The Role of Specialized Photoreceptors in the Protection of Energy-Rich Tissues

: The perception and absorption of light by plants is a driving force in plant evolutionary history, as plants have evolved multiple photoreceptors to perceive different light attributes including duration, intensity, direction and quality. Plant photoreceptors interpret these signals from the light environment and mold plant architecture to maximize foliar light capture. As active sites of the production and accumulation of energy-rich products, leaves are targets of pests and pathogens, which have driven the selection of physiological processes to protect these energy-rich tissues. In the last ten years, several research groups have accumulated evidence showing that plant photoreceptors control speciﬁc molecular programs that deﬁne plant growth and immune processes. Here, we discuss recent knowledge addressing these roles in Arabidopsis and show that (1) plant immune responses affect energy acquisition and partitioning; (2) plant photoreceptors interpret the light environment and control growth and immune processes; and ﬁnally; (3) defense and light signaling pathways can be genetically manipulated to obtain plants able to grow and defend at the same time. This basic knowledge from Arabidopsis plants should lead new lines of applied research in crops.


Introduction
As primary producers of the food chain, plants face constant attack from pests and pathogens that feed on their energy-rich tissues, while competing for sunlight with neighboring plants.Consequently, plants evolved strategies to protect their energy-rich tissues from attackers by initiating defense responses and to outperform competitors by reconfiguring plant architecture for rapid, extensile growth.However, both altered architecture and investment in defenses restricts the generation of new leaf tissues.Thus, plant strategies for competitive production and protection of biomass have future costs associated with reduced capacity for energy capture.It is therefore crucial for plants to perceive and integrate environmental cues and properly execute growth and defense programs when conditions warrant competitive growth or immunity from pests and pathogens.
Plant growth and health relies on the ability to perceive, absorb and transform solar radiation into photosynthates.Most of the absorbed light is funneled through chlorophyll and accessory pigments, but a reduced proportion of the light spectra is reflected and transmitted by green tissues.Plants perceive different attributes of the light environment using specialized photoreceptors, including phytochromes, cryptochromes, phototropins, and the ultraviolet-B photoreceptor.These constitutive SAS phenotype of the single phyB mutant.phyB inactivation leads to enhanced stability of PIF3 and PIF4 [12], triggering cell elongation responses through the induction of genes involved in AUX [13,14] and GA synthesis [15], and of cell wall degrading enzymes [16,17].The Arabidopsis genome encodes five phytochrome genes: PHYA, B, C, D and E. Recent studies are shedding light on the relative contribution of each phytochrome to the different developmental and physiological responses in Arabidopsis [18,19].

