INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

On exposure to increased levels of UV-B radiation, many plant species exhibit reductions in their net photosynthetic rate and productivity (Teramura and Ziska, 1996). High UV-B irradiance has been shown to inhibit photosynthesis in pea (Nogués and Baker, 1995), oilseed rape (Allen et al., 1997), soybean (Middleton and Teramura, 1993), rice (Ziska and Teramura, 1992), and algae (Lesser, 1996). Such inhibition of photosynthetic competence primarily involves the loss of both Rubisco activity and content (Allen et al., 1997), but is also associated with the loss of activity of sedoheptulose 1,7-biphosphatase (Allen et al., 1998), and probably that of other Calvin cycle enzymes, and is sometimes associated with damage to PSII photochemistry (Nogués and Baker, 1995; Baker et al., 1997; Allen et al., 1998).

It is not clear whether changes in stomatal function play a major role in the UV-B-induced inhibition of CO₂ assimilation. An increase in stomatal limitation observed in oilseed rape (Allen et al., 1997) and soybean (Middleton and Teramura, 1993), together with a reduction in the intercellular CO₂ concentration (c_i) in pea (Day and Vogelmann, 1995), suggests that there may be a direct UV-B effect on stomatal function. However, it is widely reported that any UV-B effects on stomata do not affect CO₂ assimilation (Murali and Teramura, 1986; Sullivan and Teramura, 1989; Teramura et al., 1991; Ziska and Teramura, 1992). Recent studies on pea leaves developed under high UV-B irradiance showed that there were no changes in any photosynthetic parameter measured: light-saturated net CO₂ assimilation rate (A_sat), maximum carboxylation velocity of Rubisco (V_cmax), maximum potential rate of electron transport contributing to RuBP regeneration (J_max), ratio of variable to maximal chlorophyll fluorescence yield (F_v/F_m), and the relative quantum efficiency of PSII photochemistry (_PSII) although there were reductions of adaxial stomatal conductance (g_s), but not abaxial g_s (Nogués et al., 1998). The effects on adaxial g_s were mediated by changes in aperture, as there was no reduction in stomatal density in these pea leaves (Nogués et al., 1998). This demonstrated direct effects of high UV-B on g_s in the long term (days). In contrast, small (30%) increases in the natural dose had no measurable effects on the g_s of pea plants grown in the field (Allen et al., 1999).

The objective of this study was to further characterize the effect of UV-B radiation on g_s. We studied the effect of growth under three different ratios of UV-B to PAR or with no UV-B radiation on adaxial and abaxial g_s in leaves of pea (Pisum sativum). Only at the higher UV-B irradiances (>3× maximum midsummer UK values) was g_s reduced, and the adaxial surface was more affected. This effect of high UV-B was confirmed in two other species, commelina (Commelina communis) and oilseed rape (Brassica napus). Clearly, abaxial stomata are exposed to a lower UV-B irradiance than those on the adaxial surface, and therefore the possibility that the abaxial stomata were similarly sensitive was investigated by inverting leaves in pea plants. The effect of sudden exposure on plants grown without UV-B on g_s was also examined over several days, together with recovery of g_s in those grown in UV-B when the UV-B was removed. Finally, the detailed time course of the UV-B effect on g_s and the net CO₂ assimilation rate (A) was characterized. The results strongly suggest that there is a direct UV-B effect on stomata, together with additional effects caused by changes in mesophyll photosynthetic activity.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

Plant Material

Pea (Pisum sativum L. cv Meteor), commelina (Commelina communis L.), and oilseed rape (Brassica napus L. cv Apex) plants were grown from seed in pots in a greenhouse as described by Nogués et al. (1998). Minimum PPFD during a 14-h photoperiod was maintained at approximately 500 µmol m² s¹ by supplementary lighting from high-pressure sodium lamps (SON-T DLS 400 W, Thorn, G.E. Lighting, Kingston-upon-Thames, UK). Temperature and the leaf-to-air vapor pressure difference (VPD) were maintained at approximately 23°C/19°C and 1.7/1.3 kPa day/night, respectively.

