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Article

Combined Acute Ozone and Water Stress Alters the Quantitative Relationships between O3 Uptake, Photosynthetic Characteristics and Volatile Emissions in Brassica nigra

by
Kaia Kask
1,*,
Eve Kaurilind
1,
Eero Talts
1,
Astrid Kännaste
1 and
Ülo Niinemets
1,2
1
Chair of Crop Science and Plant Biology, Institute of Agricultural and Environmental Sciences, Estonian University of Life Sciences, Kreutzwaldi 1, 51006 Tartu, Estonia
2
Estonian Academy of Sciences, Kohtu 6, 10130 Tallinn, Estonia
*
Author to whom correspondence should be addressed.
Molecules 2021, 26(11), 3114; https://doi.org/10.3390/molecules26113114
Submission received: 3 May 2021 / Revised: 20 May 2021 / Accepted: 21 May 2021 / Published: 23 May 2021
(This article belongs to the Special Issue Recent Discoveries and New Approaches to the Study of Plant Volatiles)
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Abstract

:
Ozone (O3) entry into plant leaves depends on atmospheric O3 concentration, exposure time and openness of stomata. O3 negatively impacts photosynthesis rate (A) and might induce the release of reactive volatile organic compounds (VOCs) that can quench O3, and thereby partly ameliorate O3 stress. Water stress reduces stomatal conductance (gs) and O3 uptake and can affect VOC release and O3 quenching by VOC, but the interactive effects of O3 exposure and water stress, as possibly mediated by VOC, are poorly understood. Well-watered (WW) and water-stressed (WS) Brassica nigra plants were exposed to 250 and 550 ppb O3 for 1 h, and O3 uptake rates, photosynthetic characteristics and VOC emissions were measured through 22 h recovery. The highest O3 uptake was observed in WW plants exposed to 550 ppb O3 with the greatest reduction and poorest recovery of gs and A, and elicitation of lipoxygenase (LOX) pathway volatiles 10 min–1.5 h after exposure indicating cellular damage. Ozone uptake was similar in 250 ppb WW and 550 ppb WS plants and, in both treatments, O3-dependent reduction in photosynthetic characteristics was moderate and fully reversible, and VOC emissions were little affected. Water stress alone did not affect the total amount and composition of VOC emissions. The results indicate that drought ameliorated O3 stress by reducing O3 uptake through stomatal closure and the two stresses operated in an antagonistic manner in B. nigra.

1. Introduction

Tropospheric O3 is a phytotoxin and considered as one of the most damaging greenhouse gases; it is mainly formed via photochemical reactions involving nitrogen oxides (NOx) and volatile organic compounds (VOCs) [1,2,3]. According to recent studies, tropospheric O3 concentration is beginning to stabilize [4,5,6]; nevertheless, the current O3 levels reduce plant photosynthesis and growth rates and decrease potential agricultural productivity in many areas of the world [7,8,9]. Average O3 concentrations vary between 14.5 and 70.1 ppb during the growing season in the forests of Europe [10], but during heat waves O3 concentrations can be even higher [11,12].
The impact of O3 is often studied using short-term acute treatments when plants are exposed to high O3 for several minutes to some hours, and resultant visible damage symptoms on leaves and modifications in photosynthetic activity are monitored [13,14,15]. O3 enters in the leaves through stomata and the O3 exposure inhibits stomatal conductance to water vapor (gs) [16] and leads to reductions in net assimilation rate (A), whereas plants may or may not recover depending on the O3 dose [17]. O3 also activates the production of reactive oxygen species (ROS) [18,19], which in turn activate various defense reactions related to non-volatile and/or volatile metabolites depending on the plant species and genotype [20,21,22,23,24]. Characteristically, O3 exposure leads to emissions of methanol and lipoxygenase (LOX) pathway volatiles due to damaged cell walls and cell and organelle membranes [23,25] and might also result in emissions of the stress hormone methyl salicylate [20,23,26].
Next to O3, drought stress is estimated to have become more widespread and severe due to climate change [27,28]. It is relatively well known how reduced water availability impacts plant photosynthetic characteristics, including reductions of the assimilation rate due to stomatal closure for mild to moderately severe water deficits, and stomatal and non-stomatal reductions of the assimilation rate for more severe and sustained water stress [29,30,31,32]. There is much less information on how plant constitutive VOC emission is affected by drought. Mild to moderate water stress can enhance and severe stress curb VOC emissions due to substrate limitations resulting from reduced photosynthetic carbon input [33,34,35,36]. However, constitutive VOC emission levels strongly vary among species [37,38,39], and the substrate limitations might not necessarily limit the emissions in relatively low volatile emitters. Furthermore, drought stress differs from other abiotic stresses, such as heat, in that it seldom results in induction of stress volatiles [40,41] or only leads to a minor elicitation of stress volatiles [26]. Although drought itself does not necessarily lead to elicitation of stress volatiles, it could prime the plants to subsequent stresses, implying modified responses of photosynthetic and volatile emission characteristics upon exposure to a different stress such as ozone stress [26,40,42,43]. Yet, only a few studies have investigated the impact of combined drought and ozone stresses and simultaneously monitored both photosynthetic and VOC emission characteristics [26]. Although both drought and O3 reduce gs, O3 can cause stomatal sluggishness, i.e., reduce the responsiveness of stomata to environmental clues such as light and humidity, disturbing the effective control of transpiration [44] and making the plants more vulnerable to the following stresses [45]. On the other hand, drought that precedes O3 stress can reduce stomatal ozone uptake and thereby reduce O3-dependent damage [36,46], but whether the impact of drought on plant O3 response is only due to reduced O3 uptake or whether there is a significant interactive effect among drought and O3 on photosynthesis and volatile emissions, e.g., due to drought priming, is not known.
Brassicaceae constitute an important plant family that includes many agriculturally important species and their wild relatives. Species from this family are typically low-level constitutive volatile emitters [47,48], but they include a myrosinase/glucosinolate defense system, constituting of separately stored myrosinase enzymes and non-volatile glucosinolates [49,50,51]. Upon cellular damage, myrosinase comes into contact with glucosinolates, leading to synthesis of toxic volatile glucosinolate breakdown products that result in a characteristic blend of volatiles [52,53]. Volatile glucosinolate emissions are usually associated with herbivory, but severe abiotic stress that results in cellular damage, such as heat stress, can also lead to emissions of glucosinolate breakdown products [47]. So far, the available evidence of the O3 effects on glucosinolates is inconclusive. In O3-stressed B. campestris L. ssp. chinensis [54] and B. napus [55], the content of different glucosinolates was differently affected. In another study, O3 levels of 70, 80 and 120 ppb had no significant effect on VOCs emitted by leaves and flowers of B. nigra [56,57]. Analogously, a chronic low-level (80 ppb for 5 days) O3 exposure did not elicit glucosinolate emissions in different Brassicaceae species [58]. However, it is unclear how glucosinolates might respond to a more severe O3 stress and O3 exposure combined with drought. The volatile glucosinolate degradation products (isothiocyanates, thiocyanates, nitriles) fulfil an essential role in plant-to-plant and plant-to-insect communication at multiple trophic levels [59,60,61,62,63], and understanding the abiotic stress impacts on these emissions is of major importance for predicting plant communication in multistress natural environments.
Next to Arabidopsis thaliana, the classical brassicaceous model, another species, black mustard (Brassica nigra (L.) W. D. J. Koch) is giving valuable knowledge to the glucosinolate pathway [64,65,66,67]. Brassica nigra is a large plant, 0.5–2 m tall with highly competitive capacity in rural sites; it has a more complex genome and greater tolerance to several environmental stresses than A. thaliana [66,67,68]. In a previous study, B. nigra had surprisingly high heat stress tolerance and a complex heat stress response [47]. In particular, the heat stress response in B. nigra was characterized by different responses of constitutive and stress-induced specialized and generic volatiles and photosynthetic characteristics, including major emissions of glucosinolate breakdown products [47].
The aims of the current study were to investigate how acute and moderate O3 exposures alter foliage photosynthetic characteristics and VOC emissions and whether drought modifies O3 effects in an interactive manner. We hypothesized that (1) acute O3 treatment leads to major reductions in photosynthetic characteristics (A, gs); (2) emissions of specific glucosinolate breakdown products and LOX compounds are enhanced in the recovery phase; (3) the rates of these volatile emissions depend on stomatal O3 uptake; (4) drought and O3 affect plant volatile emissions in an interactive manner.

