Stimulation of Tomato Drought Tolerance by PHYTOCHROME A and B1B2 Mutations

Drought stress is a severe environmental issue that threatens agriculture at a large scale. PHYTOCHROMES (PHYs) are important photoreceptors in plants that control plant growth and development and are involved in plant stress response. The aim of this study was to identify the role of PHYs in the tomato cv. ‘Moneymaker’ under drought conditions. The tomato genome contains five PHYs, among which mutant lines in tomato PHYA and PHYB (B1 and B2) were used. Compared to the WT, phyA and phyB1B2 mutants exhibited drought tolerance and showed inhibition of electrolyte leakage and malondialdehyde accumulation, indicating decreased membrane damage in the leaves. Both phy mutants also inhibited oxidative damage by enhancing the expression of reactive oxygen species (ROS) scavenger genes, inhibiting hydrogen peroxide (H2O2) accumulation, and enhancing the percentage of antioxidant activities via DPPH test. Moreover, expression levels of several aquaporins were significantly higher in phyA and phyB1B2, and the relative water content (RWC) in leaves was higher than the RWC in the WT under drought stress, suggesting the enhancement of hydration status in the phy mutants. Therefore, inhibition of oxidative damage in phyA and phyB1B2 mutants may mitigate the harmful effects of drought by preventing membrane damage and conserving the plant hydrostatus.


Introduction
Drought stress is a major threat to crop growth and development [1]. It deleteriously affects plant growth and disrupts ion and water homeostasis in plant cells, eventually leading to death [2]. Plants respond to drought stress by altering their external and internal structures [3]. The development of genetic approaches and the induction of stress resistance mechanisms are major achievements in plant research that have helped minimize the negative effects of abiotic stress factors such as drought [4].
An important vegetable crop that is sensitive to drought stress is tomato (Solanum lycopersicum L.) [5], which belongs to the Solanaceae family. Tomato is a good source of vitamins, carotenoids, and phenolic compounds, which promote human health. In addition to its economic and nutritional importance, the tomato has become a model plant for research [6].
In plants including tomatoes, there are four known light sensors or photoreceptors, i.e., phytochromes (PHYs), cryptochromes, phototropins, and UVR-8 [7]. PHYs are the most characterized photoreceptor absorbing red and far-red light [8]. The number and type of PHYs vary among plant species, with tomato having five PHYs in its genome: PHYA, PHYB1, PHYB2, PHYE, and PHYF [9]. They control the growth and development of plants in almost all growth stages (from seed germination to flowering) and regulate biotic and abiotic stresses [10] by inducing several biochemical and molecular responses [8].
the water potential of the cell [3]. In contrast, the molecular chaperone and hydrophilic solute LEA contributes to plant drought response and resistance, owing to its role in water capture, protein and membrane protection, and cellular dehydration intervention [3,30]. Furthermore, ROS scavengers protect plants against the oxidative damage caused by ROS, such as the destruction of plant biofilm systems and membrane structures, as well as degradation of plant macromolecules, including proteins and enzymes [3].
PHYs act as photoreceptors and contribute to plant growth and development, in addition to their involvement in plant responses to biotic and abiotic stresses. Knowledge regarding the functional response of PHYs to stress conditions such as drought is lacking in many plant species. It was reported that in tomato, PHYs A, B1, and B2 modulate the drought response [15] and that the response of phyA to drought stress was different than that of the wild type (WT); however the phenotypic, physiological, and molecular responses of tomato phyA mutant still need more clarification under drought conditions. Additionally, the response of tomato phyB1 and phyB2 was reported to be quite similar, especially with ABA in relation to water loss [15]; however, the functional role of tomato PHYB (PHYB1 and PHYB2 together) has not been studied under drought stress. Therefore, the purpose of this study was to elucidate the phenotypical, physiological, and molecular responses of tomato phyA and phyB1B2 mutants under drought stress.

