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Tree Physiology 22, 687–697 © 2002 Heron Publishing—Victoria, Canada Photosynthetic responses to water deficit in six Mediterranean sclerophyll species: possible factors explaining the declining distribution of Rhamnus ludovici-salvatoris, an endemic Balearic species J. GULÍAS,1 J. FLEXAS,1,2 A. ABADÍA3 and H. MEDRANO1 1 Laboratori de Fisiologia Vegetal, Departament de Biologia, Universitat de les Illes Balears, Carretera de Valldemossa, Km. 7.5, 07071 Palma de Mallorca, Balears, Spain 2 Author to whom correspondence should be addressed ([email protected]) 3 Departamento de Nutrición Vegetal, Estación Experimental de Aula Dei (Consejo Superior de Investigaciones Científicas), Apartado 202, 50080 Zaragoza, Aragón, Spain Received September 25, 2001; accepted December 31, 2001; published online June 3, 2002 Summary We sought to explain the declining distribution in the Balearic Islands of the endemic shrub Rhamnus ludovicisalvatoris R. Chodat, by comparing its photosynthetic response to drought with that of several widely distributed, competing Mediterranean species (R. alaternus L., Quercus ilex L., Pistacia lentiscus L., Q. humilis Mill. and P. terebinthus L.). All of the study species, except for the two Rhamnus species, avoided desiccation by rapidly adjusting their stomatal conductance at the onset of drought, and maintaining constant leaf relative water content. The two Rhamnus species showed desiccation-tolerant behavior; i.e., as drought progressed, their predawn leaf relative water content decreased simultaneously with stomatal closure. All four desiccation-avoiding species showed a significant positive correlation between leaf thermal dissipation (estimated by the fluorescence parameter NPQ (non-photochemical quenching)) and the de-epoxidation state of the xanthophyll cycle (DPS). The two Rhamnus species exhibited maximum DPS regardless of treatment, but only R. alaternus increased NPQ in response to drought. Rhamnus ludovici-salvatoris had a high ratio of photorespiration to photosynthesis and a low intrinsic water-use efficiency; traits that are likely to be unfavorable for plant productivity under arid conditions. It also had the lowest DPS and thermal dissipation among the six species. We conclude that the photosynthetic traits of R. ludovici-salvatoris account for its limited ability to compete with other species in the Mediterranean region. Keywords: chlorophyll fluorescence, deciduous, drought, evergreen, gas exchange, leaf mass area, nitrogen, Pistacia, Quercus, Rhamnus, xanthophyll cycle. Introduction Drought is the main environmental constraint on plant biomass production in the Mediterranean region. Consequently, it is likely that ecophysiological traits that determine the ability of a species to cope with drought partially explains its distribution and ecological fitness in the Mediterranean region (Bazzaz 1979, Schulze 1982, Lambers et al. 1998). The intrinsic link between photosynthesis and biomass production suggests that photosynthesis and its response to drought is likely to play a major role in determining the ability of tree seedlings to establish in drought-prone areas, because unlike adult trees, seedlings do not possess additional compensatory mechanisms such as deep roots or dense canopies. The closest association between leaf photosynthesis and plant growth is seen in young plants, a fact attributable to their low leaf area index (Gardner et al. 1985). A good correlation between net photosynthesis and relative growth rate has been observed in saplings (Pattison et al. 2001) and a correlation between seasonal photosynthesis and the percentage of ground covered was found in Chaparral species (Oechel et al. 1981). Differences in photosynthetic properties and responses to