2. Results

2.1. Impacts of Water Stress on Photosynthetic Characteristics and O3 Uptake by Leaf Surface and Stomata

In non-ozone-treated plants, net assimilation rate (A, mean ± SE) was 15.5 ± 1.7 µmol m−2 s−1 for well-watered (WW) and 10.9 ± 1.7 µmol m−2 s−1 for water-stressed (WS) plants and stomatal conductance (gs) was 300 ± 60 mmol m−2 s−1 for WW and 107 ± 12 mmol m−2 s−1 for WS plants. The ratio of intercellular to ambient CO2 concentrations (Ci/Ca) in non-ozone-treated WW plants was 0.6–0.8 (Ci = 261 ± 10 µmol mol−1) and 0.2–0.4 (Ci = 122 ± 8 µmol mol−1) for WS plants (all means are different at p < 0.001).
The highest O3 uptake was observed in WW plants exposed to 550 ppb O3 at all time-points, at the beginning (ca. 5 min from the start of fumigation), in the middle (0.5 h after start of fumigation) and at the end (1 h after the fumigation), reaching 317 ± 25 µmol m−2 by the end of the treatment (Figure 1). O3 uptake of WW plants exposed to 250 ppb O3 and WS plants exposed to 550 ppb O3 was similar (Figure 1). O3 uptake in these plants varied by only around 16 to 23 µmol m−2 at the beginning of the fumigation and around 100 to 140 µmol m−2 at the end of the fumigation (Figure 1; O3 uptake was significantly greater for WW plants exposed to 550 ppb O3 than in the plants in the other two treatments).
At different times during the exposure period, average (±SE) surface O3 uptake rate (including uptake by surface and ozone quenching by plant-emitted reactive hydrocarbons) of WW plants exposed to 550 ppb O3 (41 ± 5 nmol m−2 s−1) for the whole exposure period was higher than that of WW plants exposed to 250 ppb O3 (13 ± 1 nmol m−2 s−1; Table 1). For WS plants exposed to 550 ppb O3, the surface O3 uptake rate was intermediate (25.3 ± 0.4 nmol m−2 s−1, Table 1).
Stomatal O3 uptake rate in WW plants exposed to 550 ppb O3 was higher than in the other two treatments and reached up to 53 ± 4 nmol m−2 s−1 (Figure 2, Table 1). Stomatal O3 uptake rates of WW and WS plants exposed to 250 and 550 ppb O3 ranged from 12 to 17 nmol m−2 s−1 through the exposure period (Table 1). Within treatments, there were only minor time-dependent variations in surface and stomatal O3 uptake rate and the ratios of surface and stomatal O3 uptake rates to whole leaf uptake rate (Table 1). O3 exposure concentration increased surface and stomatal O3 uptake rates through all treatments, but the share of surface vs. stomatal uptake rate did not differ significantly among O3 concentrations (Table 1). Strong positive relationships between the stomatal O3 uptake and gs were observed for both 250 ppb and 550 ppb O3 fumigations (p < 0.001; Figure 2).

2.2. Changes in Photosynthetic Characteristics Upon Ozone Exposure

O3 exposure reduced A in all cases (significant O3 effect in Figure 3A) with the reduction observed already 10 min after the exposure to O3, followed by a more gradual reduction between 10 min and 4.5 h, and a minor recovery between 7.5 and 22 h for WS plants exposed to 550 ppb O3 and WW plants exposed to 250 ppb O3, whereas A continuously decreased in WW exposed to 550 ppb O3 (significant time and O3 x time effects in Figure 3A). The reduction was greater in plants that took up more O3 (Table 1). In particular, at the time point of maximum photosynthetic reduction at 4.5 h, the reduction in A was greater in WW plants exposed to 550 ppb O3 than that in WS plants exposed to 550 ppb and greater than in WW plants exposed to 250 ppb O3 (Figure 3A).
Differently from A, gs showed a decreasing trend only in WW plants exposed to 550 ppb O3, although there was a globally significant O3 effect across all treatments (Figure 3B). In WS plants exposed to 550 ppb O3, gs changed little with a significant, but minor reduction, only observed at 7.5 h after O3 treatment (Figure 3B). Taken together, 550 ppb O3 exposure effect on gs was greater for WW than for WS plants (Figure 3B). In the case of WW plants exposed to 250 ppb, gs increased during recovery, and gs was greater than that in control leaves at the end of the measurements (Figure 3B). Both WW plants exposed to 250 and 550 ppb O3 had a higher Ci/Ca at 22 h recovery point than the controls (Figure 4A). Ci/Ca in WS plants exposed to 550 ppb was almost constant with a minor reduction at 7.5 h after treatment (Figure 4A). During the recovery period, Ci/Ca ratio was positively correlated with gs in WW plants exposed to 250 ppb O3 and WS plants exposed to 550 ppb O3 (Figure 4B). A values during recovery also correlated positively with Ci/Ca ratio in WW and WS plants exposed to 550 ppb O3 (p = 0.02 for both; p = 0.09 for WW plants exposed to 250 ppb O3; data now shown).

2.3. Drought and O3 Impacts on Total Volatile Emissions and Emissions of Different Volatile Groups

In control plants, the total VOC emissions were dominated by saturated aldehydes and geranyl diphosphate (GDP, monoterpenes) or geranylgeranyl diphosphate (GGDP) pathway compounds (carotenoid breakdown products); most WW and WS plants before O3 treatment showed similar total VOC emission rates (Figure 5). O3 exposure and water stress (for plants exposed to 550 ppb O3) modified the share of different volatile groups depending on treatment (Figure 6, see below), but total emissions were not affected (Figure 5).
O3 exposure affected all groups of volatiles except glucosinolate breakdown products and saturated aldehydes, but the effects were treatment-specific (Figure 6). LOX compound emissions in WW plants exposed to 250 ppb O3 at 10 min and 22 h measurements were enhanced compared to control leaves (Figure 6A). In 550 ppb exposed plants, the LOX compound emissions were greater in WW than in WS plants through the recovery (Figure 6A). For GDP and GGDP compound emissions, O3 enhanced emissions, but the emissions at different recovery time points differed little (Figure 6C,D). Only in WW plants exposed to 250 ppb O3, the emission of GGDP compounds was greater at 10 min recovery time point compared with the control and other recovery times (Figure 6D). Water stress inhibited GDP and GGDP compound emissions in plants exposed to 550 ppb O3 (Figure 6C,D). For saturated aldehydes, the treatments generally had a minor effect. Saturated aldehydes emission was only enhanced in WW plants exposed to 250 ppb O3 right after O3 exposure, and it decreased in WS plants exposed to 550 ppb O3 22 h after treatment (Figure 6E).

2.4. Elicitation of Emissions of Individual LOX Pathway Compounds by O3 Exposure

Among the LOX compounds released, pentanal and hexanal were the main compounds in all O3 treatments (Table 2). Hexanal emission in WW plants exposed to 550 ppb O3 was enhanced at 10 min and 1.5 h recovery times compared to values in control plants (Table 2). In WW plants exposed to 250 ppb O3, no other LOX compounds were detected through recovery time, except 1-hexanol emission in one B. nigra plant. In WW and WS plants exposed to 550 ppb O3, (Z)-3-hexen-1-ol and 1-hexanol were the main LOX pathway compounds indicating stress together with 2-ethylfuran, while (E)-3-hexen-1-ol, 1-penten-3-ol, (Z)-2-penten-1-ol, 1-penten-3-one, (E,E)-2,4-hexadienal and 2-methyl-2-cyclopenten-1-one were emitted only at some time-points during recovery (Table 2).

2.5. Impact of Glucosinolate Breakdown Products on the O3-Induced Smell Bouquet

All control and stressed plants released a similar blend of glucosinolate breakdown products 22 h after the O3 treatments (Monte Carlo permutation test, p > 0.05, data not shown) (Table 2). Specific compounds like dimethyl disulfide and methanethiol were characteristic to WW plants exposed to 250 ppb O3 and WS plants exposed to 550 ppb O3, but they were rare in WW plants exposed to 550 ppb O3 (Table 2). The rest of the volatile glucosinolates, cyclohexyl isocyanate, cyclohexyl isothiocyanate, 2-propenenitrile, tetramethylthiourea and tetramethylurea, were characteristic to the control—as well as the stressed plants of different treatments (Table 2).