Tomato phyA and phyB1B2 Exhibited a Tolerant Phenotype toward Drought Stress
Drought stress severely affects plant growth and development during the initial growth phase [31], and leaf wilting is an obvious symptom of water deficit during the vegetative phase [3]. To investigate the phenotypic response of phyA and phyB1B2 to drought stress, plants in the vegetative and flowering stages were exposed to water withholding. The one-month-old WT and phy mutants were exposed to drought stress by water withholding for 8 d (days). The WT and phy mutant plants were fresh under non-stress (control) conditions (Figure 1a). On the other hand, under water deprivation, the WT plants exhibited a severely wilted phenotype after 8 d. In contrast, phy mutants did not exhibit any wilting and maintained healthy growth under the same conditions ( Figure 1b). Furthermore, the root phenotype of the WT was more prolific than that of the phyA and phyB1B2 mutants under control and drought conditions (Figure 1c,d).
Further phenotypic confirmation was observed in the flowering stage. The WT, phyA, and phyB1B2 plants were exposed to water withholding in the flowering stage under sunlight conditions in the greenhouse. When the plants were exposed to stress conditions for 12 d, the WT was severely affected by drought conditions and showed a dehydrated phenotype. On the contrary, the phyA plant exhibited the best growth, with healthy green leaves. Additionally, the phyB1B2 plant showed a better phenotype than the WT but not like the phyA mutant ( Figure 1e). These results confirm that phyA and phyB1B2 mutants might have a tolerant response to drought stress compared to the WT.
Drought stress affects the elongation and expansion of plants [31]. During the vegetative phase, drought stress can cause a reduction in plant height and modifications in the number and size of leaves [3]. To investigate the effect of drought stress on vegetative growth of phyA and phyB1B2 mutants, root surface area, root length, stem height, stem thickness, plant fresh weight (FW), leaf FW, and leaf number/plant were measured in WT and phy mutants under control and water-withholding conditions. In terms of root surface area, both phy mutants exhibited significantly lower values compared to the WT under control and drought conditions. The reduction in the root surface area in phy mutants under drought stress was not significant compared to the control conditions, whereas the WT exhibited a significant reduction under drought stress compared to control conditions ( Figure 1f). The root length decreased significantly in the WT and phyA mutant after water deprivation compared to the root length in those under non-stress conditions. However, the phyB1B2 mutant did not show any significant difference between the normal and drought conditions (Figure 1g). In addition, there was a significant decline in stem height, stem thickness, plant FW, leaf FW, and leaf number/plant in the WT and phyA mutant under drought stress compared to those under control conditions. Similar results were observed in phyB1B2 with respect to stem height and leaf number/plant, whereas the other vegetative characteristics did not exhibit a marked variance between the stress and non-stress conditions (Figure 1h-l). These results suggest that the vegetative growth of the WT and phyA mutant was inhibited by drought stress, whereas in phyB1B2, only the stem height and leaf number were affected.

Inhibiting Membrane Damage and Oxidative Damage by phyA and phyB1B2 under Drought Stress
EL is used as an indicator for cell membrane stability under stressful conditions [23]. Because membrane stability is negatively affected by drought stress [32], the EL% was measured in one-month-old WT, phyA, and phyB1B2 plants after 8 d of water withholding. The phyA and phyB1B2 mutants had a significantly lower EL% than that of the WT under water deprivation. The EL% of the WT plants reached approximately 39%, whereas the EL% of phyA and phyB1B2 plants was approximately 2.6% and 5%, respectively ( Figure 1m). This result suggests that both phy mutants have enhanced membrane stability under drought conditions.
Hydrogen peroxide (H 2 O 2 ) is an ROS that works as a central player in the signal transduction pathways of various biotic and abiotic stresses [33]. The concentration of H 2 O 2 was detected in the WT, phyA, and phyB1B2 plants under non-stress and drought stress (8 d of water withholding) conditions. The level of H 2 O 2 was not markedly different between these genotypes under control conditions. However, the H 2 O 2 level significantly increased in the WT after drought application compared to both phy mutants. Moreover, there was no significant variance between the phyA and phyB1B2 mutants under the stress conditions ( Figure 2a). These results indicate that oxidative damage was not boosted in either phy mutant under drought conditions. Additionally, MDA is often used to assess the damage level of cells caused by stress, as it is the byproduct of lipid peroxidation [34]. MDA levels were analyzed in one-monthold WT, phyA, and phyB1B2 plants after 8 d of water deprivation and compared to the samples under control conditions. MDA accumulation was not significantly different in any of the genotypes under the control conditions. However, after withholding water, the phy mutants had significantly lower MDA, with concentrations of 0.5 and 0.6 µmol/L in phyA and phyB1B2, respectively, and an MDA concentration of 1.2 µmol/L in the WT (Figure 2b). These results indicate that both the phy mutants suppressed lipid peroxidation under drought conditions.
With respect to antioxidant properties, 2,2-diphenyl-1-picrylhydrazyl (DPPH) is used as a method to determine radical scavenging activities. The radical inhibition percentage was measured in the WT, phyA, and phyB1B2 plants under control and water-deprivation stress conditions. Under control conditions, there were no significant differences between the WT and either phy mutant, whereas under drought conditions, the phyA and phyB1B2 plants achieved significantly higher values of DPPH radical inhibition compared to the WT (Figure 2c). This indicates that phy mutants exhibited a high capacity for to scavenge DPPH free radicals compared with that of the WT tomato under drought conditions.  (Table S2).