Exposure to Different UV-B Irradiance and Leaf Inversion Experiments

After the pea seeds were sown, pots were placed in a transparent UV-exposure cabinet within the greenhouse, as described by Allen et al. (1997). The UV-C radiation was screened out by cellulose diacetate film, and the control treatments were under the same configuration of lamps as the UV-B treatments, but the UV-B was screened out with Mylar-D film. The UV spectrum at the top of the plants was measured with a scanning spectroradiometer (SR 991-PC, Macam Photometrics, Livingston, UK) and was the same as that previously described (Allen et al., 1997). Greenhouse and cabinet transmission of UV-A radiation, supplemented by the UV fluorescent lamps, ensured that UV-A exposure was maintained for photorepair and flavonoid biosynthesis (Teramura and Ziska, 1996). Plants were grown throughout their development without UV-B or with three different UV-B doses. The biologically weighted UV-B dosages over the 14-h exposure period according to the generalized plant action spectrum (normalized to 300 nm; Caldwell, 1971) for the high-, medium-, and low-UV-B and control treatments were 0.63 W m² (32 kJ m² d¹), 0.30 W m² (15 kJ m² d¹), 0.21 W m² (11 kJ m² d¹), and 0.001 W m², respectively. The UV-exposure cabinet was divided into four independent sections, and plants and treatments were regularly exchanged between these sections to minimize any between-section differences other than UV-B treatments. Individual plants were considered as replicates in all statistical analyses. The experiment started with 18 plants in each section. After 21 d of growth from sowing under control or different UV-B treatments, the sixth leaf pair (numbered from the base, i.e. chronologically) of six plants was turned over in situ, leaves were held in an inverted position using fine nylon line for 9 d, and these were compared with six plants with normally positioned leaves.

The adaxial and abaxial g_s were measured in situ between midday and early afternoon on both normal and inverted leaves every day using a transit-time porometer (AP4, Delta-T Devices, Cambridge, UK), taking measurements from six leaves per treatment according to the method of Nogués et al. (1998). The sixth leaf pair (fully expanded on d 21) was used for all measurements.

In a second experiment, plants of oilseed rape were also grown in the same experimental system, but only at the highest UV-B dose (0.63 W m²). Measurements of g_s were taken after full expansion of both first and second true leaves. In a third experiment, commelina plants were grown in the greenhouse and after 21 d they were placed in the control and high UV-B sections of the UV-exposure cabinet described above for 5 d. The adaxial and abaxial g_s were measured in situ around midday as above after 5 d of high-UV-B or control treatments.

Sudden Exposure and Recovery Experiments in Pea

After 5 d of the above experiment with pea, the remaining six plants were transferred from high UV-B (0.63 W m²) to the control treatment to determine recovery, and simultaneously six control plants were transferred to the high-UV-B treatment to determine the kinetics of the effect on stomata. Measurements of g_s were taken on the seventh leaf (fully expanded on d 26).

Kinetics of Stomatal Closure in Response to UV-B

Pea plants were grown in the greenhouse described above for 21 d without UV-B. Attached mature leaves were then enclosed for 14 h in a temperature-controlled leaf cuvette connected to a programmable gas-exchange system (model MPH-1000, Campbell Scientific, Logan, UT) incorporating an IR gas analyzer (model LI-6262, LI-COR, Lincoln, NE). The glass top of the cuvette was replaced by 2-mm-thick quartz glass (Optiglass, Essex, UK), allowing UV-B radiation to reach the leaf tissue. UV-B radiation was provided by two UV-B tubes (model TL40W, Philips, Hamburg, Germany) mounted above the chamber. The UV spectrum reaching the leaves was measured with the scanning spectroradiometer with the sensor placed below the quartz glass and was the same as in the UV-exposure cabinet. The biologically weighted UV-B dosages were the same as the high UV-B and control treatments used in the cabinet (i.e. 0.63 and 0.001 W m², respectively). Leaf temperature was maintained at 25°C ± 0.5°C, with 800 µmol m² s¹ of incident PPFD and a VPD of 1.5 kPa.