2.6. O3 Exposure Effects on Other Volatiles

Among GDP pathway compounds, at 4.5 h recovery point, α-pinene emission was decreased in WW plants exposed to 250 ppb O3 and at 22 h recovery point, 3-carene emission was enhanced in WW plants exposed to 550 ppb O3 compared to the values in control plants (Table 2). Among saturated aldehydes, decanal, heptanal, nonanal and octanal emissions were enhanced in WW plants exposed to 250 ppb O3 right after exposure compared with the emissions in controls (Table 2). Heptanal emission was greater at 4.5 h recovery time in WS plants exposed to 550 ppb O3 than in the controls (Table 2).

3. Discussion

3.1. How Drought and Different O3 Levels Affect Leaf Photosynthetic Characteristics in B. nigra

The entry of gaseous pollutants into the leaf interior is controlled by the openness of stomatal pores and stomatal density that together determine the stomatal conductance and the diffusion of the given pollutant into leaf interior (Figure 1) [69,70,71]. Before O3 treatment, drought stress strongly reduced the stomatal conductance (gs, Figure 2 and Figure 4), and the ratio of intercellular CO2 concentration (Ci) to ambient CO2 concentration (Ca) (Ci/Ca) (Figure 4) in water-stressed (WS) plants compared with well-watered (WW) plants, highlighting the classical plant response to drought that allows conservation of water use [41,72,73,74]. Apart from drought effects, O3 typically triggers a rapid stomatal closure and the production of reactive oxygen species (ROS) [16,70,75,76,77]. In our study, in WW plants exposed to 550 ppb O3, stomatal closure was already observed at 10 min after O3 treatment, and the stomata remained closed through the recovery period (Figure 3B). Despite stomatal closure, due to higher initial gs and high O3 exposure dose, the highest stomatal O3 uptake rate was observed in this treatment (Figure 1, Figure 2 and Figure 3, Table 1). In contrast, there was almost no effect of O3 on gs in WS plants exposed to 550 ppb O3, except at 7.5 h of the recovery period and there was a moderate increase in WW plants exposed to 250 ppb O3 at the end of the recovery period (Figure 3B). Small to moderate impacts of O3 treatments on gs in WS plants exposed to 550 ppb and WW plants exposed to 250 ppb indicate that O3 constituted a mild stress in these treatments. These data collectively suggest that B. nigra is a relatively ozone-tolerant species as generally observed for cruciferous plants [68,78,79].
Abscisic acid (ABA) is considered to be the most important chemical regulator of stomatal functioning in plants [30], and these differences among treatments might be related to differences in ABA accumulation and stomatal sensitivity to ABA. Under drought stress, the stomatal closure is strongly dependent on ABA, and the ABA-sensitivity increases with the severity of drought stress [30,80]. O3, in turn, reduces the stomatal sensitivity to ABA [81], and this can ultimately lead to a failure to close stomata, also called stomatal sluggishness [40], in response to environmental stimuli such as reduced humidity or reduced light characteristically decreasing stomatal conductance [82]. Thus, the reduction of ABA sensitivity might explain why in WS plants gs was reduced only to a minor degree upon O3 exposure, and the stomatal response was delayed until 7.5 h after O3 exposure, indicative of stomatal sluggishness (Figure 3B and Figure 4B). Despite the reduction in stomatal sensitivity, water stress-driven stomatal closure strongly reduced the amount of O3 entering through the stomata (Table 1, Figure 2). Similar results have been reported in water-stressed and O3-treated Phaseolus vulgaris [44] and Quercus ilex [83]. As the result of limited O3 entry, water stress diminishes O3 damage in plants [36,84,85]. Yet, in the long term, water stress inevitably reduces photosynthetic production and plant biomass, and this can be exacerbated by ozone stress [83].
Our study demonstrated a classic reduction of photosynthetic rate (A) by water stress due to diminished gs and CO2 availability (Figure 3 and Figure 4) as observed in numerous studies [26,36,86], and this reduction was only moderately enhanced by O3 exposure (Figure 3A). This further emphasizes that reduced gs prior to O3 exposure protects photosynthetic machinery and results in a lower effective O3 dose as observed also in other studies [23]. Similarly to WS plants exposed to 550 ppb O3, exposure of WW plants to 250 ppb O3 caused only a minor reduction in A (Figure 3A). Although the reductions in A and gs were apparently correlated (Figure 3) as demonstrated by strong positive relationships Ci/Ca ratio and gs (Figure 4B), gs and A changed differently during recovery after O3 exposure. Indeed, the Ci/Ca ratio increased by the end of the recovery period in WW plants (Figure 4A), but due to different reasons for plants exposed to 250 ppb and 550 ppb O3. In the case of 250 ppb O3 fumigation, A remained at the control level and gs was increased, whereas in the case of 550 ppb O3 fumigation, both A and gs were reduced, but the reduction in A was greater (Figure 3). This indicates that non-stomatal factors also affected A in WW plants exposed to the higher O3 concentration. Such non-stomatal factors responsible for the decrease of A can be the reduction in ribulose 1,5-bisphosphate (RuBP) carboxylase/oxygenase activity, inactivation of photosynthetic electron transport and concomitant reduction in RuBP regeneration rate [87,88]. Analogously to our study, a reduction of A partly independent of gs has been shown in other species [89,90]. Furthermore, as a reduction in A can also cause a reduction in gs [91,92], we cannot rule out the non-stomatal reduction in A in earlier phases of recovery in WW plants exposed to 550 ppb O3.

3.2. Water Stress Effects on Non-Ozonated Plant Volatile Emissions

Plant physiological and metabolic processes critically depend on water stress duration and severity [40,93,94,95]. Mild water stress can have only limited effects on constitutive VOC emissions, but moderate water stress might enhance VOC emissions, and severe water stress can decrease the emissions [35,40,96,97]. Although water stress might alter the constitutive VOC emissions, it typically does not result in induction of stress volatile emissions [98]. In our study, water stress did not affect significantly the total average VOC emission rate and the emission rate and chemical composition of volatiles was similar among non-ozonated WW and WS B. nigra plants (Figure 5, Table 2). Given that the constitutive VOC emissions occur at a low level in B. nigra (Figure 5, Table 2) [47], the metabolic energy and photosynthetic substrate requirements for VOC synthesis are also low. Therefore, it is plausible that the reduction in photosynthate production rate in water-stressed plants did not limit the substrate availability for constitutive volatile synthesis in B. nigra.

3.3. O3 Effects on Total VOC Emissions in Well-Watered and Water-Stressed Plants

In the present study, both WW and WS plants released stress VOCs after the treatment with 550 ppb O3 (Table 2). The blend of released volatiles was similar to that in the heat-stressed B. nigra [47], yet the different treatments in our study did not affect the total emissions of VOCs (see Results). Similarly, limited effects of chronic low-level O3 treatments on VOC emissions in B. nigra have been observed in other studies [57,99]. Nevertheless, the emission of VOCs from plants is affected by the stress dose (severity) and also depends on plant species [40,47,93,94,100,101]. In another O3 treatment study, B. nigra was most ozone tolerant compared to Sinapis alba, S. arvensis and B. napus [57].