drought between evergreen and winter deciduous species may account for differences in the distribution patterns of the two groups of species in Mediterranean-type ecosystems (Ehleringer and Mooney 1982, Ne’eman and Goubitz 2000). Deciduous species generally predominate in cold and humid subMediterranean regions and compensate for their shorter growth period with a higher photosynthetic capacity (Ehleringer and Mooney 1982, Ne’eman and Goubitz 2000, but see Damesin et al. 1998). In contrast, evergreen species predominate in the hot and dry Mediterranean regions, where they can maintain high photosynthetic rates during winter when deciduous species are photosynthetically inactive. Endemic plants account for 7–8% of the flora of the Mediterranean islands (Cardona and Contandriopoulos 1979). However, judging from their declining distribution and high extinction rates (Alomar et al. 1997), some endemic species are poorly adapted to present conditions. Because climate 688 GULÍAS, FLEXAS, ABADÍA AND MEDRANO change models predict that more arid conditions will prevail in the Mediterranean Basin (Osborne et al. 2000), many of these species may become extinct. A recent survey of Balearic endemic species showed that these plants have a lower photosynthetic capacity under optimal conditions than their widespread relatives (J. Gulías et al., unpublished results). The low photosynthetic capacity was associated with low specific leaf area and photosynthetic nitrogen-use efficiency. We studied Rhamnus ludovici-salvatoris R. Chodat, an endemic evergreen shrub that declined in distribution during the last century. Until recently, this species was found in Cabrera, Menorca, Serra de Tramuntana and Serra de Llevant (the last two areas located on the island of Mallorca) (Alomar et al. 1997). Today, however, the species has disappeared from Menorca and Serra de Llevant. Furthermore, where it survives, the populations are characterized by a low proportion of seedlings and young saplings, suggesting low establishment success. The main objective of this study was to compare the photosynthetic response to drought of saplings of R. ludovicisalvatoris with that of species that are widely distributed in the Mediterranean region. A second goal was to evaluate whether other species with low distribution in the Balearic Islands (i.e., winter deciduous species) have the same leaf traits as R. ludovici-salvatoris. the shrubs (P. lentiscus and the two Rhamnus species) are nanophylls, and the trees (P. terebinthus and the two Quercus species) are nano-microphylls or microphylls (Christodoulakis and Mitrakos 1987). All these species share some basic characteristics: they have a Mediterranean origin and distribution (Suc 1984, Castro-Díez et al. 1998, Ne’eman and Goubitz 2000), they are currently growing within the Mediterranean oak forests and related successional communities (Tomaselli 1981, Suc 1984), and they are sclerophyllous (Christodoulakis and Mitrakos 1987). The study plants, six per species, were grown outdoors at the University of the Balearic Islands (Mallorca, Spain), in large pots (volume 60 l, height 60 cm) containing a 1:1 (v/v) mixture of clay–calcareous soil and horticultural substrate. Although the pots may eventually limit root growth, they otherwise simulate natural conditions because about 85% of root biomass of sclerophyllous shrubs is located in the upper 50 cm of the soil profile (Jackson et al. 1996). The plants were 5 years old at the onset of the experiments, which were conducted during the summers (July–September) of 1998, 1999 and 2000. The environmental conditions during these summers were similar, with a mean maximum temperature of 30 °C and a mean minimum temperature of 19 °C, no rain and a mean monthly evapotranspiration of 160 l m –2. Materials and