At the beginning and end of the 14-h measurement period, analyses of the response of net carbon assimilation to intercellular CO₂ concentration at 1200 µmol m² s¹ of incident PPFD were carried out to separate possible limitations imposed by stomata, the carboxylation velocity, and the capacity for regeneration of RuBP on leaf photosynthesis (Allen et al., 1997).

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

Exposure to Different UV-B Irradiances

To evaluate the UV-B dose that affects g_s, pea plants were grown throughout their development without UV-B or with three different UV-B doses (0.21, 0.30, and 0.63 W m²; Fig. 1). For clarity, results from the low-UV-B dose, 0.21 W m², are not shown since they were indistinguishable from the controls. Growth of pea plants under the high dose of UV-B radiation (0.63 W m²) reduced adaxial g_s by 83% (Fig. 1a; Table I) compared with the control (no UV-B) plants, and abaxial g_s by 39% (Fig. 1b; Table I). Therefore, the total g_s (Fig. 1c) decreased. The medium UV-B dose (0.30 W m²) reduced adaxial g_s slightly (23%, Table I), but had no significant effect on abaxial g_s. There were no significant effects on either adaxial or abaxial g_s when pea plants were grown under the low-UV-B dose (0.21 W m²). It should be noted that while artificial lighting was used in the exposure cabinets and the greenhouse was approximately temperature controlled, the environmental conditions were not constant, and some of the day-to-day variation was caused by varying environmental conditions and by leaf aging.

View larger version (24K): [in this window] [in a new window]   Figure 1.   Changes in the adaxial (a), abaxial (b), and total (adaxial plus abaxial) (c) gs for mature pea leaves during 10 d of UV-B treatment. Plants were grown from seed for 21 d prior to these measurements either without UV-B radiation () or with 0.30 () or 0.63 () W m2 of UV-B radiation. Another treatment of 0.21 W m2 of UV-B had no detectable effect, and is not shown. Data are the means of six replicates ± 1 pooled SE derived from ANOVA shown on the last day.

View this table: [in this window] [in a new window]   Table I.   The effects of UV-B exposure during growth on gs of pea leaves Results averaged over 9 or 10 d after growth from seed for 21 d either without UV-B radiation (control), or with 0.21 (low), 0.30 (medium), or 0.63 (high) W m2 UV-B. Total gs is the sum of abaxial and adaxial gs. Means and pooled SE for each UVB treatment were calculated from separate ANOVA for each parameter with data from single leaves on six plants in each treatment, with leaves in the normal position (average over 10 d) or leaves inverted after the 1st d of measurement (average over 9 d). Means within the same part of a column (either normal or inverted) followed by same letter are not significantly different (P > 0.05).

Leaf Inversion Experiments

To investigate whether the inhibition of adaxial g_s is a direct result of higher UV-B irradiances on this surface, pea leaves were turned over for 9 d in the different UV-B treatments (Fig. 2; for clarity, data from the low-UV-B dose, 0.21 W m², are not shown as they were indistinguishable from the controls). In all treatments leaf inversion resulted in a reduction in adaxial g_s, as this surface now received less PPFD (Fig. 2a; Table I), although the effect was not large for the highest UV-B treatment, where adaxial g_s was very low prior to inversion (see also Fig. 1a). In the control (no UV-B), low-, and medium-UV-B treatments, inversion caused a substantial increase in abaxial g_s, as this surface was now illuminated directly with PPFD (compare Fig. 2b with Fig. 1b; Table I). In the highest UV-B-irradiated plants there was no increase in abaxial g_s when the leaves were turned over due to the simultaneous increase in UV-B irradiation, despite the increase in PPFD (Fig. 2b; Table I). However, the direct exposure to higher irradiance of UV-B did not cause any appreciable decrease in abaxial g_s (Table I). Therefore, for the high-UV-B treatment the total g_s (Fig. 2c) was approximately the same in inverted leaves as normal leaves, but lower for the control, low-, and medium-UV-B treatments.

