response to red-light activation. Plant Physiol. 2007; 145: 1043–1051. doi: 10.1104/pp.107.105601 17827270

10. Leivar P, Monte E. PIFs: systems integrators in plant development. Plant Cell. 2014; 26: 56–78. doi: 10.1105/tpc.113.120857 24481072

11. Hornitschek P, Lorrain S, Zoete V, Michielin O, Fankhauser C. Inhibition of the shade avoidance response by formation of non-DNA binding bHLH heterodimers. EMBO J. 2009; 28: 3893–3902. doi: 10.1038/emboj.2009.306 19851283

12. Rizzini L, Favory JJ, Cloix C, Faggionato D, O'Hara A, Kaiserli E, et al. Perception of UV-B by the Arabidopsis UVR8 protein. Science. 2011; 332: 103–106. doi: 10.1126/science.1200660 21454788

13. Favory JJ, Stec A, Gruber H, Rizzini L, Oravecz A, Funk M, et al. Interaction of COP1 and UVR8 regulates UV-B-induced photomorphogenesis and stress acclimation in Arabidopsis. EMBO J. 2009; 28: 591–601. doi: 10.1038/emboj.2009.4 19165148

14. Oravecz A, Baumann A, Mate Z, Brzezinska A, Molinier J, Oakeley EJ, et al. CONSTITUTIVELY PHOTOMORPHOGENIC1 is required for the UV-B response in Arabidopsis. Plant Cell. 2006; 18: 1975–1990. doi: 10.1105/tpc.105.040097 16829591

15. Lau OS, Deng XW. The photomorphogenic repressors COP1 and DET1: 20 years later. Trends Plant Sci. 2012; 17: 584–593. doi: 10.1016/j.tplants.2012.05.004 22705257

16. Hoecker U. The activities of the E3 ubiquitin ligase COP1/SPA, a key repressor in light signaling. Curr Opin Plant Biol. 2017; 37: 63–69. doi: 10.1016/j.pbi.2017.03.015 28433946

17. Podolec R, Ulm R. Photoreceptor-mediated regulation of the COP1/SPA E3 ubiquitin ligase. Curr Opin Plant Biol. 2018; 45: 18–25. doi: 10.1016/j.pbi.2018.04.018 29775763

18. Lau K, Podolec R, Chappuis R, Ulm R, Hothorn M. Plant photoreceptors and their signaling components compete for COP1 binding via VP peptide motifs. EMBO J. 2019: e102140. doi: 10.15252/embj.2019102140 31304983

19. Huang X, Ouyang X, Yang P, Lau OS, Chen L, Wei N, et al. Conversion from CUL4-based COP1-SPA E3 apparatus to UVR8-COP1-SPA complexes underlies a distinct biochemical function of COP1 under UV-B. Proc Natl Acad Sci USA. 2013; 110: 16669–16674. doi: 10.1073/pnas.1316622110 24067658

20. Ulm R, Baumann A, Oravecz A, Mate Z, Adam E, Oakeley EJ, et al. Genome-wide analysis of gene expression reveals function of the bZIP transcription factor HY5 in the UV-B response of Arabidopsis. Proc Natl Acad Sci USA. 2004; 101: 1397–1402. doi: 10.1073/pnas.0308044100 14739338

21. Brown BA, Cloix C, Jiang GH, Kaiserli E, Herzyk P, Kliebenstein DJ, et al. A UV-B-specific signaling component orchestrates plant UV protection. Proc Natl Acad Sci USA. 2005; 102: 18225–18230. doi: 10.1073/pnas.0507187102 16330762

22. Gruber H, Heijde M, Heller W, Albert A, Seidlitz HK, Ulm R. Negative feedback regulation of UV-B-induced photomorphogenesis and stress acclimation in Arabidopsis. Proc Natl Acad Sci USA. 2010; 107: 20132–20137. doi: 10.1073/pnas.0914532107 21041653

23. Stracke R, Favory JJ, Gruber H, Bartelniewoehner L, Bartels S, Binkert M, et al. The Arabidopsis bZIP transcription factor HY5 regulates expression of the PFG1/MYB12 gene in response to light and ultraviolet-B radiation. Plant Cell Environ. 2010; 33: 88–103. doi: 10.1111/j.1365-3040.2009.02061.x 19895401

24. Huang X, Ouyang X, Yang P, Lau OS, Li G, Li J, et al. Arabidopsis FHY3 and HY5 positively mediate induction of COP1 transcription in response to photomorphogenic UV-B light. Plant Cell. 2012; 24: 4590–4606. doi: 10.1105/tpc.112.103994 23150635