3.4. Effects of O3 and Water Stress Treatments on Emissions of Specific LOX Pathway Compounds

Presence of LOX compounds in the emission blend typically indicates severe stress; LOX emissions can be induced upon mechanical damage, heat, ozone, and herbivory stresses, and the rate of LOX compound emissions often scales with the severity of stress [20,102,103,104]. O3 exposure enhanced LOX compounds emission across all treatments, but comparison of WS and WW 550 ppb O3-treated plants, demonstrated that WW plants reacted more strongly (significant water stress effect; Figure 6A). In WS plants, less O3 entered the leaves compared to WW plants exposed to 550 ppb O3 and, as a result, the O3-dependent increase in total LOX emissions was absent, although stress indicator compounds were detected (Table 1 and Table 2, Figure 6A). There is also a probability that we might have lost some LOX compound emissions during the first hour of O3 treatment in WW plants because the earliest LOX emission burst can occur a few minutes to 30 min after the damage of plant cells [105,106,107]. On the other hand, LOX-related volatiles emerge 1–2 h [23] or in some cases even 5 h after the O3 fumigation [20]. Clearly, we have been able to detect the delayed LOX emission response in WW plants exposed to 250 and 550 ppb O3 (Figure 6A).
In our study, hexanal and pentanal were the main LOX volatiles forming the vast amount of the LOX compounds emitted upon O3 exposure (Table 2). The same LOX compound composition was observed in O3-treated N. tabacum [89]. The detection of various LOX pathway compounds in the emissions of WW or WS B. nigra plants during recovery confirms the presence of cell membrane damage [108,109]. LOX pathway volatiles like (Z)-3-hexen-1-ol, 1-hexanol, 1-penten-3-ol, 1-penten-3-one together with 2-ethylfuran (Table 2) were characteristic only to the WW and WS plants exposed to 550 ppb O3. Next to typical LOX compounds, we have observed previously that 2-ethylfuran is one of the signals of a severe stress as its emissions increased in N. tabacum and B. nigra after a threshold temperature was exceeded [47,104]. It is proposed that 2-ethylfuran is formed from (E)-2-hexenal and co-emitted with (Z)-3-hexenol [110,111], and 2-ethylfuran was observed in WW 550 ppb O3-treated plants in our study as well. This evidence collectively suggests that at a given O3 exposure, higher stomatal O3 uptake caused a more severe stress of WW B. nigra plants (Table 1 and Table 2; Figure 1 and Figure 2).

3.5. O3 Effects on Species—Specific Glucosinolate Degradation Products

Glucosinolates and/or their degradation products are characteristic compounds of the Brassicaceae that are considered as human health-promoting compounds and having an important role in plant protection [112,113]. The results of this study showed that O3 or water stress did not significantly affect emissions of glucosinolate degradation products (Figure 6B). Nevertheless, we detected multiple glucosinolate breakdown products in WW and WS plants during the recovery period, including damage-related dimethyl disulfide and even methanethiol [114,115] (Table 2). Lack of a quantitative scaling of glucosinolate breakdown product emission and O3 exposure might indicate that O3 treatments did not cause extensive cell damage that would have led to enhanced activation of the glucosinolate–myrosinase system [49,116]. This result is different from heat-stressed B. nigra, where emissions of glucosinolate breakdown products and LOX compounds occurred similarly [47]. Over the longer term, O3 treatment and water-deficit can lead to modifications in glucosinolate content [34,54,96], and this could further contribute to alterations in the release of glucosinolate breakdown products under O3 or other stresses.

3.6. O3 Effects on Other Volatile Groups

The plastidial methylerythritol phosphate (MEP) pathway is responsible for the biosynthesis of GDP-derived compounds and their emission depends on the supply of photosynthates [117,118]. Being highly reactive, monoterpenes could improve plant thermo- or O3-tolerance by reacting with stress-generated oxidative compounds [119,120]. In the present study, the emission of GDP compounds through recovery was similar within O3 treatments (Figure 6C). Such a limited time-dependent response might seem surprising given the strong changes in photosynthetic rate (Figure 3). However, this might indicate the overall low GDP compound emission rate in B. nigra such that the carbon flux going into GDP compound synthesis is small and not suppressed by the O3-driven reductions in photosynthesis. Decreased GDP emissions have been previously found in O3 treated N. tabacum [89] and B. napus [121], and relatively stable GDP emissions in O3 treated B. nigra plants [56,89,121,122,123].
Part of our results, especially high GGDP compounds emission at 10 min recovery time in WW plants exposed to 250 ppb O3, support earlier findings of increased emission of GGDP compounds upon O3 treatment [38,124,125]. It has been suggested, that in B. nigra the release of GGDP compounds is related to the oxidative cleavage of carotenoids [126,127]. Carotenoids are continuously produced and degraded in green plants [128,129], but their primary role is to protect the photosynthetic apparatus against the oxidative stress [130,131].
The release of saturated aldehydes is probably related to several pathways functioning simultaneously with the LOX pathway such as the conversion of saturated fatty acids into aldehydes or the opposite [109,132,133]. Emission of saturated aldehydes could be partly controlled by stomatal conductance [43,134], but in our study there was no evidence of the direct effect of stomata on the emissions of these volatiles through recovery in different treatments and an overall limited effect of different treatments on saturated aldehyde emissions (Figure 6E). Decanal and nonanal are commonly found in the odor of B. nigra leaves and flowers and more importantly, their emission is associated with plant O3 tolerance and O3 dose, and the degree of damage [135,136,137]. For example, B. nigra plants treated with 70 ppb or 120 ppb O3, showed diminished emissions of nonanal and decanal, while the treatment of B. napus leaves with ~140 ppb O3 increased the release of aforementioned saturated aldehydes [56,121]. The insensitivity of saturated aldehyde emissions to water stress and O3 exposure further underscores the high O3 tolerance of B. nigra.

4. Materials and Methods

4.1. Plant Material

Brassica nigra seeds of local source were purchased from the Department of Entomology, University of Wageningen, the Netherlands. Seeds were sown in 0.8 L plastic pots filled with commercial soil (Biolan Oy, Eura, Finland) and quartz sand (1:1 mixture) (AS Silikaat, Tallinn, Estonia). The soil was fertilized with a slow-release mineral fertilizer at an optimum level (Biolan Oy, Eura, Finland). Plants were grown at a light intensity of 400 µmol m−2 s−1 (HPI-T Plus 400 W metal halide lamps, Philips, Brussels, Belgium), relative humidity of 60%, day length of 12 h and day/night temperatures of 24/20 °C in a plant growth room. During the first three weeks, the plants were watered every other day and at the beginning of the fifth week. Then the plants were randomly divided between ‘well-watered plants’ (WW) and ‘water-stressed plants’ (WS; Figure 7). Watering of WW plants was continued as described above, but WS plants were watered once a week, resulting in a mild water stress as plant water potential was −0.5 to −0.8 MPa (measured with a PMS 600 pressure chamber, PMS Instrument Company, Albany, OR, USA). The experiment was conducted with mature fully-expanded leaves (ca. 3 week old leaves).

4.2. Experimental Set-Up and Gas Exchange Measurements

A custom-made gas-exchange system was used for foliage photosynthesis and transpiration measurements and volatile sampling. The system has a 1.2 L temperature-controlled double-walled glass chamber that is connected to an infra-red dual-channel gas analyzer (CIRAS II, PP-Systems, Amesbury, MA, USA) for measuring CO2 and H2O concentrations at the chamber in- and outlets [138]. Chamber temperature is regulated by a controlled-temperature water bath that circulates water between the double glass walls of the gas-exchange chamber [138]. All gas-exchange measurements were conducted at standard conditions of light intensity of 800 µmol m−2 s−1 at leaf surface, air temperature inside the chamber of 25 °C (leaf temperature was ± 1 °C of chamber temperature) and relative humidity 60%. The temperature inside the gas-exchange chamber was monitored by a thermistor (NTC thermistor, model ACC-001, RTI Electronics, Inc., St. Anaheim, CA, USA). The air was taken from outside, passed through a 10 L buffer volume, an HCl-activated copper tubing for scrubbing O3 and further through a humidifier. Inside the chamber, the CO2 concentration was 380–400 µmol mol−1 and the air flow rate was set to 1.6 L min−1. Turbulent conditions inside the chamber were achieved by a fan installed in the chamber. Three fully-expanded mature upper canopy leaves were inserted in the chamber, and 20–30 min after plant enclosure, when leaf gas-exchange rates had stabilized, net assimilation rate (A) and stomatal conductance to water vapor (gs) were recorded (Figure 7). Simultaneously with the gas-exchange measurements, volatiles were collected as described below. Values of A and gs were calculated according to [139].