View larger version (23K): [in this window] [in a new window]   Figure 2.   Changes in the adaxial (a), abaxial (b), and total (adaxial plus abaxial) (c) gs for mature pea leaves during 9 d of UV-B treatment after leaves were turned over (indicated by the dotted line). The plants were grown from seed for 21 d prior to these measurements either without UV-B radiation () or with 0.30 () or 0.63 W m2 () of UV-B radiation. Another treatment of 0.21 W m2 of UV-B radiation had no detectable effect, and is not shown. Data are the means of six replicates ± 1 pooled SE derived from ANOVA shown on the last day.

Sudden Exposure and Recovery Experiments

A reciprocal transfer of pea plants from control (no UV-B) and high-UV-B growth treatments (0.63 W m²) for 5 d showed large effects on the 1st d (Fig. 3). Initial g_s values were similar to those of plants shown in Figure 1. After the 1st d of exposure of control plants to UV-B radiation, adaxial g_s decreased by approximately 42% (Fig. 3a), with further decreases subsequently. The abaxial g_s (Fig. 3b) also decreased sharply on the 1st d, but subsequently recovered to a level similar to that in the beginning of the experiment. When UV-B-irradiated pea plants were transferred to the control (no UV-B) treatment (Fig. 3a), there was an initial large increase in adaxial g_s, followed by a decline to very similar values to those of plants moved into UV-B and comparable to those of plants continually exposed to high UV-B (compare with Fig. 1a). Abaxial and total g_s increased on the 1st d after transfer out of UV-B (Fig. 3, b and c), but thereafter in both transferred groups of plants g_s values on either side of the leaf were indistinguishable, and were similar to those in plants continually exposed to high UV-B (Fig. 1, but note these were leaf 6, not leaf 7). Adaxial g_s of leaf 6 for no UV-B and high UV-B plants not transferred over this same period was 0.422 ± 0.075 and 0.128 ± 0.052 mol m² s¹, respectively, and for the abaxial surface, g_s was 0.472 ± 0.082 and 0.419 ± 0.088 mol m² s¹, respectively.

View larger version (20K): [in this window] [in a new window]   Figure 3.   Changes in the adaxial (a), abaxial (b), and total (adaxial plus abaxial) (c) gs over 5 d for previously unexposed 21-d-old pea plants moved to 0.63 W m2 of UV-B () or for previously exposed plants moved to no UV-B (). The vertical dotted line indicates the time of transfer. Data are the means ± SE of six replicates (SE values are shown when larger than the symbols).

When mature commelina leaves previously unexposed to UV-B were irradiated with high UV-B for 5 d, the adaxial g_s was reduced by approximately 40% (Table II), somewhat less than that shown for the previously unexposed pea in Figure 3. Oilseed rape plants grown in high UV-B also showed similar reductions in adaxial g_s. For all of this material the reductions in adaxial g_s led to reductions in total g_s, as the abaxial g_s was either unchanged or reduced.

View this table: [in this window] [in a new window]   Table II.   Effect of UV-B irradiation (0.63 W m2) on gs Measurements on (a) leaves of mature C. communis previously unexposed after 5 d of irradiation (b & c) 1st and 2nd leaves of B. napus cv Apex after growth with 0.63 W m2 of UV-B radiation. Total gs is the sum of abaxial and adaxial gs. Means ± SE are given. P, The probability of difference between treatments from one-tailed t test; NS, P > 0.10.