Enhancing Leaf RWC and Shoot Water Content by phyA and phyB1B2 under Drought Stress
Leaf RWC is a water status index of tissues and generally decreases under drought stress [36]. Leaf RWC was measured in one-month-old WT, phyA, and phyB1B2 plants after 8 d of drought stress and compared to that of plants under control conditions. The results of leaf RWC did not exhibit any significant difference between WT and phy mutants under control conditions; however, after water withholding, leaf RWC was significantly decreased in the WT plants compared to that in the phy mutants. In addition, there was no significant difference between the leaf RWC of phyA and phyB1B2 plants under drought conditions (Figure 3a). Furthermore, the water content in the shoots of WT, phyA, and phyB1B2 was observed under control and drought conditions. There was no marked difference between the WT and phy mutants under control conditions, whereas under drought stress, the water content was decreased in all genotypes. However, the phyA and phyB1B2 plants exhibited a significantly higher water content in comparison with the WT (Figure 3b). These results suggest that both phy mutants can retain more water in their leaves and shoots under drought conditions.  (Table S2).
Moreover, under water stress, proline is one of the most common osmolytes in plants [35]. The level of proline was measured in one-month-old WT, phyA, and phyB1B2 plants after 8 d of water withholding and compared to plants under control conditions. No significant difference in proline accumulation was observed in any genotype under control conditions, but WT plants exhibited a significantly higher accumulation of proline than the phy mutants after drought stress ( Figure 2d). This is because of the lower expression levels of proline biosynthesis genes pyrroline-5-carboxylate synthase (P5CS) and pyrroline-5-carboxylate reductase (P5CR) in both phy mutants under drought conditions compared to their expression levels in WT plants ( Figure S1). These results indicate that the lack of proline accumulation did not affect the mechanism of phy mutants under drought stress.

Enhancing Leaf RWC and Shoot Water Content by phyA and phyB1B2 under Drought Stress
Leaf RWC is a water status index of tissues and generally decreases under drought stress [36]. Leaf RWC was measured in one-month-old WT, phyA, and phyB1B2 plants after 8 d of drought stress and compared to that of plants under control conditions. The results of leaf RWC did not exhibit any significant difference between WT and phy mutants under control conditions; however, after water withholding, leaf RWC was significantly decreased in the WT plants compared to that in the phy mutants. In addition, there was no significant difference between the leaf RWC of phyA and phyB1B2 plants under drought conditions ( Figure 3a). Furthermore, the water content in the shoots of WT, phyA, and phyB1B2 was observed under control and drought conditions. There was no marked difference between the WT and phy mutants under control conditions, whereas under drought stress, the water content was decreased in all genotypes. However, the phyA and phyB1B2 plants exhibited a significantly higher water content in comparison with the WT (Figure 3b). These results suggest that both phy mutants can retain more water in their leaves and shoots under drought conditions.  (Table S2).

Stomata Pore Area of phyA and phyB1B2 Did Not Change under Drought Stress
Stomata play an important role in water use efficiency and plant productivity by controlling water loss through transpiration and CO2 uptake for photosynthesis [37]. The stomatal pore areas of WT, phyA, and phyB1B2 plants were measured under control and water-withholding conditions. The resulting index of stomatal pore area was similar between the WT and phy mutants under both conditions. Tomato phyA and phyB1B2 exhibited significantly lower stomatal pore areas than the WT under both conditions (Figure 3c). These results indicate that stomatal closure status was not affected by drought stress in phy mutants.

Xylem Thickness of Tomato phyA and phyB1B2 and Their Water Uptake
Water and minerals are transported by a specialized vascular tissue called xylem [38]. To observe the xylem structure status of WT, phyA, and phyB1B2 plants, cross sections of the stems of one-month-old plants were prepared and checked under a microscope under control and water-withholding conditions. The xylem of WT appeared thicker than that of the phy mutants under both conditions, with WT values approximately 2-and 2.9-fold higher than those of phyA and phyB1B2, respectively, under control conditions, and 2.8and 3-fold higher than phyA and phyB1B2, respectively, under drought conditions ( Figure  4a-c).
Furthermore, the level of water uptake was measured in one-month-old WT, phyA, and phyB1B2 plants under control conditions. Tomato phyA and phyB1B2 exhibited significantly lower levels of water uptake than the WT plants. The average amount of water absorbed by WT plants was approximately 1.6-and 1.8-fold higher than that absorbed by phyA and phyB1B2 mutants, respectively (Figure 4d). According to these results, phyA and  (Table S2).

Stomata Pore Area of phyA and phyB1B2 Did Not Change under Drought Stress
Stomata play an important role in water use efficiency and plant productivity by controlling water loss through transpiration and CO 2 uptake for photosynthesis [37]. The stomatal pore areas of WT, phyA, and phyB1B2 plants were measured under control and water-withholding conditions. The resulting index of stomatal pore area was similar between the WT and phy mutants under both conditions. Tomato phyA and phyB1B2 exhibited significantly lower stomatal pore areas than the WT under both conditions (Figure 3c). These results indicate that stomatal closure status was not affected by drought stress in phy mutants.