4.3. Ozone Stress Application

O3 concentration in chamber in- and outlets was monitored by a UV photometric O3 detector (Model 49i, Thermo Fisher Scientific, Waltham, MA, USA). In the ambient air entering the chamber, O3 concentration was less than 2 ppb. O3 was generated with a Stable Ozone Generator SOG-2 (LLC-Upland, CA, USA) and mixed with the air entering the chamber to the desired concentration. Plants were exposed to O3 for 1 h as follows: 250 ± 10 ppb for 6 WW plants and 550 ± 25 ppb for 5 WW plants and 4 WS plants (Figure 7). Exposure with 250 ppb O3 was not tested for WS treatment as preliminary experiments showed no effect on volatile emissions due to too low O3 uptake. A and gs were recorded 10 min, 1.5 h, 4.5 h, 7.5 h and 22 h after O3 exposure, and volatiles were collected 10 min, 1.5 h, 4.5 h and 22 h after O3 treatment. O3 uptake rate by stomata (nmol m−2 s−1), leaf surface (nmol m−2 s−1) and the total amount of O3 uptake (ΦO3, µmol m−2) by the leaves were calculated at the beginning (~5 min), in the middle (0.5 h) and at the end (1 h) of O3 application by using the O3 binary diffusion coefficient and equations from [23]. “Surface” ozone uptake also includes quenching of ozone by reactive hydrocarbons emitted by leaves [89,140].

4.4. Volatile Sampling and GC-MS Analysis

Multi-bed stainless steel cartridges filled with three different carbon-based adsorbents were used for collecting the volatiles (VOCs) [141]. A portable 210-1003MTX air sampling pump (SKC Inc., Houston, TX, USA) was connected to the chamber outlet with a T-piece and the air enriched with plant VOCs was drawn from the chamber through the cartridge with a constant flow rate of 200 mL min−1 for 20 min. Each day before the plant measurements, VOCs in the empty chamber were collected and subtracted from measurements with plants.
The cartridges were analyzed with a combined Shimadzu TD20 automated cartridge desorber connected to a Shimadzu 2010 Plus gas chromatograph-mass spectrometer (GC–MS) (Shimadzu Corporation, Kyoto, Japan). Adsorbent cartridges were heated to 250 °C and back-flushed with high purity He (99.9999% AGA, The Linde Group, Tallinn, Estonia) at a flow rate of 40 mL min−1 for 6 min. During this period, desorbed VOCs were collected onto a cold trap filled with Tenax TA at −20 °C. In the second stage, the trap was heated to 280 °C and during 6 min, VOCs were carried with He into a Zebron ZB-624 fused silica capillary column (0.32 mm i.d., 60 m, 1.8 μm film thickness, Phenomenex, Torrance, CA, USA). In GC, the flow rate of the carrier gas (He) was 2.9 mL min−1 and VOCs were separated according to the following program: oven temperature kept at 40 °C for 1 min, then increasing the temperature by 9 °C min−1 to 120 °C, held for 5 min, then increasing the temperature by 2 °C min−1 to 190 °C, held for 2 min, and finally increasing the temperature by 5 °C min−1 to 250 °C, held for 5 min. The Shimadzu QP2010 Plus mass spectrometer (MS) was operated in the electron impact mode. The transfer line temperature was 255 °C and ion-source temperature 170 °C. The GC-MS system was calibrated as explained in [47] and in [141]. VOCs (Table 1) were identified by comparing their mass spectra to the spectra of authentic standards and to those in the NIST library (NIST05). Volatile emissions rates per leaf area were calculated according to [142].
Volatiles were divided among five groups according to their biosynthesis pathways (Table 2). Group 1: lipoxygenase pathway (LOX) volatiles such as (Z)-3-hexen-1-ol, 1-hexanol, hexanal, 1-penten-3-ol, pentanal etc. together with 2-ethylfuran and 2-methyl-2-cyclopenten-1-one; Group 2: glucosinolate degradation products such as 2-propenenitrile, cyclohexyl isocyanate, cyclohexyl isothiocyanate, dimethyl disulfide, methanethiol, methyl isothiocyanate, tetramethylthiourea and tetramethylurea; Group 3: geranyl diphosphate (GDP) pathway volatiles (monoterpenes) α- and β-pinene, 3-carene, limonene, and camphene; Group 4: geranylgeranyl pathway (GGDP) volatiles (carotenoid degradation products) 6-methyl-5-hepten-2-one and geranyl acetone; Group 5: long-chained saturated aldehydes (≥C7) heptanal, octanal, nonanal and decanal.

4.5. Statistical Analyses

For statistical analyses, net assimilation rate (A) and stomatal conductance (gs) were log-transformed. The controls for WW and WS plants (values prior to O3 exposure) were compared with the values of treated plants at different time-points by paired sample t-tests. The differences of A and gs between the control and treated plants were calculated as Vc-Vt(t), where Vc is the average trait value of control and Vt is the average trait value of O3-treated plants at time t after O3 treatment. Paired sample t-tests were used to compare the paired values of photosynthetic characteristics, ozone uptake characteristics and log-transformed total VOC emission rates and average emission rates at different time-points during recovery within the given treatment.
The effects of O3, recovery time, their interaction and the effect of water stress (for WW and WS plants exposed to 550 ppb O3) on A, gs, total VOC emission, VOC groups and O3 uptake rates by stomata, leaf surface and total O3 uptake were evaluated by repeated measures ANOVA. Linear regression analyses were used to explore the relationships of stomatal O3 uptake with gs, and the relationship of the Ci/Ca ratio with gs during recovery. All these statistical analyses were conducted with STATISTICA 7 (StatSoft Inc., Tulsa, OK, USA). All statistical effects were considered significant at p < 0.05.
Differences in volatile emissions for different combinations of O3 exposure and water stress were evaluated by principal component analyses (PCA) [143] using CANOCO 5.0 software (ter Braak and Smilauer, Biometris—Plant Research International, the Netherlands). In total, 71% of data variance was explained by the first and the second principal components (PCA 1 46%, PCA 2 25%) (data not shown). Before the analyses, the data were mean-centered and log-transformed. Redundancy data analysis (RDA) with the Monte-Carlo permutation test was used to test for statistical differences in emission blends across the treatments and no statistical differences were observed (p > 0.05, data not shown).

5. Conclusions and Outlook

This study demonstrated classic reductions in stomatal conductance (gs) and net assimilation rate (A) in water-stressed B. nigra, but the impact of water stress on constitutive volatile emissions was minor, nor did water stress elicit emissions of stress volatiles. In well-watered plants, acute O3 stress (550 ppb exposure for 1 h) led to major reductions in gs and A with limited recovery by the end of the experiment at 22 h. In these plants, acute O3 stress also led to induction of emissions of lipoxygenase pathway (LOX) volatiles between 10 min and 1.5 h after exposure. Due to lower gs, O3 uptake was reduced under water stress, and as a result, soil water limitation strongly ameliorated the impact of acute O3 stress, as evidenced in much lower reductions in gs and A and lack of induction of LOX volatiles. Ozone uptake was similar in well-watered plants exposed to a lower O3 concentration of 250 ppb and in water-stressed plants, and the responses of foliage physiological characteristics to O3 exposure were also similar, except that gs and A were maintained at a higher level in well-watered plants. This suggests that water stress did not result in the priming of plants to subsequent O3 stress. Nevertheless, O3 exposure resulted in surprisingly minor modifications in volatile profiles in the annual plant B. nigra compared with observations for perennial species. This might be indicative of high ozone tolerance of B. nigra, but also reflect the general strategy of annual species that have a rapid leaf turnover and, instead of responding stronger after the stress and repairing the damages, might sacrifice the heavily damaged leaves to form new leaves [144]. In the current study, we looked at O3 responses right after exposure and through 22 h recovery, but O3 exposure can have longer-term effects, including initiation of acclimation responses that improve plant tolerance to sustained mild chronic O3 stress [145,146]. We suggest that future studies should look at stress memory and priming effects including alterations in the physiological characteristics of O3-stressed leaves and new leaves formed after O3 stress.

Author Contributions

K.K., A.K., E.T. and Ü.N. designed the research; K.K performed the experiment and analyzed the data; K.K. and A.K. interpreted the data and wrote the first draft of the article; E.K. interpreted the data; K.K., E.K., A.K. and Ü.N. wrote, reviewed, edited, and approved the final version of the article. All authors have read and agreed to the published version of the manuscript.

Funding

We acknowledge funding from the European Commission through European Research Council (advanced grant 322603, SIP-VOL+) and the European Regional Development Fund (Centre of Excellence EcolChange), and from the Estonian Research Council (team grant PRG537) and the Estonian University of Life Sciences (grant P180273PKTT).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Data available in a publicly accessible repository after the manuscript is published.

Acknowledgments

We would like to thank Peter C. Harley for his knowledge during the experiment.