methods Treatments and water status determination Plant material and environmental conditions Mallorca, the largest Balearic Island, is situated in the western Mediterranean Basin (39°15′ to 40°00′ N, 2°15′ to 3°30′ E). The climate is Mediterranean, with a mean annual rainfall ranging from 300 mm on the south coast to more than 1000 mm in some mountain areas in the northwest. Rain falls mainly from September to April, and drought can last for 5–6 months. The dominant vegetation comprises evergreen sclerophyll shrublands (dominated by Pistacia lentiscus L., Rhamnus alaternus L. and Olea europaea L.) and woodlands (dominated by the holm oak, Quercus ilex L.). Winter deciduous woodlands are absent. Six species were studied: Rhamnus alaternus, R. ludovicisalvatoris, Quercus ilex, Q. humilis Mill., Pistacia lentiscus and P. terebinthus L. Rhamnus alaternus, P. lentiscus and Q. ilex are evergreen plants (two shrubs and a tree, respectively) widely distributed on the Balearic Islands and along the western Mediterranean Basin. Rhamnus ludovici-salvatoris is an evergreen shrub of limited distribution, endemic to the Balearic Islands. Its distribution has diminished during the last century, with the extinction of several populations (authors’ unpublished observations). At present, this species is present in only certain localities of Mallorca and Cabrera, a small island south of Mallorca. Pistacia terebinthus and Q. humilis are winter deciduous trees (the former frequently appearing as a shrub), typical of Mediterranean conditions wetter than those in Mallorca. The distribution area of P. terebinthus in Mallorca is limited to some humid mountain areas, whereas Q. humilis is absent from the Balearics. Among these species, Mid-morning (i.e., maximum) light-saturated stomatal conductance (g) is very sensitive to water stress. Its complex regulation depends on interactions with soil water status, xylem abscisic acid (ABA) content, leaf water status and other factors. We have recently shown that g is indicative of leaf water stress, regardless of the factor causing the stress (Flexas et al. 2002, Medrano et al. 2002). Our main rationale for using g as an indicator of water stress is that many species (including those studied here) have similar reductions in photosynthesis at any given g, irrespective of leaf water status and leaf-to-air vapor pressure deficit (Medrano et al. 2002). Based on this criterion, mild drought treatments and severe drought treatments were defined as soil water deficits causing 50 and 75% reductions in maximum g (i.e., relative to the control treatment), respectively. The drought treatments were imposed by withholding water, and mid-morning g values were measured daily until the values corresponding to each treatment were reached. Typically, under summer conditions, water was withheld for about 3 days to achieve a mild drought and for 4–6 days to achieve a severe drought. Although mid-morning g values were used to define the drought treatments, two other independent measurements were also performed to characterize the degree of drought exposure. First, soil water content was determined in four to eight randomly chosen pots per treatment by time domain reflectometry (TDR, Trime System, Imko, Ettlingen, Germany), and referred to as percent of field capacity. Soil water content was 100% (by definition) under well-watered conditions (control), 84 ± 3% for mild drought and 42 ± 2% for severe drought. Second, six leaves per species and treatment TREE PHYSIOLOGY VOLUME 22, 2002 DROUGHT AND PHOTOSYNTHESIS IN MEDITERRANEAN SPECIES were sampled before sunrise to determine relative water content (RWC = (fresh weight – dry weight)/(turgid weight – dry weight)). The turgid weight of the leaves was determined after 24 h in distilled water at 4 °C in the