Xylem Thickness of Tomato phyA and phyB1B2 and Their Water Uptake
Water and minerals are transported by a specialized vascular tissue called xylem [38]. To observe the xylem structure status of WT, phyA, and phyB1B2 plants, cross sections of the stems of one-month-old plants were prepared and checked under a microscope under control and water-withholding conditions. The xylem of WT appeared thicker than that of the phy mutants under both conditions, with WT values approximately 2-and 2.9-fold higher than those of phyA and phyB1B2, respectively, under control conditions, and 2.8-and 3-fold higher than phyA and phyB1B2, respectively, under drought conditions (Figure 4a-c).  (Table S2).  (Table S2). Furthermore, the level of water uptake was measured in one-month-old WT, phyA, and phyB1B2 plants under control conditions. Tomato phyA and phyB1B2 exhibited significantly lower levels of water uptake than the WT plants. The average amount of water absorbed by WT plants was approximately 1.6-and 1.8-fold higher than that absorbed by phyA and phyB1B2 mutants, respectively (Figure 4d). According to these results, phyA and phyB1B2 may efficiently conserve water.
2.6. Enhancement of the Expression of Genes Related to Water Transport and ROS Scavenging by phyA and phyB1B2 under Drought Stress To study the molecular response of phyA and phyB1B2 to water-deprivation stress, the relative expression of numerous genes associated with drought response, water transport, ABA biosynthesis and signaling, and antioxidant-mediated response (ROS scavengers) was analyzed in one-month-old WT, phyA, and phyB1B2 plants after 8 d of water withholding in comparison with under well-watered conditions. DEHYDRATION RESPONSIVE ELEMENT BINDING proteins (DREBs) are essential transcription factors that are induced by biotic and abiotic stresses and are independent of the ABA signaling pathway [39]. The expression of DREB2 was significantly lower in both phyA and phyB1B2 mutants than that in the WT plants under drought conditions, without any marked difference under control conditions (Figure 5a). Moreover, the expression levels of RESPONSIVE TO DESICCATION 29A (RD29A) and RD29B, which are dehydrationresponsive genes that enhance drought tolerance [40], under control conditions were higher in the phyA mutant than that in the WT and phyB1B2 mutant, without a significant difference between the latter two. In addition to RD29A and RD29B, the expression of EARLY RESPONSIVE TO DEHYDRATION 1 (ERD1), which is also a dehydration-responsive gene that enhances drought tolerance [40], was not significant in either phy mutant compared to the WT under non-stress conditions. In contrast, the expression level of these genes was markedly lower in phyA and phyB1B2 mutants than that in the WT plants under drought conditions (Figure 5a). Additionally, the expression levels of other stress-responsive genes, including GLYCINE RICH PROTEIN (GRP) and dehydrins (LEA and DRCi7), were detected under control and stress conditions. The GRP expression level was lower in both phy mutants compared to the WT under both conditions. Moreover, the expression of LEA and DRCi7 under control conditions was not significant between the WT and phyA mutant, whereas the phyB1B2 showed a significantly higher value in DRCi7 expression (Figure 5a). Under drought conditions, there was a markedly higher expression of GRP, LEA, and DRCi7 in the WT plants than in phy mutants (Figure 5a). These results suggest that phyA and phyB1B2 mutants did not stimulate the expression of these drought-responsive genes under drought stress.
ZEAXANTHIN EPOXIDASE (ZEP) and 9-CIS-EPOXYCAROTENOID DIOXYGE-NASE (NCED) are important enzymes in ABA biosynthesis and are key regulators of plant responses to abiotic stresses [41,42]. In addition, PROTEIN PHOSPHATASE 2Cs (PP2Cs) is a drought-responsive regulatory protein that is essential for plant drought defense and is known to be a negative regulator of ABA signaling [43]. For the ABA-dependent pathway, the expression levels of ZEP, NCED1, and PP2C were examined. Under control conditions, the expression level of these genes was insignificant between the WT and phy mutants, whereas under drought stress, the expression level of ZEP was not markedly different between the WT and either phy mutant. However, the PP2C expression level was markedly lower in both phy mutants compared to WT plants. Similarly, the NCED1 expression level was significantly lower in the phyB1B2 mutant than in the WT and phyA plants, with a nonsignificant difference between the expression levels in the latter two (Figure 5b). According to these results, phyA and phyB1B2 mutants did not enhance the ABA signaling pathway under water deprivation. 5c). These results suggest that phy mutants display better water and substrate flux than WT plants.  (Table S3).  (Table S3). TONOPLAST INTRINSIC PROTEINs (TIPs) are plant AQPs that are localized in the tonoplasts and are key to bidirectional water and substrate movement across cell membranes [44]. PLASMA MEMBRANE INTRINSIC PROTEINs (PIPs) are AQPs that mediate water transport in several plant species [45]. Three AQPs were analyzed as water-transport-responsive genes: TIP1.1, TIP2.2, and PIP2.5. Under non-stress conditions, the expression levels of TIP 1.1 and TIP2.2 were significantly higher in the phyA mutant than in the WT. Similarly, the expression levels of TIP 2.2 and PIP2.5 were significantly higher in phyB1B2 than in the WT. Under drought conditions, TIP1.1, TIP2.2, and PIP2.5 expressions were significantly higher in phyA and phyB1B2 mutants compared to the WT (Figure 5c). These results suggest that phy mutants display better water and substrate flux than WT plants.
Antioxidant mechanisms prevent plants from suffering oxidative damage resulting from drought stress [46]. The expression levels of ASCORBATE PEROXIDASE 1 (APX1), APX2, CATALASE 1 (CAT1), and CAT2 were analyzed as antioxidant scavengers. Under normal conditions, the expression level of the ROS scavenger genes was not significant between the WT and phy mutants, except in CAT2 expression, which was lower in the phyB1B2 mutants compared to the WT. On the other hand, under drought stress, the expression level of APX1 was significantly upregulated in the phyA mutant compared with that in the WT and phyB1B2 mutant, without any marked difference between the latter two. Both phy mutants exhibited a significantly higher APX2 expression level in comparison with the WT. Similarly, the phyA and phyB1B2 mutants showed higher CAT1 and CAT2 expression levels compared to the WT plants, which was insignificant in the case of phyA and significant in the phyB1B2 mutant (Figure 5d). These results indicate that the inhibition of oxidative damage participates in the tolerance response of phyA and phyB1B2 to water deprivation.