Conflicts of Interest

The authors declare no conflict of interest.

Sample Availability

Samples of the compounds are not available from the authors.

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Molecules 26 03114 g001 550
Figure 1. Total O3 uptake (ΦO3, mean ± SE) in well-watered (WW) plants and water-stressed (WS) Brassica nigra plants during the O3 treatments of 250 or 550 ppb measured at the beginning (~5 min), in the middle (0.5 h) and at the end (1 h) of the fumigation. Grey bars correspond to WW plants treated with 250 ppb, white bars correspond to WW plants treated with 550 ppb and black bars correspond to WS plants treated with 550 ppb. Data between different time-points within treatments were compared by paired sample t-tests and significant differences (p < 0.05) are shown by lowercase letters. The effects of exposed O3, recovery time and their interaction and the effect of water stress (WS vs. WW) in plants treated with 550 ppb were evaluated by repeated measures ANOVA.
Figure 1. Total O3 uptake (ΦO3, mean ± SE) in well-watered (WW) plants and water-stressed (WS) Brassica nigra plants during the O3 treatments of 250 or 550 ppb measured at the beginning (~5 min), in the middle (0.5 h) and at the end (1 h) of the fumigation. Grey bars correspond to WW plants treated with 250 ppb, white bars correspond to WW plants treated with 550 ppb and black bars correspond to WS plants treated with 550 ppb. Data between different time-points within treatments were compared by paired sample t-tests and significant differences (p < 0.05) are shown by lowercase letters. The effects of exposed O3, recovery time and their interaction and the effect of water stress (WS vs. WW) in plants treated with 550 ppb were evaluated by repeated measures ANOVA.
Molecules 26 03114 g001
Molecules 26 03114 g002 550
Figure 2. Relationships between stomatal conductance to water vapor and stomatal O3 uptake rate in well-watered (WW) B. nigra plants treated with 250 or 550 ppb O3 and water-stressed (WS) plants treated with 550 ppb O3 measured at the beginning (~5 min), in the middle (0.5 h) and at the end (1 h) of the O3 exposure. Linear regressions were statistically significant at p < 0.001 (***).
Figure 2. Relationships between stomatal conductance to water vapor and stomatal O3 uptake rate in well-watered (WW) B. nigra plants treated with 250 or 550 ppb O3 and water-stressed (WS) plants treated with 550 ppb O3 measured at the beginning (~5 min), in the middle (0.5 h) and at the end (1 h) of the O3 exposure. Linear regressions were statistically significant at p < 0.001 (***).
Molecules 26 03114 g002
Molecules 26 03114 g003 550
Figure 3. Absolute O3-dependent differences (mean ± SE) in net assimilation rate (A) and stomatal conductance to water vapor (B) in O3-treated well-watered and water-stressed B. nigra plants. The differences are given as the average values of A and gs in control plants minus the average values at different time-points during recovery. The values between control and different time-points were compared by paired sample t-tests and significant differences (p < 0.05) are indicated by lowercase letters. The effects of O3 exposure, recovery time, their interaction and the effect of water stress (WS vs. WW) for plants treated with 550 ppb were evaluated by repeated measures ANOVA. ns denotes non-significant effects (p > 0.05).
Figure 3. Absolute O3-dependent differences (mean ± SE) in net assimilation rate (A) and stomatal conductance to water vapor (B) in O3-treated well-watered and water-stressed B. nigra plants. The differences are given as the average values of A and gs in control plants minus the average values at different time-points during recovery. The values between control and different time-points were compared by paired sample t-tests and significant differences (p < 0.05) are indicated by lowercase letters. The effects of O3 exposure, recovery time, their interaction and the effect of water stress (WS vs. WW) for plants treated with 550 ppb were evaluated by repeated measures ANOVA. ns denotes non-significant effects (p > 0.05).
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Molecules 26 03114 g004 550
Figure 4. The ratio of mean ± SE intercellular CO2 (Ci) to ambient CO2 concentration (Ci/Ca; Ca = 380–400 µmol mol−1 during the measurements) after O3 fumigation (A) and correlations among Ci/Ca with stomatal conductance to water vapor (gs) through recovery (10 min, 1.5 h, 4.5 h, 7.5 h and 22 h after O3 exposure; (B) in B. nigra. In A, the data are labelled as: grey continuous line with grey circles—well-watered (WW) plants treated with 250 ppb O3; black continuous line with white squares—WW and 550 ppb O3; black continuous line with black circles—water-stressed (WS) and 550 ppb O3. In B, each data point indicates an individual measurement and the symbols are as: grey circles—WW/250 ppb O3; white squares—WW/550 ppb O3; black circles—WS/550 ppb O3. In A, the means at different recovery time-points within treatments were compared by paired sample t-tests, significant differences (p < 0.05) are indicated by lowercase letters. In B, the data were fitted by linear regressions, and the regression lines are shown for the significant relationships (p < 0.01 for WW/250 ppb O3 (grey line), and WS/550 ppb O3 (black line).
Figure 4. The ratio of mean ± SE intercellular CO2 (Ci) to ambient CO2 concentration (Ci/Ca; Ca = 380–400 µmol mol−1 during the measurements) after O3 fumigation (A) and correlations among Ci/Ca with stomatal conductance to water vapor (gs) through recovery (10 min, 1.5 h, 4.5 h, 7.5 h and 22 h after O3 exposure; (B) in B. nigra. In A, the data are labelled as: grey continuous line with grey circles—well-watered (WW) plants treated with 250 ppb O3; black continuous line with white squares—WW and 550 ppb O3; black continuous line with black circles—water-stressed (WS) and 550 ppb O3. In B, each data point indicates an individual measurement and the symbols are as: grey circles—WW/250 ppb O3; white squares—WW/550 ppb O3; black circles—WS/550 ppb O3. In A, the means at different recovery time-points within treatments were compared by paired sample t-tests, significant differences (p < 0.05) are indicated by lowercase letters. In B, the data were fitted by linear regressions, and the regression lines are shown for the significant relationships (p < 0.01 for WW/250 ppb O3 (grey line), and WS/550 ppb O3 (black line).
Molecules 26 03114 g004
Molecules 26 03114 g005 550