The Jasmonate and Salicylate Pathways Drive Inducible Defenses
Plants have an important diversity of defense responses, many of which are activated only after stress.These inducible defenses minimize the costs of synthesizing defensive metabolites and limit detrimental effects on plant health.In general, plant inducible defenses against chewing insects and necrotrophic pathogens are controlled by the lipid-derived hormone jasmonic acid (JA), whereas the shikimate-derived hormone salicylic acid (SA) controls inducible defenses against sucking arthropods and biotrophic pathogens [20].In both cases, hormone synthesis is initiated by perception of specific elicitors associated with attack.These "danger" signals include plant-derived signals produced by cellular damage (i.e., damaged self), so-called damage-associated molecular patterns (DAMPs), or specific elicitors produced by foreign organisms, known as herbivore-associated molecular patterns (HAMPs) from feeding arthropod herbivores, and as microbe-associated molecular patterns (MAMPs) from invading microbes [21].In an example of co-evolution between host and attacker, herbivores and microbes secrete effectors that target host signaling to neutralize defenses, while plants deploy receptors that recognize specific effectors to elicit immunity.
Studies over the past decade have dramatically improved our understanding of the molecular controls of plant defense responses against pests and pathogens.Immune responses are maintained in a repressed "off" state in healthy plants by key transcriptional regulators, the JAZ (JASMONATE ZIM-DOMAIN) and NPR (NONEXPRESSOR OF PR GENES) proteins.These regulators perceive elevated JA or SA levels in plants challenged by pests or pathogens and activate appropriate responses.For JA signaling, JA promotes direct binding of JAZ proteins with the F-Box protein COI1 (CORONATINE INSENSITIVE 1), and this interaction targets the JAZs for degradation by the proteasome [22][23][24][25][26].The Arabidopsis thaliana genome encodes 13 JAZ proteins with overlapping functions.Functional specificity of individual JAZ proteins is conferred by the diversity of their conserved domains, which is expanded by alternative splicing [27][28][29].Differences in the conserved domains of JAZs influence their interaction with other proteins, including altered affinity for COI1 that determines JAZ degradation rate.Together, these differences fine-tune JA signaling and preference for target transcription factors that defines immune and developmental responses [28,30].For SA signaling, NPR proteins may perceive SA as a multireceptor complex, where SA sensitivity would depend on the NPR protein in the receptor [31].SA binding converts NPR1 into a transcriptional activator that initiates immune responses [32], while NPR3 and NPR4 proteins integrate SA levels by binding SA with different affinities to regulate turnover of NPR1 by the proteasome [33].A high turnover of NPR1 is critical to plant immune responses [34] and also relies on other protein modifications including phosphorylation and SUMOylation [35].
Numerous laboratory and field experiments using different plant crops have shown a conserved antagonism between JA-and SA-defense responses, whereby the activation of JA-related responses is associated with suppression of SA-related responses and vice-versa [36].For example, insect-damaged or JA-induced plants were more susceptible to infection by pathogens that trigger SA-dependent defense responses [37,38].Similarly, Arabidopsis plants infected with the biotrophic pathogen Pseudomonas syringae, which elicits SA responses, were more susceptible to the necrotrophic pathogen Alternaria brassicicola by suppression of JA responses [39].Interestingly, attackers have evolved to manipulate JA-SA antagonism; several biotrophic pathogens deploy effectors that hijack JA signaling to suppress SA-mediated immunity, while insects have strategies that hijack SA signaling to interfere with JA defenses [40].Several points of crosstalk have been reported that contribute to JA-SA antagonism [41], including recent reports showing that NPR3 and NPR4 interact directly with several JAZ proteins to trigger JAZ degradation in a COI1-independent manner [42] and that JA activates a signaling cascade that inhibits SA accumulation [43].It is becoming evident that SA-JA antagonism allows plants to tailor immune responses against specific attackers [36], which may mitigate the costs associated with immune responses.

Plant Immunity Constrains Growth and Development
Activation of defense processes can have negative consequences on plant growth and development [44], including reduced growth of shoots and roots, delayed development, and ultimately reduced biomass.The clearest examples of these trade-offs are constitutive defense mutants in which growth is severely hindered [45][46][47][48][49][50].Photosynthesis is often reported to be decreased during defense responses, which would reduce growth and biomass if resources are limiting [51,52].There is good evidence that wounding actively suppresses photosynthesis, as the decrease in photosynthesis is greater than the amount of tissue damaged and requires intact JA signaling [52,53].Recently, the key defense regulator MYC2 was shown to directly trigger expression of genes involved in chlorophyll degradation, suggesting a mechanism of JA-mediated suppression of photosynthesis [54,55].However, other evidence questions whether photosynthesis is genuinely suppressed during defense responses.Chlorophyll degradation itself may be a defensive strategy, as degradation products have anti-insect activity [56].Other studies have shown that photosynthetic rates are not perturbed when defense responses are activated in the absence of physical damage, suggesting that some reports of decreased photosynthesis could be a consequence of physical damage (e.g., localized water loss from disrupted cells) [48,49,57].Importantly, active defense responses trigger reduced growth without a corresponding reduction in photosynthesis, demonstrating that decreased photosynthesis is not the main cause of reduced growth during defense responses [48,49].
Decreased biomass is also common during defense responses [58], and may be ascribed to tissue loss (i.e., damage or removal) and suppression of plant growth.However, the partitioning of resources to defense may play an important role, since the relationship between leaf area and leaf mass is determined by the partitioning of carbon among different physiological processes [59].Interestingly, leaves treated with JA showed a delayed reduction in biomass relative to leaf area and these leaves had a higher ratio of leaf dry mass to area [60].These data are consistent with a hypothesis that activation of defense responses prioritizes investment of resources in leaf defense and structural integrity, representing a strategy to protect energy-rich tissues.However, reduced investment in additional photosynthetic tissues is a lost opportunity, the consequence of which is compounding future losses in whole-plant photosynthesis and growth [60].
Several studies are now revealing that the processes to invest in growth and defense are determined by a complex signaling network, with cross-talk between hormone and light signaling pathways.Several pathogens perturb these pathways by manipulating growth-promoting levels of the hormone auxin (AUX) as a strategy to promote disease [61].Correspondingly, plant immune responses stabilize the AUX/IAA repressor proteins to suppress auxin signaling [62].Growth-defense trade-offs are also determined by competitive binding of JAZ proteins with DELLA proteins, which are repressors of growth responses promoted by the gibberellin (GA) hormone [63,64].Growth cues promote GA-dependent degradation of DELLAs to allow transcription factors such as PIFs to activate growth traits, while stress cues trigger JA-mediated degradation of JAZs to allow transcription factors such as MYCs to activate defense responses.Interestingly, recent data suggests that the MYC transcription factors, which are associated primarily with defense processes, may also be repressors of growth themselves.MYC2 negatively regulates root growth via the PLT1 and PLT2 transcription factors [65], while gain-of-function mutations of MYC2 (myc2-322B) and MYC3 (atr2D), which have reduced interaction with JAZ repressors, exhibit reduced shoot growth [66][67][68].