Kinetics of Stomatal Closure in Response to UV-B

To evaluate with higher temporal resolution the time course of UV-B-induced stomatal closure, attached, mature pea leaves (grown without UV-B exposure) were enclosed in a leaf cuvette connected to a gas-exchange system, and illuminated with 800 µmol m² s¹ of PPFD for 14 h either without UV-B or with high UV-B (Fig. 4). While VPD, PPFD, and chamber CO₂ concentration were closely controlled, the gas exchange system estimated total g_s only, as the whole leaf was enclosed. In control leaves total g_s and A had decreased by approximately 20% by the end of the 14-h measurement period and c_i had not significantly changed. In leaves irradiated with 0.63 W m² of UV-B, both g_s and A started to drop within 3 h of the start of irradiation, and after 14 h of treatment they had both decreased by approximately 50% (Fig. 4, a and b). However, c_i remained almost constant at first, only decreasing 20 to 25 µmol mol¹ after about 7 h (Fig. 4c). The time courses of A and g_s after exposure to UV-B-fitted exponential declines well (Fig. 5, r² = 0.991 and 0.948, respectively, using nonlinear regression), although there was some uncertainty over the early part of the time course for g_s. The exponential model gave lag times of 2.8 h (±0.12 SE) and 4.3 h (±0.30 SE) for A and g_s, respectively, but similar time constants (3.51 and 3.11 h, respectively, not significantly different), and final estimated reductions of 57.6% and 55.2%, respectively (not significantly different). This suggests a close coupling of A and g_s (Fig. 6). In the leaves that were not exposed to UV-B, the small decline of g_s and the larger decline in A during the experiment resulted in the slope of the g_s/A relationship (Fig. 6) increasing slightly from that equivalent to a ratio of intercellular to ambient CO₂ (c_i/c_a) of about 0.80 to that equivalent to 0.85. In the UV-B-irradiated leaves the more closely matching declines in A and g_s over a wider range than in the control plants resulted in a more constant g_s/A, with a value equivalent to a c_i/c_a ratio between 0.80 and 0.75. 

View larger version (24K): [in this window] [in a new window]   Figure 4.   Changes in gs, A, and ci in illuminated mature pea leaves throughout 14 h of no UV-B () or 0.63 W m2 of UV-B () irradiation treatments in a leaf chamber. Incident PPFD was 800 µmol m2 s1 and leaf temperature was maintained at 25°C ± 0.5°C, with a VPD of 1.5 kPa. Data are the means ± SE of three replicates (SE values are shown when larger than the symbols).

View larger version (22K): [in this window] [in a new window]   Figure 5.   Exponential decline time courses of total gs (a) and A (b) in illuminated mature pea leaves after exposure at t = 0 to 0.63 W m2 of UV-B irradiation. Lines shown were fitted by nonlinear regression using the model y = yf + aeb(tto), where yf is the estimated final value, b is (time constant)1, to is the lag time, and a the overall change in y. Symbols indicate means of three leaves replotted from Figure 4.

View larger version (16K): [in this window] [in a new window]   Figure 6.   Relationship between total gs and A in illuminated mature pea leaves throughout 14 h of no UV-B () and 0.63 W m2 of UV-B () treatments. Points were joined in the time course in the order indicated by the arrows. Dotted lines indicate the relationship between gs and A if the ratio ci/ca was constant at the value indicated. Data are the means of three replicates, and are replotted from Figure 4.

Analyses of the response of A to c_i were carried out at the beginning and at the end of the 14-h measurement period to characterize the effect of the UV-B on photosynthesis. After 14 h of constant illumination in the leaf cuvette without UV-B the CO₂-saturated net CO₂ assimilation rate (A_max), the A_sat, V_cmax, and the J_max were decreased by approximately 20% to 30% compared with the values obtained at the beginning of the measurement period (Table III). There was little change in stomatal limitation, indicating close coupling between mesophyll assimilation and stomatal aperture as leaf activity changed. In comparison, irradiation for 14 h with high UV-B caused larger reductions of A_sat (55% compared with 28%) and increased the limitation imposed by stomata to CO₂ uptake (l) from approximately 12% to 20% (Table III).

View this table: [in this window] [in a new window]   Table III.   Analysis of the response of A to ci in pea leaves before or after exposure to high-UV B (0.63 W m2) irradiation for 14 h Parameters estimated from analysis were: Amax, Asat, Vc,max, Jmax, and l. During measurement PPFD was 1200 µmol m2 s1, leaf temperature was 25°C ± 0.5°C, and VPD = 1.5 kPa. Values shown are means ± 1 SE of three replicates. P, Probability for observed differences between 0- and 14-h measurements for each treatment, calculated from paired, one-tailed t test; Pdiff, probability for difference between treatments in percentage change, calculated from one-tailed t test. NS, Pdiff > 0.20.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