Figure 5. Total volatile emission rates (mean ± SE) in well-watered (WW) and water-stressed (WS) O3-fumigated B. nigra plants before exposure (control) and through the recovery phase (grey bars—WW/250 ppb O3; white bars—WW/550 ppb O3; black bars—WS/550 ppb O3). The values between different time-points among treatments were compared by paired sample t-tests and significant differences (p < 0.05) are indicated by lowercase letters. The effect of O3 exposure, recovery time, their interaction and the effect of water stress (WS vs. WW) for plants treated with 550 ppb O3 were evaluated by repeated measures ANOVA. ns denotes non-significant effects (p > 0.05).
Figure 5. Total volatile emission rates (mean ± SE) in well-watered (WW) and water-stressed (WS) O3-fumigated B. nigra plants before exposure (control) and through the recovery phase (grey bars—WW/250 ppb O3; white bars—WW/550 ppb O3; black bars—WS/550 ppb O3). The values between different time-points among treatments were compared by paired sample t-tests and significant differences (p < 0.05) are indicated by lowercase letters. The effect of O3 exposure, recovery time, their interaction and the effect of water stress (WS vs. WW) for plants treated with 550 ppb O3 were evaluated by repeated measures ANOVA. ns denotes non-significant effects (p > 0.05).
Molecules 26 03114 g005
Molecules 26 03114 g006 550
Figure 6. Emission rates (mean ± SE) of volatile lipoxygenase (LOX) pathway compounds (A) glucosinolate degradation products; (B), geranyl diphosphate (GDP) pathway compounds (monoterpenes; (C), geranylgeranyl diphosphate (GGDP) pathway compounds; (D), long-chained saturated aldehydes; (E) in O3-treated well-watered (WW) and water-stressed (WS) B. nigra plants before fumigation (control) and through recovery (grey bars—WW/250 ppb O3; white bars—WW/550 ppb O3; black bars—WS/550 ppb O3). Emission rates within treatments at different time-points during recovery were compared by paired sample t-tests, and significant differences are indicated by lowercase letters (p < 0.05). The effect of O3 exposure, recovery time and their interaction and the effect of water stress (WS vs. WW) for plants exposed to 550 ppb O3 were evaluated by repeated measures ANOVA. ns denotes non-significant effects (p > 0.05). The list of compounds belonging to different volatile groups is shown in Table 2.
Figure 6. Emission rates (mean ± SE) of volatile lipoxygenase (LOX) pathway compounds (A) glucosinolate degradation products; (B), geranyl diphosphate (GDP) pathway compounds (monoterpenes; (C), geranylgeranyl diphosphate (GGDP) pathway compounds; (D), long-chained saturated aldehydes; (E) in O3-treated well-watered (WW) and water-stressed (WS) B. nigra plants before fumigation (control) and through recovery (grey bars—WW/250 ppb O3; white bars—WW/550 ppb O3; black bars—WS/550 ppb O3). Emission rates within treatments at different time-points during recovery were compared by paired sample t-tests, and significant differences are indicated by lowercase letters (p < 0.05). The effect of O3 exposure, recovery time and their interaction and the effect of water stress (WS vs. WW) for plants exposed to 550 ppb O3 were evaluated by repeated measures ANOVA. ns denotes non-significant effects (p > 0.05). The list of compounds belonging to different volatile groups is shown in Table 2.
Molecules 26 03114 g006
Molecules 26 03114 g007 550
Figure 7. Scheme of studying ozone stress of well-watered and water-stressed plants of Brassica nigra. After measurements of photosynthetic characteristics and emissions of volatile organic compounds (VOCs) of control plants, well-watered B. nigra plants were treated with O3 concentrations of 250 ppb and 550 ppb, while water-stressed plants were only exposed to 550 ppb. The exposure period was 1 h and O3 uptake by stomata and leaf surface was recorded during the exposure. Photosynthetic characteristics were measured 10 min, 1.5 h, 4.5 h, 7.5 h and 22 h after O3 stress. In the case of VOCs, measurements at 7.5 h were not conducted.
Figure 7. Scheme of studying ozone stress of well-watered and water-stressed plants of Brassica nigra. After measurements of photosynthetic characteristics and emissions of volatile organic compounds (VOCs) of control plants, well-watered B. nigra plants were treated with O3 concentrations of 250 ppb and 550 ppb, while water-stressed plants were only exposed to 550 ppb. The exposure period was 1 h and O3 uptake by stomata and leaf surface was recorded during the exposure. Photosynthetic characteristics were measured 10 min, 1.5 h, 4.5 h, 7.5 h and 22 h after O3 stress. In the case of VOCs, measurements at 7.5 h were not conducted.
Molecules 26 03114 g007
Table
Table 1. Average surface and stomatal O3 uptake rates and relative uptake rates at the beginning (~5 min), in the middle (0.5 h) and at the end (1 h) of fumigation with 250 ppb or 550 ppb O3 for well-watered (WW) and water-stressed (WS) Brassica nigra plants.
Table 1. Average surface and stomatal O3 uptake rates and relative uptake rates at the beginning (~5 min), in the middle (0.5 h) and at the end (1 h) of fumigation with 250 ppb or 550 ppb O3 for well-watered (WW) and water-stressed (WS) Brassica nigra plants.
Uptake RateWW/250 ppb O3WW/550 ppb O3WS/550 ppb O3p Value
TimeTimeTime
~5 min0.5 h1 h~5 min0.5 h1 h~5 min0.5 h1 hO3TimeO3 x Time
Surface O3 uptake rate (nmol m−2 s−1)15.6 ± 2.4 a12.1 ± 2.0 b11.5 ± 2.2 b43.1 ± 4.0 a35.8 ± 4.1 a44 ± 8 a26 ± 9 a25 ± 9 a25 ± 9 a<0.01<0.05ns
Stomatal O3 uptake rate (nmol m−2 s−1)13.1 ± 2.8 a16.1 ± 3.1 b16.8 ± 3.5 b54 ± 11 a60 ± 12 a44 ± 5 a12 ± 2 a13.3 ± 1.7 a12.4 ± 1.4 a0.001ns<0.05
Surface O3 uptake rate/Whole leaf uptake rate (%)56 ± 8 a45 ± 8 b43 ± 10 b50.5 ± 2.8 a43 ± 6 a50 ± 7 a66 ± 5 a61 ± 7 a63 ± 8 ans0.01ns
Stomatal O3 uptake rate/Whole leaf uptake rate (%)44 ± 8 a55 ± 8 b57 ± 10 b49.5 ± 2.8 a57 ± 6 a50 ± 7 a34 ± 5 a39 ± 7 a37 ± 8 ans<0.05<0.05
Differences between ~5 min and other time-points were separated by paired samples t-tests, and differences significant at p < 0.05 are shown by lowercase letters. The effect of O3 exposure, recovery time and their interaction were evaluated by repeated measures ANOVA. ns denotes non-significant effects (p > 0.05).
Table
Table 2. Average (±SE) emission rates of individual volatile organic compounds detected in the emissions of well-watered (WW) and water-stressed control and O3-treated (250 ppb or 550 ppb O3 for 1 h) Brassica nigra plants.
Table 2. Average (±SE) emission rates of individual volatile organic compounds detected in the emissions of well-watered (WW) and water-stressed control and O3-treated (250 ppb or 550 ppb O3 for 1 h) Brassica nigra plants.
WW/250 ppb O3WW/550 ppb O3WS/550 ppb O3
CompoundControl10 min1.5 h4.5 h22 hControl10 min1.5 h4.5 h22 hControl10 min1.5 h4.5 h22 h