Discussion
Tomato phyA and phyB1B2 mutants exhibited a healthy tolerant phenotype under drought conditions (Figure 1). However, the phyA mutant showed inhibition in its growth pattern after drought application (Figure 1f-l), probably because plants can adapt to drought stress by altering their growth patterns and plant morphology and by activating their defense mechanisms [47] such as root thinning and shoot growth reduction to prevent water loss through transpiration [48]. This might indicate that the phyA mutant induced this inhibition to control water loss and plant metabolic processes. In contrast, the phyB1B2 mutant showed no significant growth inhibition under drought stress, possibly due to its fewer values of vegetative characteristics under non-stress conditions, compared to the WT and phyA plants, except for the plant stem height, which was longer under control conditions and was significantly inhibited by drought stress (Figure 1f-l). In contrast, the reduction in the growth pattern of the WT plants with their severely wilted phenotype under drought stress (Figure 1) indicates that this inhibition was not related to stress adaptation; instead, it occurred due to plant growth breakdown. This hypothesis could explain the reduction in plant vegetative growth in phy mutants during drought adaptation. However, the WT plants showed a higher plant FW with a thicker stem, which indicates their high biomass. They had smaller stems than the phy mutants (Figure 1f-l), which might be due to the function of PHYs A and B genes in controlling plant elongation and inhibiting hypocotyl elongation [49].
Moreover, the physiological response of both phy mutants to drought stress was different than that of the WT. Generally, plants promote various physiological and biochemical responses as resistance and adaptation mechanisms to cope with drought stress [21]. Higher EL% [50] and MDA content [51] are indicators used to identify injured cell membranes [52]. Additionally, drought stress can enhance MDA accumulation, owing to the disruption of the antioxidant enzyme system, ROS accumulation, membrane lipid peroxidation, and, eventually, membrane damage [53]. The EL and MDA accumulation were significantly lower in tomato phyA and phyB1B2 mutants than in the WT under drought stress (Figures 1m and 2b), indicating the enhancement of cell membrane protection and stress tolerance.
In addition to the role of MDA in oxidative damage and cell membrane damage, ROS hyperproduction stimulates oxidative damage to macromolecules and cell structures and disrupts metabolism, leading to cell death [54,55]. Additionally, the balance between ROS generation and elimination is critical for plant survival and growth under drought conditions [56]. APX and CAT are antioxidant enzymatic components that scavenge ROS to ensure plant survival under stress [57]. In this study, the expression of antioxidant enzymatic genes APX or CAT was upregulated in phyA and phyB1B2 mutants (Figure 5d), which suppressed ROS accumulation in association with the scavenging of H 2 O 2 and DPPH free radicals in these mutants (Figure 2a,c) in comparison with the WT under drought stress, indicating the stimulation of antioxidant activity. Moreover, ROS production can be enhanced by stomatal closure and a reduction in CO 2 availability, which is important for photosynthetic enzymes, as well as a disequilibrium between photochemical and biochemical actions of leaves [56,58]. Furthermore, stomatal closure is a common adaptation response in plants to drought stress [27]. Thus, the balance between stomatal closure and ROS accumulation is important against stress tolerance. Tomato phyA and phyB1B2 did not enhance stomatal closure under drought stress, showing the same index of stomatal pore area as the WT under both non-stress and stress conditions. However, the stomatal pore area was significantly smaller in both phy mutants than that in the WT plants (Figure 3c), suggesting lower water loss.
It was reported that the PHYA and PHYB genes are related to the stomatal opening. In Arabidopsis, a mutation in the PHYB gene resulted in inhibition of the stomatal opening. Additionally, a double phyAphyB mutant downregulated the expression of the MYB60 gene, which is involved in the stomatal opening, compared to a phyB mutant under red light [59]. Furthermore, Arabidopsis phyA and phyB mutants under far-red and red light, respectively, exhibited significantly lower values of the stomatal and meristemoid index compared to the WT [60]. Thus, in the present research, the lack of change in stomatal pore area of phy mutants under drought stress compared to normal conditions, with a smaller area than that in the WT, was due to the function of PHY genes in regulating stomatal opening, in addition to the role of tomato PHYA, PHYB1, and PHYB2 in stomatal conductance, which was reduced in the mutated plants compared to the WT [15]. There is an additional reason that might make the stomatal pore area of phy mutants smaller than that in the WT (Figure 3c) according to previous reports showing that as water travels through the xylem, it is drawn into mesophyll cell walls and evaporated via stomatal pores [28,61]. The xylem of the phyA and phyB1B2 mutants is significantly thinner, and the level of water uptake is lower compared to those of the WT (Figure 4c,d), which perhaps helped in stomatal pore closure. This smaller stomatal pore area in phy mutants (Figure 3c) might participate in increasing the percentage of leaf RWC in both phyA and phyB1B2 mutants in comparison with the WT under drought stress (Figure 3a), resulting in an improved water status index of tissues [36].