Specialized Photoreceptors Inform Growth-Defense Trade-offs
Increasing evidence supports a positive correlation between higher crop densities and the occurrence of pests [69].These observations in agricultural and ecological systems led to the proposed "dilemma of plants"; that is whether to invest limited resources for competitive growth with neighboring plants or for robust defense against insects and pathogens [70].The high susceptibility of densely-cropped plants is partly related to changes in the light environment.Crowded stands combine lower PAR, less UV-B radiation, less B, and a lower R:FR ratio.In recent years, the use of Arabidopsis photoreceptor mutants and light-manipulation experiments has generated important evidence showing that these light components contribute to the immune-suppressed state of plants growing in crowded stands.
UV-B and inducible defenses: UV-B attenuation experiments in the field have clearly shown that natural herbivory is more severe on plants growing with attenuated levels of UV-B compared to those exposed to full sunlight [7,[71][72][73].Most of the plants increase the accumulation of soluble phenolic compounds in green tissues in response to UV-B, where some of these compounds were shown to have a direct role on insect herbivore performance [51,74,75].In addition, UV-B altered Plutella xylostella oviposition behavior in a JA-dependent manner, since adult moths laid more eggs on plants growing under attenuated UV-B [72].Conversely, plants supplemented with UV-B experienced less herbivory and disease symptoms than control plants [51,76].Resistance to Botrytis cinerea infection was significantly increased in plants grown with supplemental UV-B, an effect that required the UVR8 photoreceptor but not JA signaling [76].This UV-B effect on B. cinerea resistance was mediated by the accumulation of sinapate in Arabidopsis [76].
Blue light and inducible defenses: B depletion does not appear to affect immunity.Arabidopsis plants expressing SAS, either due to B depletion or mutation of the CRY1 photoreceptor, were not more susceptible to B. cinerea infection [77].Moreover, cry1 mutants showed similar resistance to infection by P. syringae [78,79].However, the cry1 mutant has also been reported more susceptible to P. syringae [80].B may also indirectly influence defense responses since B controls stomatal openings, which are the main points of entry for pathogens [81,82].B signals also synchronize the circadian clock, which regulates plant growth and defense processes.Immune responses against both herbivores and pathogens are 'gated' by the plant circadian clock such that defense is strongest in the morning when biotic attack is more likely [83][84][85].Interestingly, NPR1 also contributes to synchronizing the circadian clock, allowing SA to reinforce the circadian clock and gate immune responses [86].Altogether, B signals contribute to circadian gating of immunity, which allows plants to reinforce morning defenses in 'anticipation' of challenge from herbivores and pathogens, while also minimizing the negative side effects on growth responses that take place at night.R:FR ratio and inducible defenses: Plants expressing SAS, from either high-density planting or supplemental FR, displayed weak defense phenotypes against insect herbivores, necrotrophic fungus, and pathogenic bacteria [77,87,88].The levels of defense metabolites, including phenolics, aliphatic glucosinolates, and camalexin, were lower in SAS-expressing plants upon B. cinerea infection [77,87,89].In addition, growth in FR-rich environments suppressed both JA-and SA-dependent expression of defense genes [88].Together, these results demonstrated that phytochrome inactivation by FR reduces JA and SA sensitivity.phyB is the principle phytochrome receptor responsible for FR-mediated perturbation of immune responses, as phyB mutants are less sensitive to JA and SA, and are more susceptible to insect herbivory and to infection by B. cinerea and P. syringae [77,87,88,90].The molecular mechanisms behind these growth-defense trade-offs include multiple layers of regulation by FR: (1) JA-mediated degradation of JAZ10 is significantly reduced in seedlings exposed to FR radiation and in the phyB mutant background [91]; (2) FR destabilizes MYC2, MYC3 and MYC4 proteins, key transcription factors of JA responses, in a phyB-dependent manner [92]; (3) FR triggers turnover of DELLA proteins [91], which releases repression of PIFs to activate growth processes, as well as the release of JAZ proteins from DELLA-JAZ interactions to enhance repression of JA responses (see Section 3) [62,63]; and (4) FR interferes with NPR1 phosphorylation, contributing to reduced NPR1-mediated immune responses [88].