Growth of pea plants in high (0.63 W m²) and medium (0.30 W m²) UV-B radiation doses resulted in a substantial decrease of g_s (Fig. 1; Table I), with a much larger effect on adaxial than on abaxial g_s. However, the lowest doses observed to exert significant effects (0.30 W m²) were approximately three times the current maximum midsummer UK exposure. There were similar reductions in g_s in commelina and oilseed rape plants (Table II), indicating that this is a general effect. In our previous work with pea (Nogués et al., 1998), although the decline in total g_s was very similar to that reported here, only adaxial g_s was affected by high UV-B, and that change was mediated by changes in aperture, as there was no reduction in stomatal density (number of stomata per millimeter). The results from the leaf inversion experiments with pea (Fig. 2) and the transfer experiments for pea (Fig. 3) and commelina (Table II) also show that UV-B affected stomatal aperture, as changes in cell development and stomatal density cannot be involved over the short time scales of these g_s changes in fully developed leaves.

We conclude that the UV-B affects guard cells directly, independently of changes in the mesophyll photosynthetic activity for three reasons. First, our previous work with pea (Nogués et al., 1988) in an identical experimental arrangement to that used here showed that there were no changes in any photosynthetic parameter measured (A_sat, V_cmax, J_max, F_v/F_m, or _PSII) in plants developed under high UV-B (0.63 W m²). Second, the effects of UV-B was largest on the exposed adaxial leaf surface. If UV-B was affecting mesophyll photosynthesis it presumably would have affected both leaf surfaces equally. Lastly, on leaf inversion, the light level on the different epidermes is changed by 10- to 50-fold, but photosynthesis should not be affected, as the same total photon flux density is incident on the mesophyll, (see early examples of this technique by Turner, 1970; Pemadasa, 1979). Therefore, in the control plants (Fig. 2), the so-called "direct" response of guard cells to light, which acts independently of the response to c_i or to some mesophyll photosynthesis-related signal, resulted in abaxial stomata opening and adaxial stomata closing. However, in the UV-B treatments the opening response of abaxial stomata on inversion was either reduced or eliminated at the highest dose, while the adaxial stomata (with a lower sensitivity to light) closed, demonstrating a direct effect of UV-B on the guard cells. It is interesting to speculate that the larger closing effect of UV-B on adaxial compared with abaxial stomata when equally exposed is related to their well-established lower sensitivity to light (e.g. Pemadasa, 1979; Lu et al., 1993).

Adaxial guard cells receive much higher UV-B irradiation than the mesophyll cells and abaxial guard cells due to attenuation through the leaf by UV-B-adsorbing pigments such as flavonoids, particularly in the epidermis (Bilger et al., 1997; Allen et al., 1998). It is tempting to think of the UV-B induced reduction in g_s as "damage" to the stomatal mechanism. However, it should be noted that the stomata most affected in the adaxial surface did still close in response to shading when inverted (Fig. 2a; Table I). In addition, the stomata in the normal adaxial surface (Fig. 1a) and in the inverted abaxial surface still responded to environmental stimuli, as the day-to-day variations closely followed that of control plants (compare Figs. 1 and 2). Even so, upon inversion, stomata in the abaxial surface of the high-UV-B treatment did not open in response to greater illumination (Fig. 2b; Table I).

The results of the sudden exposure and removal of UV-B experiments are intriguing (Fig. 3). For the long-term irradiated plants there was a brief "recovery" on the 1st d after removal of UV-B, followed by a return to previous reduced g_s values, suggesting that the effects of UV-B irradiation on g_s were persistent. We can offer no explanation for the brief recovery. Plants newly exposed to high UV-B showed a large decline in g_s that took 2 to 3 d to reach a new steady value, but which was already marked within 1 d. Further, kinetic analyses (Figs. 4 and 5) showed that the inhibitory effect of UV-B started within 4 to 5 h of the onset of irradiation. However, while there may be a more rapid short-term effect on adaxial g_s (perhaps responsible for the drop in total g_s evident after approximately 2 h in Fig. 5), the major effect seemed to be associated with the decline in A. Indeed, there was a close but not complete correlation of g_s with A (Fig. 6), as was first noted by Wong et al. (1979) and as is often observed with a wide range of environmental conditions.