dark. Dry weights were obtained after oven-drying for 48 h at 70 °C. Determination of leaf mass area and leaf nitrogen Samples of the leaves that were used for gas exchange measurements were analyzed for leaf nitrogen concentration ([N]) with an elemental analyzer (Model EA 1108, Carlo Erba Instruments, Milan, Italy). Leaf mass area (LMA = leaf dry weight/fresh leaf area) was determined with an AM-100 leaf area meter (ADC, Herts, U.K.), after which the leaves were dried and weighed. Gas exchange measurements Gas exchange measurements were determined on attached fully expanded leaves in saturating light (1000 µmol m –2 s –1) with a portable IRGA (LI-6400, Li-Cor, Lincoln, NE). When four to six sun-exposed leaves of a given plant showed a g value corresponding to the desired treatment (see above), two were chosen to construct a light- and a CO2-response curve, respectively. This selection procedure was repeated for four replicates per treatment. Temperature was maintained at 30 °C with a relative humidity of 40–60% inside the leaf chamber during measurements (leaf temperatures were between 28 and 33 °C, and leaf-to-vapor pressure deficits were between 2 and 3 kPa). These measurements were completed during the morning to avoid the midday depression of photosynthesis and stomatal conductance. The LI-6400 light source enabled automatic changes in photosynthetic photon flux density (PPFD), which were applied at 3–5 min intervals to determine the light response curves. The PPFDs were 1500, 1000, 750, 500, 200, 50, 25 and 0 µmol m –2 s –1. The CO2 flux was adjusted to maintain a concentration inside the chamber of 360 µmol mol –1. The CO2 response curves were determined at a PPFD of 1000 µmol m –2 s –1. The different CO2 concentrations were obtained from portable CO2/air mixture tanks and automatically controlled by the LI-6400 CO2 injector. The CO2 concentration ([CO2]) was first set near zero and then progressively increased to 50, 100, 200, 360, 500, 650 and 800 µmol mol –1 (Escalona et al. 1999). Gas exchange measurements were determined at each step after maintaining the leaf at the new [CO2] for 5 min. The sub-stomatal [CO2] (Ci) was calculated according to von Caemmerer and Farquhar (1981). The net CO2 assimilation (AN) versus PPFD and AN versus Ci curves were fitted with Sigma Plot 4.0 for Windows (SPSS) by nonlinear regression to hyperbolic and exponential equations, respectively (Martin and Ruiz-Torres 1992, Escalona et al. 1999). Apparent quantum yield (φ) and apparent carboxylation efficiency (ε) were estimated as the initial slopes of the AN –PPFD and AN –Ci curves, respectively. The compensation points for light (k) and CO2 (Γ) were calculated from the x-intercepts of the AN –PPFD and AN –Ci curves, respectively. Dark respiration (RD) was measured after holding the leaves in 689 darkness. The stomatal limitation to photosynthesis (l) was calculated from AN –Ci curves according to Farquhar and Sharkey (1982). Maximum photosynthetic rates at saturating light and [CO2] (Amax) were not measured during construction of the AN –Ci curves, because the [CO2] was not increased above 800 µmol mol –1 to avoid any interference of high [CO2] with stomatal conductance. To ensure that Amax values estimated by the exponential adjustments were close to the real Amax values, we applied higher CO2 concentrations to different leaves than those used for the construction of the AN –Ci curves. These leaves were clamped in the LI-6400 chamber at atmospheric [CO2] and allowed to stabilize. The [CO2] was then immediately (within 1 min) increased to 2000 µmol mol –1, and stomatal conductance monitored continuously. After about 1 min, photosynthesis was stable, and g was almost unchanged. The value of Amax was then recorded. Figure 1 shows the relationship between the measured