Growth-Defense Decisions Are Controlled by the Phytochrome B Signaling Pathway
Several studies are now revealing that the classic and simple view that growth and defense processes are limited by resource constraints is too simplistic; instead, growth and defense are determined by signaling programs.For example, studies have shown that JA-mediated growth repression involves reduced cell division and expansion by perturbation of the cell cycle [58,93,94].Moreover, Arabidopsis mutants that no longer produced glucosinolates (the main defense compound in brassica plants) still exhibited growth suppression, demonstrating that growth and defense are not strictly coupled genetically [50,95].Similarly, the "decision" to prioritize growth over defense during SAS appears to be a specific physiological response mediated by phyB, rather than the limitation of plant energy constraints [87,91].As such, several studies are revealing that SAS-mediated growth promotion and defense suppression can be processes that are uncoupled in various mutants.For example, the cpr1 and cev1 mutants, which have constitutively active SA-and JA-dependent defense responses, respectively, both express partial SAS in response to FR, suggesting that these mutants can direct resources to growth and defense [88].In the sav3-2 mutant, FR exposure does not trigger expression of SAS but does suppress immune responses, demonstrating that the morphological investment of energy during SAS expression cannot per se explain the increased susceptibility to insects or B. cinerea [77,87].Defense suppression is also uncoupled from SAS in the jaz10 phyB double mutant, which maintains constitutive SAS but with wild type JA sensitivity [91].These points of cross-talk among growth and defense signaling pathways are establishing how complex networks of regulators govern these processes to properly respond to external conditions [49,95,96].An emerging question is whether we can use the knowledge of these networks to manipulate growth-defense trade-offs (see Section 7 below).

Manipulating Repressors of Defense and Light Signaling for Improved Protection and Growth of Energy-Rich Tissues
The molecular basis of how the JA signaling pathway integrates growth and defense remained obscured by the genetic redundancy among the JAZ transcriptional repressors.As a consequence, the majority of single jaz mutants showed no clear phenotype [25].In an effort to overcome this situation, Campos et al. ( 2016) developed a higher-order mutant that lacks five of the thirteen JAZ repressors present in the Arabidopsis genome.Removal of multiple JAZ genes in this jaz quintuple (jazQ) mutant led to constitutive activation of JA responses, causing hypersensitivity to exogenous JA treatment, upregulation of defense-related genes, increased production of secondary metabolites and higher resistance to insect herbivory attack [49].On the other hand, rosette expansion was restricted in this higher-order mutant, as jazQ exhibited stunted rosettes and overall delayed development when compared to wild type plants (Figure 1).In addition, jazQ was ~50% lighter than wild type in terms of rosette dry weight, indicating strong down-regulation of plant biomass accumulation.Taken together, these results support the premise that JA modulates a transcriptional route whose activation (through removal of multiple JAZ transcriptional repressors) culminates in strong promotion of defense along with a reduction in growth-related processes (see Section 3).
restricted in this higher-order mutant, as jazQ exhibited stunted rosettes and overall delayed development when compared to wild type plants (Figure 1).In addition, jazQ was ~50% lighter than wild type in terms of rosette dry weight, indicating strong down-regulation of plant biomass accumulation.Taken together, these results support the premise that JA modulates a transcriptional route whose activation (through removal of multiple JAZ transcriptional repressors) culminates in strong promotion of defense along with a reduction in growth-related processes (see Section 3).The evident shift observed in jazQ growth-defense parameters can be explained in light of its genetic lesions.The five JAZ impaired in jazQ (JAZ1, JAZ3, JAZ4, JAZ9 and JAZ10) were shown to physically interact with DELLA proteins [64].The concept that plant hormones integrate a regulatory network that determines growth-defense outputs was further confirmed by Campos et al. (2016), who genetically rewired crosstalk among defense and growth signaling pathways to obtain an Arabidopsis genotype where growth and defense are transcriptionally and physiologically uncoupled.The authors showed that the combination of the "more defenses, less growth" jazQ with the "more growth, less defense" phyB genotypes produced a higher-order mutant (named jazQ phyB) where growth and defense processes were simultaneously activated (Figure 1).These results are consistent with, and greatly expand upon, previous work showing that suppression of defenses is uncoupled from shade avoidance traits in the jaz10 phyB double mutant [91,97].The jazQ phyB plants showed increased expression of defense-related genes, higher production of secondary metabolites and enhanced resistance against insect herbivory, as well as growth promotion and faster development, even when compared with wild type Arabidopsis plants [49].Full transcriptome sequencing indicated that the jazQ phyB phenotype is the result of an additive combination of the immune program activated in jazQ and the growth program activated in phyB.Those results indicate that depletion of the JAZ and DELLA repressors caused by jazQ and phyB mutations respectively leads to concomitant de-repression of growth and defense transcriptional cascades in the jazQ phyB mutant [49,91].Specific traits found in jazQ phyB were not observed in the jazQ or phyB mutants.For instance, the biomass of both jazQ and phyB was about 50% of that observed for wild type plants, yet the combination of these mutations restored plant biomass to similar levels as wild type plants.Projected leaf area and rosette diameter were also larger in jazQ phyB compared to the parental mutants, as well as wild type plants.At the transcriptional level, more than a thousand genes were differentially expressed in jazQ phyB but not in its parental mutants.Taken together, these results indicate, at one side, a strong modular effect of defense and growth transcriptional programs mainly dependent on MYC and DELLA transcriptional regulators and, at the other side, demonstrate that growth and photomorphogenic signaling pathways show a synergistic control of transcriptional changes to achieve a balanced physiological response to the dilemma of plants.