Furthermore, the regulation of water transportation inside the plant and water uptake from the soil play important roles in drought tolerance. For water transportation inside the plant, AQPs play a key role in facilitating the transportation of water and other small molecules through cell membranes, as well as in water conservation and ion balance in plants; moreover, they are important for cell integrity, growth, and survival of plants under environmental changes [62]. In tomato phyA and phyB1B2, the expression of AQPs (TIP1;1, TIP2;2, and PIP2;5) was higher than in the WT under drought stress (Figure 5c). TIP1;1 is essential for plant life and plays a beneficial role in plant growth under stress. In Arabidopsis, the loss of TIP1;1 caused early senescence and death [63]. In addition, the expression of TIP 2;2 was enhanced in poplar DREB6 overexpressed lines that exhibited drought tolerance [64]. Moreover, under drought conditions, overexpression of SlPIP2;5 in tomato resulted in significantly higher survival rates, improved plant water content, and maintenance of osmotic balance [65]. Similarly, HvPIP2;5-overexpressing barley plants experienced enhanced survival and recovery under the same conditions [66]. The upregulation of TIP1;1, TIP2;2, and PIP2;5 expression in phyA and phyB1B2 mutants indicates the enhancement of water transport in plants, even under water-deprivation conditions (Figure 5c). With respect to water uptake from the soil, the efficient use of water with better growth under conditions of finite water resources is considered a desired plant trait under drought conditions [67]. The level of water uptake was lower in phyA and phyB1B2 mutants (Figure 4d), indicating the regulation of water consumption and the enhancement of water use efficiency. This lower water uptake might be due to the smaller root area of phyA and phyB1B2 under either control or drought conditions (Figure 1f), in addition to their thinner xylem zones under these conditions (Figure 4c). Thus, this lower water uptake by phy mutants as a result of their stomatal pore area status might decrease the level of water loss, which is confirmed by the higher water content in the shoots of these mutants (Figure 3b,c) and by the high level of leaf RWC (Figure 3a) compared to the WT, resulting in regulation of water consumption for improved utilization, which was found to be better in phy mutants than the WT. This indicates that in terms of water consumption, the phy mutants utilized absorbed water from the soil efficiently by decreasing the water loss percentage.
Despite the tolerance phenotype the phyA and phyB1B2 mutants, the expression levels of the drought-responsive genes, including DREB2 and several stress-inducible and ABA-inducible genes, were not enhanced under water scarcity ( Figure 5) because both phy mutants stimulated the defense system against oxidative damage by enhancing the expression of ROS scavengers (Figure 5d), which are usually suppressed in sensitive plants by drought stress [68]; by promoting antioxidant activity; by enhancing the percentage of free radical inhibition (Figure 2c); and by inhibiting H 2 O 2 accumulation, which meant that other drought-inducible and ABA-inducible genes did not need to be enhanced. The stimulation of the hydrostatus in both phy mutant plants by enhancing leaf RWC and shoot water content relative to the WT plants (Figure 3a,b) led to their drought-tolerant response.
In conclusion, tomato phyA and phyB1B2 mutants exhibited drought tolerance by inhibiting oxidative damage, which is an important negative effect of drought. The inhibition of oxidative damage caused by enhancing the expression of ROS scavenger genes and the antioxidant activities and inhibition of H 2 O 2 accumulation, as well as the inhibition of MDA accumulation, led to enhanced cell membrane protection, as indicated by the inhibition of EL from the cells under drought stress. Furthermore, phy mutants showed enhanced leaf RWC% and shoot water content, owing to their smaller stomatal pore area and higher expression level of several AQPs under drought stress. As a result of ROS scavenging and plant water status in phyA and phyB1B2 mutants under drought stress, the plants exhibited a healthy phenotype without requiring the enhancement of drought-inducible or ABA-inducible genes ( Figure 6). Thus, the PHYA and PHYB genes might be suitable potential targets to enhance drought tolerance in other plant species. of water loss, which is confirmed by the higher water content in the shoots of these mutants (Figure 3b,c) and by the high level of leaf RWC (Figure 3a) compared to the WT, resulting in regulation of water consumption for improved utilization, which was found to be better in phy mutants than the WT. This indicates that in terms of water consumption, the phy mutants utilized absorbed water from the soil efficiently by decreasing the water loss percentage. Despite the tolerance phenotype the phyA and phyB1B2 mutants, the expression levels of the drought-responsive genes, including DREB2 and several stress-inducible and ABA-inducible genes, were not enhanced under water scarcity ( Figure 5) because both phy mutants stimulated the defense system against oxidative damage by enhancing the expression of ROS scavengers (Figure 5d), which are usually suppressed in sensitive plants by drought stress [68]; by promoting antioxidant activity; by enhancing the percentage of free radical inhibition ( Figure 2c); and by inhibiting H2O2 accumulation, which meant that other drought-inducible and ABA-inducible genes did not need to be enhanced. The stimulation of the hydrostatus in both phy mutant plants by enhancing leaf RWC and shoot water content relative to the WT plants (Figure 3a,b) led to their droughttolerant response.
In conclusion, tomato phyA and phyB1B2 mutants exhibited drought tolerance by inhibiting oxidative damage, which is an important negative effect of drought. The inhibition of oxidative damage caused by enhancing the expression of ROS scavenger genes and the antioxidant activities and inhibition of H2O2 accumulation, as well as the inhibition of MDA accumulation, led to enhanced cell membrane protection, as indicated by the inhibition of EL from the cells under drought stress. Furthermore, phy mutants showed enhanced leaf RWC% and shoot water content, owing to their smaller stomatal pore area and higher expression level of several AQPs under drought stress. As a result of ROS scavenging and plant water status in phyA and phyB1B2 mutants under drought stress, the plants exhibited a healthy phenotype without requiring the enhancement of droughtinducible or ABA-inducible genes ( Figure 6). Thus, the PHYA and PHYB genes might be suitable potential targets to enhance drought tolerance in other plant species.