25. Binkert M, Kozma-Bognar L, Terecskei K, De Veylder L, Nagy F, Ulm R. UV-B-responsive association of the Arabidopsis bZIP transcription factor ELONGATED HYPOCOTYL5 with target genes, including its own promoter. Plant Cell. 2014; 26: 4200–4213. doi: 10.1105/tpc.114.130716 25351492

26. Brown BA, Jenkins GI. UV-B signaling pathways with different fluence-rate response profiles are distinguished in mature Arabidopsis leaf tissue by requirement for UVR8, HY5, and HYH. Plant Physiol. 2008; 146: 576–588. doi: 10.1104/pp.107.108456 18055587

27. Tavridou E, Pireyre M, Ulm R. Degradation of the transcription factors PIF4 and PIF5 under UV-B promotes UVR8-mediated hypocotyl growth inhibition in Arabidopsis. Plant J. 2020; 101: 507–517. doi: 10.1111/tpj.14556 31571300

28. Hayes S, Velanis CN, Jenkins GI, Franklin KA. UV-B detected by the UVR8 photoreceptor antagonizes auxin signaling and plant shade avoidance. Proc Natl Acad Sci USA. 2014; 111: 11894–11899. doi: 10.1073/pnas.1403052111 25071218

29. Liang T, Mei S, Shi C, Yang Y, Peng Y, Ma L, et al. UVR8 interacts with BES1 and BIM1 to regulate transcription and photomorphogenesis in Arabidopsis. Dev Cell. 2018; 44: 512–523 doi: 10.1016/j.devcel.2017.12.028 29398622

30. Yang Y, Liang T, Zhang L, Shao K, Gu X, Shang R, et al. UVR8 interacts with WRKY36 to regulate HY5 transcription and hypocotyl elongation in Arabidopsis. Nat Plants. 2018; 4: 98–107. doi: 10.1038/s41477-017-0099-0 29379156

31. Kliebenstein DJ, Lim JE, Landry LG, Last RL. Arabidopsis UVR8 regulates ultraviolet-B signal transduction and tolerance and contains sequence similarity to human regulator of chromatin condensation 1. Plant Physiol. 2002; 130: 234–243. doi: 10.1104/pp.005041 12226503

32. Sharma A, Sharma B, Hayes S, Kerner K, Hoecker U, Jenkins GI, et al. UVR8 disrupts stabilisation of PIF5 by COP1 to inhibit plant stem elongation in sunlight. Nat Commun. 2019; 10: 4417. doi: 10.1038/s41467-019-12369-1 31562307

33. Mazza CA, Ballare CL. Photoreceptors UVR8 and phytochrome B cooperate to optimize plant growth and defense in patchy canopies. New Phytol. 2015; 207: 4–9. doi: 10.1111/nph.13332 25659974

34. Vandenbussche F, Tilbrook K, Fierro AC, Marchal K, Poelman D, Van Der Straeten D, et al. Photoreceptor-mediated bending towards UV-B in Arabidopsis. Mol Plant. 2014; 7: 1041–1052. doi: 10.1093/mp/ssu039 24711292

35. Fraser DP, Sharma A, Fletcher T, Budge S, Moncrieff C, Dodd AN, et al. UV-B antagonises shade avoidance and increases levels of the flavonoid quercetin in coriander (Coriandrum sativum). Sci Rep. 2017; 7: 17758. doi: 10.1038/s41598-017-18073-8 29259256

36. Hayes S, Sharma A, Fraser DP, Trevisan M, Cragg-Barber CK, Tavridou E, et al. UV-B perceived by the UVR8 photoreceptor inhibits plant thermomorphogenesis. Curr Biol. 2017; 27: 120–127. doi: 10.1016/j.cub.2016.11.004 27989670

37. Lorrain S, Trevisan M, Pradervand S, Fankhauser C. Phytochrome interacting factors 4 and 5 redundantly limit seedling de-etiolation in continuous far-red light. Plant J. 2009; 60: 449–461. doi: 10.1111/j.1365-313X.2009.03971.x 19619162

38. Toledo-Ortiz G, Johansson H, Lee KP, Bou-Torrent J, Stewart K, Steel G, et al. The HY5-PIF regulatory module coordinates light and temperature control of photosynthetic gene transcription. PLoS Genet. 2014; 10: e1004416. doi: 10.1371/journal.pgen.1004416 24922306

39. Gangappa SN, Kumar SV. DET1 and HY5 Control PIF4-Mediated Thermosensory Elongation Growth through Distinct Mechanisms. Cell Rep. 2017; 18: 344–351. doi: 10.1016/j.celrep.2016.12.046 28076780