Amax and that estimated from exponential adjustments. All values fall near the 1:1 ratio, indicating that the estimated values of Amax are reasonable. Extrapolation of the curve to Ci = 0 (R L) was used to estimate the sum of photorespiration and mitochondrial respiration in the light. Although this method could overestimate actual photorespiration, the range of values obtained was consistent with estimations made according to the model of Valentini et al. (1995), which is based on combining gas exchange and chlorophyll fluorescence measurements (data not shown). Chlorophyll fluorescence measurements Chlorophyll fluorescence parameters were measured on attached leaves. For each treatment, six measurements were made on six leaves (i.e., two leaves per plant) with a portable pulse amplitude modulation fluorometer (PAM-2000, Walz, Effeltrich, Germany). At predawn (0600 h), the background Figure 1. Relationship between light- and CO2-saturated photosynthetic rate (Amax) measured at 2000 µmol CO2 mol –1 and that estimated from exponential adjustments of AN versus C i curves. Abbreviations: R.l-s. = Rhamnus ludovici-salvatoris; R.a. = Rhamnus alaternus; Q.i. = Quercus ilex; Q.h. = Quercus humilis; P.l. = Pistacia lentiscus; and P.t. = Pistacia terebinthus. TREE PHYSIOLOGY ONLINE at http://heronpublishing.com 690 GULÍAS, FLEXAS, ABADÍA AND MEDRANO fluorescence signal (Fo), the maximum fluorescence (Fm) and the maximum quantum yield of photosystem II (PSII) (Fv /Fm = (Fm – Fo)/Fm) were determined at an irradiance of 0.5 µmol m –2 s –1 and a frequency of 600 Hz. Steady-state fluorescence (Fs) in mid-morning sunlight was determined at an irradiance of 0.5 µmol m –2 s –1 and a frequency of 20 kHz. The PPFD incident on the leaves was always higher than 1000 µmol m –2 s –1, which was above photosynthesis saturation in these plants. To obtain the steady-state maximum fluorescence yield (Fm′), saturation pulses of about 10,000 µmol m –2 s –1 and 0.8-s duration were applied. The PSII photochemical efficiency (∆F/Fm′) was then calculated according to Genty et al. (1989): ∆F/ Fm′ = ( Fm′ − Fs ) / Fm′, (1) and used to determine the linear electron transport rate (ETR) (Krall and Edwards 1992): ETR = ( ∆F / Fm′ PPFD0.5 ) 0.84, (2) where PPFD is photosynthetic photon flux density incident on the leaf, 0.5 is a factor that assumes an equal distribution of energy between the two photosystems, and 0.84 is the leaf absorptance for many sclerophyll species (Ehleringer and Comstock 1987). In this study, leaf absorptance was estimated according to Sharp et al. (1984). No significant differences were observed among the six species (data not shown). Nonphotochemical quenching of chlorophyll fluorescence (NPQ) at mid-morning was calculated as: NPQ = ( Fm − Fm′ ) / Fm′. (3) Pigment analyses Immediately after chlorophyll fluorescence measurements (at predawn and midday), discs were punched from leaves of the same plants showing the same orientation as those used for fluorescence measurements and submersed in liquid nitrogen. Six samples per treatment were taken from different plants (around three to four leaves per sample). The values presented are means ± SE. Pigments were extracted by grinding leaf tissue in a mortar with acetone (1 cm2 of leaf tissue per ml of solvent) in the presence of sodium ascorbate. Pigments were identified and quantified by high performance liquid chromatography according to Abadía and Abadía (1993). Statistical analyses Statistical analyses of the data were performed with the SPSS 9.0 software package (SPSS, Chicago, IL). Pearson’s correlation analysis was performed on all the studied parameters. Two-way ANOVAs, with treatment and species as factors, were performed for the studied parameters. Differences between means were revealed by Tukey’s highest