Plant Materials and Growth Conditions
To study the role of tomato PHYA, PHYB1, and PHYB2 genes in response to drought stress, tomato (Solanum lycopersicum L. 'Moneymaker') WT, phyA mutant, and phyB1B2 double mutant [69] plants were used. The seeds were grown in 0.35 L soil pots and incubated in a controlled culturing room, where the average temperature was 25 • C and the average light intensity was 35 µmol/m 2 s for a cycle of 16 h light and 8 h dark. At the age of one month, plants were exposed to drought conditions.

Drought Application
Plants were exposed to drought stress by water withholding for 8 d to study the plant phenotypic, physiological, and molecular response. Plant responses were further confirmed by observing the phenotypic response during the flowering stage by exposing the plants to water withholding for 12 d under sunlight conditions in the greenhouse.

Morphological Phenotype under Drought Stress
Phenotypes were observed in vegetative and flowering stages after drought treatment. Morphological phenotype characteristics, including root surface area, length of root, stem height (from the soil surface), stem thickness, plant FW, leaf FW, and leaf number/plant, were measured after 8 d of water withholding compared to control conditions.

EL%
The EL was measured as specified in [70]. Leaf samples were collected after water withholding for 8 d. The leaf surface was washed with Milli-Q water (MQ) and flooded in a tube filled with MQ for 12 h, after which the ionic conductivity 1 (C1) was measured using a conductivity meter (Lutron Electronics Co., Inc., Upper Saucon Township, PA, USA). The samples were then autoclaved at 121 • C for 10 min, and conductivity was re-examined (C2) once the samples reached 20-25 • C. The EL% was calculated using the following formula:

H 2 O 2 Content
H 2 O 2 content was measured as described in [71] with some modifications. First, 0.2 g of plant leaves from WT and phy mutant plants after 8 d of water withholding and control conditions was ground in 1 mL of trichloroacetic acid (TCA) (Nacalai tesque, Kyoto, Japan) 0.1%. Then, 0.25 mL from the supernatant was added to 0.5 mL of 100 mM potassium phosphate (Wako, Osaka, Japan) buffer and 1 mL of 1 M potassium iodide (Wako, Osaka, Japan). The samples were incubated in the dark for 1 h, and the absorbance was read at 390 nm using a DU800 UV/Vis spectrophotometer (Beckman Coulter, Inc., Brea, CA, USA). Using a standard curve, the H 2 O 2 concentration was calculated, with TCA 0.1% used as a blank.

MDA Content
The concentrations of MDA were measured in WT and phy mutants after 8 d of water withholding and control conditions, as described in [18]. First, 0.3 g FW of leaf was ground in 3 mL of 10% (v/v) trichloroacetic acid (TCA) (Nacalai tesque, Kyoto, Japan). Then, after 15 min of centrifugation at 10,000 rpm, 2 mL from the supernatant was mixed with 2 mL of 0.6% thiobarbituric acid (TBA) (Nacalai tesque, Kyoto, Japan) (w/v in 10% TCA). After 20 min heating in boiled water, the mixture was cooled to room temperature. The mixture was then centrifuged at 10,000 rpm for 15 min, and the absorbance was read at 450, 532, and 600 nm by a DU-800 spectrophotometer, and the MDA concentration was calculated using the following formula:

Radical Inhibition
To analyze the percentage of radical inhibition, the scavenging of DPPH free radicals was analyzed in tomato leaves as described previously [72]. A mixture of 0.2 mM DPPH solution (Nacalai tesque, Kyoto, Japan) with ethanol (Nacalai tesque, Kyoto, Japan) was used as a control. A DU800 UV/Vis spectrophotometer was used to read the absorbance at 517nm. The following formula was used to calculate the percentage of radical inhibition: Radical inhibition (%) = Control absorbance − tested sample absorbance Control absorbance × 100 (3)