40. de Lucas M, Daviere JM, Rodriguez-Falcon M, Pontin M, Iglesias-Pedraz JM, Lorrain S, et al. A molecular framework for light and gibberellin control of cell elongation. Nature. 2008; 451: 480–484. doi: 10.1038/nature06520 18216857

41. Feng S, Martinez C, Gusmaroli G, Wang Y, Zhou J, Wang F, et al. Coordinated regulation of Arabidopsis thaliana development by light and gibberellins. Nature. 2008; 451: 475–479. doi: 10.1038/nature06448 18216856

42. Duek PD, Elmer MV, van Oosten VR, Fankhauser C. The degradation of HFR1, a putative bHLH class transcription factor involved in light signaling, is regulated by phosphorylation and requires COP1. Curr Biol. 2004; 14: 2296–2301. doi: 10.1016/j.cub.2004.12.026 15620659

43. Jang IC, Yang JY, Seo HS, Chua NH. HFR1 is targeted by COP1 E3 ligase for post-translational proteolysis during phytochrome A signaling. Genes Dev. 2005; 19: 593–602. doi: 10.1101/gad.1247205 15741320

44. Yang J, Lin R, Sullivan J, Hoecker U, Liu B, Xu L, et al. Light regulates COP1-mediated degradation of HFR1, a transcription factor essential for light signaling in Arabidopsis. Plant Cell. 2005; 17: 804–821. doi: 10.1105/tpc.104.030205 15705947

45. Yin R, Arongaus AB, Binkert M, Ulm R. Two distinct domains of the UVR8 photoreceptor interact with COP1 to initiate UV-B signaling in Arabidopsis. Plant Cell. 2015; 27: 202–213. doi: 10.1105/tpc.114.133868 25627067

46. Li L, Zhang Q, Pedmale UV, Nito K, Fu W, Lin L, et al. PIL1 participates in a negative feedback loop that regulates its own gene expression in response to shade. Mol Plant. 2014; 7: 1582–1585. doi: 10.1093/mp/ssu068 24895419

47. Luo Q, Lian HL, He SB, Li L, Jia KP, Yang HQ. COP1 and phyB physically interact with PIL1 to regulate its stability and photomorphogenic development in Arabidopsis. Plant Cell. 2014; 26: 2441–2456. doi: 10.1105/tpc.113.121657 24951480

48. Zhang B, Holmlund M, Lorrain S, Norberg M, Bako L, Fankhauser C, et al. BLADE-ON-PETIOLE proteins act in an E3 ubiquitin ligase complex to regulate PHYTOCHROME INTERACTING FACTOR 4 abundance. Elife. 2017; 6. doi: 10.7554/eLife.26759.001 28826468

49. Hornitschek P, Kohnen MV, Lorrain S, Rougemont J, Ljung K, Lopez-Vidriero I, et al. Phytochrome interacting factors 4 and 5 control seedling growth in changing light conditions by directly controlling auxin signaling. Plant J. 2012; 71: 699–711. doi: 10.1111/j.1365-313X.2012.05033.x 22536829

50. Zhang Y, Mayba O, Pfeiffer A, Shi H, Tepperman JM, Speed TP, et al. A quartet of PIF bHLH factors provides a transcriptionally centered signaling hub that regulates seedling morphogenesis through differential expression-patterning of shared target genes in Arabidopsis. PLoS Genet. 2013; 9: e1003244. doi: 10.1371/journal.pgen.1003244 23382695

51. Xu X, Kathare PK, Pham VN, Bu Q, Nguyen A, Huq E. Reciprocal proteasome-mediated degradation of PIFs and HFR1 underlies photomorphogenic development in Arabidopsis. Development. 2017; 144: 1831–1840. doi: 10.1242/dev.146936 28420710

52. Casal JJ, Balasubramanian S. Thermomorphogenesis. Annu Rev Plant Biol. 2019; 70: 321–346. doi: 10.1146/annurev-arplant-050718-095919 30786235

53. Keller MM, Jaillais Y, Pedmale UV, Moreno JE, Chory J, Ballare CL. Cryptochrome 1 and phytochrome B control shade-avoidance responses in Arabidopsis via partially independent hormonal cascades. Plant J. 2011; 67: 195–207. doi: 10.1111/j.1365-313X.2011.04598.x 21457375

54. Pedmale UV, Huang SS, Zander M, Cole BJ, Hetzel J, Ljung K, et al. Cryptochromes interact directly with PIFs to control plant growth in limiting blue light. Cell. 2016;164: 233–245. doi: 10.1016/j.cell.2015.12.018 26724867

55. Ma D, Li X, Guo Y, Chu J, Fang S, Yan C, et al. Cryptochrome 1 interacts with PIF4 to regulate high temperature-mediated hypocotyl elongation in response to blue light. Proc Natl Acad Sci USA. 2016; 113: 224–229. doi: 10.1073/pnas.1511437113 26699514