It should be noted that there is a substantial difference in the effect of UV-B on photosynthesis depending on whether plants have developed under it (as in the plant material used for Figs. 1 and 2, and part of Fig. 3) or whether they are suddenly exposed (plant material in part of Fig. 3 and Figs. 4-6). In previous work with peas we found no effect of high-UV-B dose on A_sat, V_c,max, and J_max when plants were grown under high UV-B (Nogués et al., 1998), but declines in A_sat after 12 h of approximately 50% (Nogués and Baker, 1995) for newly exposed plant material, which is consistent with the observed reductions of A shown in Figures 4 and 5, and the declines in A_sat shown in Table III. In newly exposed leaves of oilseed rape, the effects on A_sat were smaller and took longer, but were still of the order of 50% after 5 d (Allen et al., 1997), and were accompanied by decreases in carboxylation velocity and Rubisco activity and content.

The approximately constant c_i value as A changed by 50% might suggest that stomata act to maintain c_i constant, but the analyses of Farquhar and colleagues and others (e.g. Farquhar et al., 1978; Wong et al., 1978; Morison and Jarvis, 1983) have shown that usually the sensitivity of stomata to c_i is not sufficient to result in a constant c_i. Instead, it appears that there is some other mechanism that results in the close coupling of g_s and A. Recently, Jarvis and Davies (1998) have revived the proposal of Farquhar and Wong (1984) that stomata respond to a carbon-fixing substrate pool that Jarvis and Davies term the "residual photosynthetic capacity." The decline in g_s observed in Figures 4 and 5 during exposure to high UV-B may be an example of such a finely tuned response of g_s to the photosynthetic activity being reduced by UV-B, on which the direct effect of UV-B on stomata, particularly those on the exposed adaxial surface, is superimposed.

The observed increase in stomatal limitation after irradiation with high UV-B (Table III) was similar to that found in oilseed rape plants newly exposed to UV-B (Allen et al., 1997). However, the effect observed here was not large, because photosynthetic capacity declined (indicated by A_max) in addition to the direct effect of UV-B on g_s. In contrast, in pea plants grown under high UV-B, the small increase in stomatal limitation was entirely due to reductions in g_s (Nogués et al., 1998) as photosynthesis was not affected. It is clear that the high UV-B doses that affect stomata can lead to effects on CO₂ assimilation (see introduction).

The mechanism for the UV-B effect on stomata is not known. Stomatal opening follows a K⁺ influx along a electrochemical gradient formed by ATPase outward proton pumps situated in the guard cell plasmalemma (Zeiger, 1983). Wright and Murphy (1982) have shown that UV-B radiation can induce stomatal closure directly by inhibiting K⁺ accumulation, and Negash et al. (1987) demonstrated the leakage of ⁸⁶Rb⁺ from guard cells in response to UV-B irradiation. By extrapolation from the numerous studies on mesophyll photosynthesis (Allen et al., 1998), these effects could be due to damage to PSII in the guard cells, affecting photophosphorylation and hence ion transport. A second mechanism may involve a direct inhibition by UV-B of the plasmalemma ATPase proton pump (Allen et al., 1998). Alternatively, UV-B may not directly affect the generation of the guard cell turgor pressure, but rather may modify the effect of this turgor on pore size through UV-B-induced changes in the elasticity of the cell walls or the cytoskeleton of guard cells and the neighboring epidermal cells (Allen et al., 1998).

	CONCLUSIONS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS LITERATURE CITED

This study has shown that growth of pea plants in high-UV-B radiation resulted in a decrease of g_s, with direct effects on the exposed guard cells (usually the adaxial surface). Leaf inversion experiments showed that both adaxial and abaxial stomata could be directly affected by this UV-B, although it appeared there was different sensitivity of the stomata on the two surfaces, with adaxial stomata being more affected. There was no long-term recovery in g_s after cessation of long-term UV-B exposure, indicating that the effect is permanent. The time course of the effect of high-UV-B irradiance on stomata of previously unexposed plants was rapid (a time constant of approximately 3 h after a lag of approximately 4 h), and this was closely correlated with changes in A. We conclude that high-UV-B irradiances affect stomata both directly, by acting on the guard cell aperture control mechanisms, and indirectly, through changes in the mesophyll photosynthesis.