LOX pathway
12-Ethylfuran 0.015 ± 0.013 0.018 * 0.008 ± 0.007 a 0.02 ± 0.01 a
2(E, E)-2,4-Hexadienal 0.024
3Hexanal0.0090 ± 0.0028 a0.018 ± 0.005 a 0.0070 ± 0.0018 a0.0098 ± 0.0030 a0.015 ± 0.005 a0.0030 ± 0.0012 a0.010 ± 0.004 b0.018 ± 0.007 c0.0064 ± 0.0020 a0.0128 ± 0.0007 a0.011 ± 0.008 a0.0028 ± 0.0005 a0.0017 ± 0.0004 a0.0086 ± 0.0034 a0.00070 ± 0.00050 a
41-Hexanol 0.0014 0.0180.0022 ± 0.0003 0.0015 0.0036 ± 0.0030
5(E)-3-hexen-1-ol 0.180
6(Z)-3-hexen-1-ol 0.0100.03 ± 0.010.002 0.0197 0.027 ± 0.025
72-Methyl-2-cyclopenten-1-one 0.012
8Pentanal0.0068 ± 0.0014 a0.010 ± 0.002 a0.0039 ± 0.0013 a0.0070 ± 0.0024 a0.0103 ± 0.0017 a0.0062 ± 0.0015 a0.0063 ± 0.0013 a0.0042± 0.002 a0.0026 ± 0.0010 a0.0070 ± 0.0026 a0.0048 ± 0.0026 a0.0023 ± 0.0005 a0.0026 ± 0.0007 a0.0018 ± 0.0010 a0.00119 ± 0.00003 a
91-Penten-3-ol 0.034 0.022
10(Z)-2-Penten-1-ol 0.053
111-Penten-3-one 0.016
Glucosinolate degradation products
12Cyclohexyl isocyanate0.0087 ± 0.0029 a0.0530.00080.070 ± 0.066 a0.0176 ± 0.0032 a0.0073 ± 0.0040 a0.030 ± 0.020 a0.034 ± 0.030 a0.0083 ± 0.0050 a0.0097 ± 0.0010 a0.012 ± 0.007 a0.0015 ± 0.0004 a0.0011 ± 0.0003 a0.0050 ± 0.0027 a0.16
13Cyclohexyl isothiocyanate0.0017 ± 0.0011 a0.005 ± 0.004 a0.000050.006 ± 0.005 a0.00121± 0.00040 a0.0030.0062 ± 0.0040 a0.0031± 0.0029 a0.0090.00305 ± 0.00006 a0.0017 ± 0.0006 a0.00111 ± 0.00020 a0.0019 ± 0.0005 a0.0015 ± 0.0005 a0.09
14Dimethyl disulfide 0.0040.0031 ± 0.0010 a0.0017 ± 0.0012 a0.0007 0.0030.011 0.00040.00023 ± 0.00007 a
15Methanethiol0.0056 ± 0.0034 a0.0030.016 ± 0.013 a0.0080 0.0130.00110.0003 0.003
162-Propenenitrile0.09 ± 0.08 a0.036 ± 0.018 a 0.18 ± 0.16 a0.043 ± 0.020 a0.040.24 ± 0.17 a0.18 ± 0.15 a0.084 ± 0.040 a0.09 ± 0.05 a0.053 ± 0.020 a0.08 ± 0.06 a0.22 ± 0.21 a0.14 ± 0.09 a0.22 ± 0.21 a
17Methyl isothiocyanate 0.0039 0.006
18Tetramethylthiourea0.00070.008 ± 0.0070.00050.0041 0.031 ± 0.030 a 0.0110.0036 ± 0.0030 a 0.0019 ± 0.0007 a 0.0014 ± 0.0009 a0.009
19Tetramethylurea0.0020 ± 0.0016 a0.042 ± 0.035 a0.0035 ± 0.0020 a0.0046 ± 0.0040 a 0.0040.0057 ± 0.0050 a0.002 ± 0.001 a0.0270.014 ± 0.007 a0.0032 ± 0.0020 a0.002 ± 0.001 a0.0031 ± 0.0004 a0.0040 ± 0.0022 a0.025
GDP pathway
20Camphene0.0017 ± 0.0008 a0.0006± 0.0002 a0.0007 ± 0.0002 a0.0005 ± 0.0001 a0.0015 ± 0.0008 a0.0013 ± 0.0006 a0.0017 ± 0.0009 a0.00067 ± 0.00018 a0.014 ± 0.013 a0.00141± 0.00015 a0.00044 ± 0.00009 a0.00041 ± 0.00013 a0.00020 ± 0.00002 a0.00032 ± 0.00015 a0.00057 ± 0.00031 a
213-Carene0.013 ± 0.006 a0.014 ± 0.003 a0.012 ± 0.002 a0.009 ± 0.003 a0.019 ± 0.003 a0.005 ± 0.003 a0.014 ± 0.006 a0.014 ± 0.006 a0.0147 ± 0.0027 a0.025 ± 0.00 9 b0.004 ± 0.002 a0.0017 ± 0.0009 a0.0025 ± 0.0010 a0.0062 ± 0.0027 a0.0049 ± 0.0032 a
22Limonene0.013 ± 0.008 a0.005 ± 0.001 a0.005 ± 0.001 a0.0019 ± 0.0006 a0.0040 ± 0.0005 a0.003 0.003 ± 0.002 a0.004 ± 0.002 a0.0021 ± 0.0004 a0.004 ± 0.002 a0.0023 ± 0.0016 a0.0006 ± 0.0001 a0.0005 ± 0.0002 a0.002 ± 0.001 a0.0013
23α-Pinene0.025 ± 0.006 a0.019 ± 0.004 a0.017 ± 0.003 a0.015 ± 0.003 b0.022 ± 0.004 a0.0080 ± 0.0001 a0.014 ± 0.006 a0.012 ± 0.007 a0.016 ± 0.005 a0.04 ± 0.01 a0.009 ± 0.004 a0.005 ± 0.001 a0.005 ± 0.003 a0.012 ± 0.002 a0.012 ± 0.007 a
24β-Pinene0.0012 ± 0.0002 a0.0012± 0.0004 a0.0007 ± 0.0003 a0.0005 ± 0.0002 a0.0008 ± 0.0001 a0.00040.00050.0020.00076 ± 0.00003 a0.0021 ± 0.0007 a0.0021 ± 0.0013 a0.00028 ± 0.00002 a0.00049 ± 0.00001 a0.0006 ± 0.0001 a0.0006 ± 0.0003 a
GGDP pathway
25Geranyl acetone0.0108 ± 0.0039 a0.036 ± 0.018 a0.0090 ± 0.0034 a0.013 ± 0.005 a0.015 ± 0.006 a0.030 ± 0.006 a0.042 ± 0.027 a0.049 ± 0.020 a0.058 ± 0.050 a0.049 ± 0.008 a0.010 ± 0.007 a0.0071 ± 0.0048 a0.0029 ± 0.0016 a0.013 ± 0.003 a0.0063 ± 0.0056 a
266-Methyl-5-hepten-2-one0.0034 ± 0.0015 a0.062 ± 0.047 a0.010 ± 0.005 a0.0077 ± 0.0031 a0.014 ± 0.008 a0.0031 ± 0.0015 a0.013 ± 0.010 a0.055 ± 0.027 a0.0077 ± 0.0050 a0.0057 ± 0.0014 a0.0087 ± 0.0081 a0.0042 ± 0.0033 a0.0037 ± 0.0022 a0.020 ± 0.008 a0.00033 ± 0.00011 a
Saturated aldehydes
27Decanal0.0132 ± 0.0030 a0.077 ± 0.030 b0.026 ± 0.007 a0.018 ± 0.006 a0.030 ± 0.006 a0.060 ± 0.044 a0.030 ± 0.016 a0.071 ± 0.012 a0.029 ± 0.016 a0.046 ± 0.017 a0.035 ± 0.016 a0.0190 ± 0.0070 a0.013 ± 0.002 a0.050 ± 0.027 a0.0029 ± 0.0008 a
28Heptanal0.0072 ± 0.0011 a0.010 ± 0.003 b0.0042 ± 0.0010 a0.0053 ± 0.0011 a0.0071 ± 0.0020 a0.0055 ± 0.0020 a0.0040 ± 0.0003 a0.014 ± 0.005 a0.0072 ± 0.0020 a0.0078 ± 0.0002 a0.004 ± 0.001 a0.003 ± 0.001 a0.0019 ± 0.0003 a0.0083 ± 0.0006 b0.0014 ± 0.0001 a
29Nonanal0.0182 ± 0.0043 a0.063 ± 0.020 b0.025 ± 0.007 a0.014 ± 0.005 a0.022 ± 0.007 a0.035 ± 0.020 a0.026 ± 0.008 a0.074 ± 0.020 a0.026 ± 0.009 a0.033 ± 0.018 a0.019 ± 0.007 a0.011 ± 0.004 a0.010 ± 0.002 a0.050 ± 0.017 a0.0026 ± 0.0003 a
30Octanal0.0086 ± 0.0010 a0.022 ± 0.007 b0.011 ± 0.003 a0.006 ± 0.002 a0.012 ± 0.002 a0.013 ± 0.006 a0.0076 ± 0.0020 a0.033 ± 0.012 a0.0068 ± 0.0022 a0.0090 ± 0.0020 a0.012 ± 0.006 a0.004 ± 0.001 a0.0040 ± 0.0012 a0.021 ± 0.005 a0.0013 ± 0.0003 a
The compounds were divided among key volatile groups: volatiles of the lipoxygenase (LOX) pathway, glucosinolate breakdown products, geranyl diphosphate (GDP) pathway volatiles, geranylgeranyl diphosphate (GGDP) pathway volatiles and saturated aldehydes. * Data without SE values correspond to measurements where the given compound was observed only in one plant among all the replicates. Emission rates between control and stressed plants at different time-points within the treatments were compared by paired sample t-tests and significant differences (p < 0.05) are indicated by lowercase letters.
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Kask, K.; Kaurilind, E.; Talts, E.; Kännaste, A.; Niinemets, Ü. Combined Acute Ozone and Water Stress Alters the Quantitative Relationships between O3 Uptake, Photosynthetic Characteristics and Volatile Emissions in Brassica nigra. Molecules 2021, 26, 3114. https://doi.org/10.3390/molecules26113114

AMA Style

Kask K, Kaurilind E, Talts E, Kännaste A, Niinemets Ü. Combined Acute Ozone and Water Stress Alters the Quantitative Relationships between O3 Uptake, Photosynthetic Characteristics and Volatile Emissions in Brassica nigra. Molecules. 2021; 26(11):3114. https://doi.org/10.3390/molecules26113114

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Kask, Kaia, Eve Kaurilind, Eero Talts, Astrid Kännaste, and Ülo Niinemets. 2021. "Combined Acute Ozone and Water Stress Alters the Quantitative Relationships between O3 Uptake, Photosynthetic Characteristics and Volatile Emissions in Brassica nigra" Molecules 26, no. 11: 3114. https://doi.org/10.3390/molecules26113114

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