56. Huq E, Quail PH. PIF4, a phytochrome-interacting bHLH factor, functions as a negative regulator of phytochrome B signaling in Arabidopsis. EMBO J. 2002; 21: 2441–2450. doi: 10.1093/emboj/21.10.2441 12006496

57. Pham VN, Kathare PK, Huq E. Dynamic regulation of PIF5 by COP1-SPA complex to optimize photomorphogenesis in Arabidopsis. Plant J. 2018; 96: 260–273. doi: 10.1111/tpj.14074 30144338

58. Cloix C, Kaiserli E, Heilmann M, Baxter KJ, Brown BA, O'Hara A, et al. C-terminal region of the UV-B photoreceptor UVR8 initiates signaling through interaction with the COP1 protein. Proc Natl Acad Sci USA. 2012; 109: 16366–16370. doi: 10.1073/pnas.1210898109 22988111

59. Salter MG, Franklin KA, Whitelam GC. Gating of the rapid shade-avoidance response by the circadian clock in plants. Nature. 2003; 426: 680–683. doi: 10.1038/nature02174 14668869

60. Galstyan A, Cifuentes-Esquivel N, Bou-Torrent J, Martinez-Garcia JF. The shade avoidance syndrome in Arabidopsis: a fundamental role for atypical basic helix-loop-helix proteins as transcriptional cofactors. Plant J. 2011; 66: 258–267. doi: 10.1111/j.1365-313X.2011.04485.x 21205034

61. Hao Y, Oh E, Choi G, Liang Z, Wang ZY. Interactions between HLH and bHLH factors modulate light-regulated plant development. Mol Plant. 2012; 5: 688–697. doi: 10.1093/mp/sss011 22331621

62. Roig-Villanova I, Bou-Torrent J, Galstyan A, Carretero-Paulet L, Portoles S, Rodriguez-Concepcion M, et al. Interaction of shade avoidance and auxin responses: a role for two novel atypical bHLH proteins. EMBO J. 2007; 26: 4756–4767. doi: 10.1038/sj.emboj.7601890 17948056

63. Moriconi V, Binkert M, Costigliolo C, Sellaro R, Ulm R, Casal JJ. Perception of sunflecks by the UV-B photoreceptor UV RESISTANCE LOCUS8. Plant Physiol. 2018; 177: 75–81. doi: 10.1104/pp.18.00048 29530938

64. Sellaro R, Yanovsky MJ, Casal JJ. Repression of shade-avoidance reactions by sunfleck induction of HY5 expression in Arabidopsis. Plant J. 2011; 68: 919–928. doi: 10.1111/j.1365-313X.2011.04745.x 21848684

65. McNellis TW, von Arnim AG, Araki T, Komeda Y, Misera S, Deng XW. Genetic and molecular analysis of an allelic series of cop1 mutants suggests functional roles for the multiple protein domains. Plant Cell. 1994; 6: 487–500. doi: 10.1105/tpc.6.4.487 8205001

66. Fankhauser C, Chory J. RSF1, an Arabidopsis locus implicated in phytochrome A signaling. Plant Physiol. 2000; 124: 39–45. doi: 10.1104/pp.124.1.39 10982420

67. Sessa G, Carabelli M, Sassi M, Ciolfi A, Possenti M, Mittempergher F, et al. A dynamic balance between gene activation and repression regulates the shade avoidance response in Arabidopsis. Genes Dev. 2005; 19: 2811–2815. doi: 10.1101/gad.364005 16322556

68. de Wit M, Keuskamp DH, Bongers FJ, Hornitschek P, Gommers CMM, Reinen E, et al. Integration of phytochrome and cryptochrome signals determines plant growth during competition for light. Curr Biol. 2016; 26: 3320–3326. doi: 10.1016/j.cub.2016.10.031 27889265

69. Arongaus AB, Chen S, Pireyre M, Glockner N, Galvao VC, Albert A, et al. Arabidopsis RUP2 represses UVR8-mediated flowering in noninductive photoperiods. Genes Dev. 2018; 32: 1332–1343. doi: 10.1101/gad.318592.118 30254107

70. Livak KJ, Schmittgen TD. Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method. Methods. 2001; 25: 402–408. doi: 10.1006/meth.2001.1262 11846609

71. Haring M, Offermann S, Danker T, Horst I, Peterhansel C, Stam M. Chromatin immunoprecipitation: optimization, quantitative analysis and data normalization. Plant Methods. 2007; 3: 11. doi: 10.1186/1746-4811-3-11 17892552

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