Conclusions
Recently, a wealth of studies have begun to unveil the molecular basis of the trade-offs between growth and defense, indicating the presence of a complex signaling hub where hormone and light signaling pathways converge to optimize fitness.In light of this recent evidence, we propose a model showing that growth and defense trade-offs are not just the result of metabolic constraints (such as resource limitation), but rather a consequence of a transcriptional network that evolved to maximize plant fitness (Figure 2) [49,95].As such, growth and defense environmental cues are initially perceived by receptors, which in turn, activate transcriptional cascades responsible for the activation of specialized responses.A signaling node integrates these transcriptional programs to precisely control the elicitation of growth and defense traits in order to optimize plant performance.The proposed interaction of regulatory modules is prone to evolve in natural settings, where plants are constantly facing a blend of environmental signals that must be integrated and properly translated into growth and defense traits to maximize fitness.A relevant application of this premise is the use of genetic rewiring to achieve concomitant activation of growth and defense [49,91].This strategy could lead, in a relative short time, to the development of new crop cultivars where high biomass production is combined with lower demand for pesticides.

Figure 1 .
Figure 1.Genetic uncoupling of growth and defense in Arabidopsis.The jazQ phyB mutant combines the large rosette of phyB with elevated defenses of jazQ.Photograph of 3 weeks old wild type, jazQ phyB, phyB and jazQ rosettes.Plants were grown in soil and maintained at 20 °C (±1 °C) under 16 h at a light intensity of 120 μmol m −2 •s −1 and 8 h dark.Bar = 1 cm.

Figure 1 .
Figure 1.Genetic uncoupling of growth and defense in Arabidopsis.The jazQ phyB mutant combines the large rosette of phyB with elevated defenses of jazQ.Photograph of 3 weeks old wild type, jazQ phyB, phyB and jazQ rosettes.Plants were grown in soil and maintained at 20 • C (±1 • C) under 16 h at a light intensity of 120 µmol m −2 •s −1 and 8 h dark.Bar = 1 cm.

Figure 2 .
Figure 2. Environmental cues are perceived and integrated through light and defense signaling to appropriately drive plant growth and defense processes.Proposed model of the integration of growth and defense signals, whereby a signaling node integrates multiple signals perceived from the environment to define the plant phenotype (output), which will ultimately determine plant fitness.The nature of the signal elicits different receptors (signal perception) to trigger signaling cascades that are integrated by molecular players acting as nodes of integration.The final plant phenotype is determined by the degree of activation and repression of specific molecular pathways.

Figure 2 .
Figure 2. Environmental cues are perceived and integrated through light and defense signaling to appropriately drive plant growth and defense processes.Proposed model of the integration of growth and defense signals, whereby a signaling node integrates multiple signals perceived from the environment to define the plant phenotype (output), which will ultimately determine plant fitness.The nature of the signal elicits different receptors (signal perception) to trigger signaling cascades that are integrated by molecular players acting as nodes of integration.The final plant phenotype is determined by the degree of activation and repression of specific molecular pathways.