Proline Content
The level of proline was measured in WT and phy mutants after 8 d of water withholding and control conditions, as described in [18]. First, 1 g of fresh leaves was ground after freezing in liquid nitrogen, homogenized with 5 mL of sulfosalicylic acid (Nacalai tesque, Kyoto, Japan) (3%), and centrifuged at 3000 rpm for 5 min. Then, 1 mL of the supernatant was mixed with 2 mL of both of glacial acetic acid (Sigma-Aldrich, Tokyo, Japan) and acid ninhydrin (Nacalai tesque, Kyoto, Japan) (0.62 ninhydrin warmed to be dissolved in 15 mL glacial acetic acid and 10 mL 6M phosphoric acid (Wako, Osaka, Japan)) for 1 h at 100 • C; the reaction was stopped in ice. The reaction mixture was then vigorously mixed with 10 mL of toluene (Nacalai tesque, Kyoto, Japan). The chromophore containing toluene was aspirated from the aqueous phase and reached room temperature (20-25 • C). The absorbance was read at 520 nm using a DU-800 spectrophotometer and calculated according to the following equation: Proline (µmol/g) = A 520 (µg proline /mL) × Toluene amount(mL) 115.13 / Sample FW(g) 5 (4)

Leaf RWC
The RWC of leaves grown under control and drought (8 d of water withholding) conditions was measured as described previously in [73]. To measure the leaf RWC, the leaf FW, turgid weight (TW), and dry weight (DW) were recorded as follows. First, the FW of the leaves were measured; next, they were immersed in dH 2 O until fully turgid and they reached a constant weight (4 h); then, TW was measured. Then, the leaves were dried until they reached a constant weight, and the DW was measured. Finally, RWC was calculated using the following equation:

Shoot Water Content
The water content in the shoots was determined as described previously [74]. The FW and the DW of the vegetative organs (upper ground organs) of one-month-old WT, phyA, and phyB1B2 plants were recorded after 8 d under water-withholding conditions compared to well-watered conditions. The shoot water content was calculated using the following formula.

Microscopic Analysis
The stomatal pore condition and xylem structure were analyzed using an Olympus BX50 microscope (Olympus, Tokyo, Japan). The preparation of leaf samples for stomatal analysis was described previously in [18]. Fresh leaflets were collected from plants under control and water-withholding stress conditions, and a thick tape was pasted on their upper surface. The tape was gently pulled from the leaflet to tear off the epidermis layer and placed on a glass slide. Other leaf parts were cut off using a scalpel. A coverslip was placed on the sample after adding a drop of water. The slides were observed at 1000× magnification to determine the stomatal pore area. Due to their elliptical shape, the following formula was used to calculate the stomatal pore area: Stomatal pore area µm 2 = π × r 1 × r 2 (7) where π = 3.14, and r 1 and r 2 are the minor and major radii of the stomatal pores, respectively. To observe the xylem structure, a cross section of the stem was obtained from onemonth-old plants under control and drought stress using a scalpel. Then, the sections were immersed in 0.05% toluidine-blue-O (TBO) (Waldeck, Münster, German) for 30 s and washed with dH 2 O several times. The sections were then examined under 100× A magnification using an Olympus BX50 microscope (Olympus, Tokyo, Japan).

Plant Water Uptake Level
To measure plant water uptake, WT, phyA, and phyB1B2 plants were placed in a 50-mL polypropylene tube (one plant per tube) with 40 mL dH 2 O. The absorbed water was checked every 12 h for 3 consecutive days, with dH 2 O being refilled every 12 h. After 3 d, the average water absorbance was calculated.

RNA Isolation and Quantitative RT-PCR
Total RNA was extracted from leaf samples of WT and phy mutants using TRIzol reagent (Thermo Fisher Scientific, Waltham, MA, USA) according to the manufacturer's instructions. cDNA synthesis and real-time PCR were performed as previously described in [18]. An amount of 2 µg of RNA was used to synthesize cDNA using a high-capacity cDNA reverse transcription kit (Thermo Fisher Scientific, Waltham, MA, USA). Primers used for real-time PCR are listed in Table S4. THUNDERBIRD SYBR qPCR Mix (Toyobo, Osaka, Japan) was used for RT-PCR amplification and detection with a 7900HT real-time PCR system (Applied Biosystems/Thermo Fisher Scientific, Waltham, MA, USA). Relative transcript abundance was calculated using the comparative C T method, as described in [75]. The ∆C T of WT under control conditions was used as a subtrahend factor in the ∆∆C T subtraction formula for comparison with phy mutants under control and drought stress conditions, as in the following: ∆∆CT (∆CT (Tested) − ∆CT, (WT under control) ). The tomato-expressed sequence gene (EXPRESSED) (Gene ID: Solyc07g025390.2.1) was used as a reference endogenous control for gene expression analyses [76].

Statistical Analyses
Three independent biological experiments were conducted in this study using 4-6 plants for each replicate. Analysis of variance (ANOVA) was used to analyze the recorded quantitative data, and a post hoc Tukey HSD test was conducted to compare the mean values using IBM SPSS statistics software (version: 29.0 (241)). The p-values of ANOVA are presented in each figure, and the p-values of post hoc tests are presented in the Supplementary Materials (Tables S1-S3).