significant difference (HSD) analyses (P < 0.05). Results Maximum photosynthesis and stomatal conductance values Maximum values of photosynthesis and stomatal conductance (Table 1) of the experimental plants were similar to those obtained for the same species under field conditions. Net photosynthetic rates were about 15–16 µmol m –2 s –1 for the Quercus species and for P. terebinthus (see Gucci et al. 1997, Damesin et al. 1998, Gulías et al. 2002), and about 11 µmol m –2 s –1 for the Rhamnus species and for P. lentiscus (see Gucci et al. 1997, Flexas et al. 2001, J. Gulías et al., unpublished results). The values under mild and severe drought were similar to those of field-grown plants at the beginning and at the end of the summer, respectively (Damesin and Rambal 1995, GarcíaPlazaola et al. 1997, Faria et al. 1998, Flexas et al. 2001, Gulías et al. 2002). Variations in RWC, LMA and leaf N concentration with declining g A summary of the ANOVA of the effects of drought treatment and species, and the combined treatment × species interaction on mid-morning g, predawn leaf relative water content (RWC), leaf mass area (LMA) and leaf [N] is shown in Table 2. Drought treatment had little effect on RWC; that is, g was reduced by half before any change in RWC could be detected. However, the highly significant effect of the combined treatment × species interaction reveals species-dependent differences in the RWC response. As shown in Figure 2, the Quercus and Pistacia species showed changes in RWC of less than 10%, even when stomatal closure was pronounced (we therefore refer to these species as desiccation avoiders). In contrast, both Rhamnus species showed large reductions in RWC (> 10%) in response to soil water depletion that were paralleled by stomatal closure (a response characteristic of desiccation-tolerant species). A small reduction in RWC in response to severe drought has been reported in some species (Henson et al. 1989), and may be a result of tight stomatal regulation in response to rapidly imposed drought. Drought did not significantly affect LMA. The highly significant effect of the treatment × species interaction on LMA was caused by the two Rhamnus species, which showed progressively increasing LMA with increasing soil water depletion. Because leaf growth was complete before the start of the experiments, it is likely that the observed treatment effect on LMA was simply a result of interannual differences. Although there were significant effects of treatment, species and treatment × species interaction on leaf [N], the treatment effect was evident only under severe drought. Even under severe drought, leaf [N] was reduced by less than 30% (Table 2), whereas g was reduced by 75%, suggesting that the reduction in leaf [N] was a consequence of low water uptake by roots as a result of reduced transpiration. Because no leaf or shoot growth was observed during the experiment, we assumed that any influence of developmental and nutritional differences between treatments was low. TREE PHYSIOLOGY VOLUME 22, 2002 DROUGHT AND PHOTOSYNTHESIS IN MEDITERRANEAN SPECIES 691 Table 1. Mean values for the study species and treatments of most of the parameters studied. Different letters indicate significantly (P < 0.05) different means among treatments and species (that is a total of 18 treatments, these being the 18 species × treatment combinations). Abbreviations: g (mmol H2O m –2 s –1) = stomatal conductance; RWC (%) = relative water content; LMA (g m –2) = leaf mass area; [N] (mg g –1 dry weight) = leaf nitrogen concentration; AN (µmol m –2 s –1) = net CO2 assimilation; A/g (µmol mol –1) = intrinsic water-use efficiency; φ (mol quantum –1) = apparent quantum yield; k (µmol m –2 s –1) = compensation points for light; RD (µmol m –2 s –1) = dark respiration ; Amax (µmol CO2 m –2 s –1) = light- and CO2-saturated photosynthesis; ε (mol –1) = apparent carboxylation efficiency; Γ (µmol mol –1) = compensation point for CO2; RL (µmol m –2 s –1) = the sum of photorespiration and mitochondrial respiration in the light; l (dimensionless) = stomatal limitation to photosynthesis; Fv /Fm (dimensionless) = maximum quantum yield of photosystem II; ETR (µmol m –2 s –1) = electron transport rate; NPQ (relative units) = non-photochemical quenching of chlorophyll fluorescence; [Chl] (mmol m –2) = concentration of chlorophyll; [VAZ] (mmol m –2) = concentration of violaxanthin, antheraxanthin and zeaxanthin. Treatments: C = control; MD = mild drought; and SD = severe drought. R. alaternus C g 165.0 bc RWC 87.2 abc LMA 136.1 abcd [N] 1.98 def 11.5 AN bc AN/g 74.9 abc φ 0.063 ab k 19.3 a 1.2 RD cd Amax 26.1 bc ε 0.066 bcde Γ 74.6 abc 4.9 RL bcde l 0.43 abcdef Fv/Fm 0.794 abcd ETR 96.1 def NPQ 2.7 bcd [Chl] 22.5 efg [VAZ] 10.5 abc R. ludovici-salvatoris Q. ilex Q. humilis P. lentiscus P. therebinthus MD SD C MD SD C MD SD C MD SD C MD SD C MD SD 59.6 def 77.2 bcde 155.4 cde 2.12 cde 5.2 fghi 87.4 abc 0.042 bcdef 37.4 ab 1.5 cd 19.4 cde 0.044 defg 98.3 abcd 4.3 cde 0.51 abcdef 0.741 ef 64.9 fgh 3.9 def 30.1 bcdef 7.6 cdef 38.5 f 81.4 de 162.1 de 1.75 efg 4.2 ghi 113.9 c 0.048 abcdef 38.8 ab 1.8 cd 17.1 cdef 0.043 defg 103.3 bcd 4.5 bcde 0.62 def 0.736 f 44.9 gh 3.8 def 37.0 b 9.0 abcde 222.0 ab 88.9 abc 111.5 a 1.84 ef 10.9 cde 49.2 a 0.060 abcd 73.2 c 4.2 a 32.1 ab 0.080 bcd 96.7 abcd 7.8 ab 0.33 a 0.799 abcd 106.1 def 2.7 bcd 26.1 cdefg 7.4 cdef 115.5 cdef 82.2 bcde 145.1 bcde 1.76 efg 9.3 cde 83.1 abc 0.048 abcdef 46.3 abc 2.1 bcd 26.0 bc 0.064 bcdef 93.1 abcd 6.0 abcd 0.38 ab 0.791 abcd 74.4 efg 3.2 bcde 33.9 bc 9.5 abc 37.9 f 73.2 de 174.0 ef 1.65 fg 3.3 i 85.1 abc 0.033 cdef 43.0 abc 1.4 cd 16.7 cdef 0.037 efg 163.9 e 5.9 abcd 0.59 bcdef 0.737 f 80.0 def 3.3 bcde 45.5 a 4.8 f 277.8 a 80.3 cde 198.3 fg 1.34 hi 15.5 a 56.9 ab 0.060 abc 23.1 ab 1.4 cd 32.3 ab 0.089 bc 69.0 ab 6.2 abcd 0.39 a 0.816 ab 164.8 ab 2.3 abc 21.6 fg 5.9 def 112.3 cdef 82.7 bcd 200.3 fg 1.27 i 7.4 defgh 66.3 ab 0.032 def 52.1 bc 1.5 cd 14.8 cdef 0.070 bcde 79.1 abc 5.4 bcde 0.34 abcd 0.807 abc 105.3 cde 2.9 bcd 31.2 bcde 5.8 ef 42.8 f 73.2 e 217.7 g 1.21 i 3.7 hi 87.5 abc 0.027 f 41.5 ab 1.1 cd 6.7 f 0.028 fg 117.5 d 3.3 de 0.53 abcdef 0.797 abcd 46.0 gh 3.8 def 26.9 cdefg 7.9 cdef 278.8 a 95.4 a 115.9 ab 2.59 a 16.0 a 57.9 ab 0.051 abcdef 37.7 ab 1.9 bcd 34.6 ab 0.099 abc 63.0 a 6.2 abcd 0.38 ab 0.824 a 184.2 a 2.0 ab 25.9 cdefg 9.2 abcd 134.0 cd 92.3 a 113.0 a 2.31 bc 8.8 cdef 66.1 ab 0.071 a 45.5 abc 3.3 ab 15.4 cdef 0.057 cdefg 89.9 abcd 5.1 bcde 0.36 abcdef 0.825 a 78.4 def 4.2 ef 27.3 cdefg 9.8 abc 47.2 ef 88.4 abc 116.4 ab 2.00 de 4.0 hi 83.9 abc 0.031 ef 28.8 ab 0.9 d 8.5 ef 0.059 cdef 93.1 abcd 5.4 bcde 0.35 ef 0.805 abc 69.0 fg 3.0 bcd 26.6 cdefg 10.8 abc 167.0 bc 90.5 ab 221.8 g 1.30 hi 11.2 cd 75.3 abc 0.050 abcdef 28.4 ab 1.3 cd 34.6 ab 0.080 bcd 73.3 abc 5.9 abcd 0.41 abcde 0.804 abc 134.8 bc 2.7 bcd 19.7 g 8.2 bcde 78.7 def 83.4 abc 207.3 g 1.55 gh 7.2 efgh 91.6 bc 0.049 abcdef 33.4 ab 1.6 cd 26.0 bc 0.058 cdefg 77.3 abc 4.4 bcde 0.66 cdef 0.775 cde 105.0 cde 2.9 bcd 31.6 bcde 8.7 bcde 37.1 f 86.8 de 265.6 h 0.96 j 2.5 i 65.8 ab 0.038 bcdef 46.4 abc 1.8 cd 12.6 def 0.021 g 102.7 bcd 2.1 e 0.62 f 0.766 ef 36.1 h 5.1 f 22.5 bcdef 11.4 ab 243.3 ab 89.7 abc 130.4 abc 2.42 ab 15.2 ab 63.9 ab 0.054 abcdef 47.1 abc 2.5 bc 38.2 a 0.128 a 74.4 abc 9.0 a 0.38 ab 0.779 bcd 163.5 ab 1.2 a 33.0 bcd 8.5 bcde 129 cde 89.5 abc 132.2 abcd 2.39 ab 7.9 cdefg 63.0 ab 0.055 abcde 40.5 ab 2.3 bc 22.6 bcd 0.089 bc 80.8 abcd 7.1 abc 0.46 abcdef 0.785 bcd 106.8 cd 2.8 bcd 23.8 defg 12.2 a 42.5 f 89.6 abc 120.4 ab 1.76 efg 3.3 i 76.0 abc 0.046 abcdef 46.4 abc 2.2 bcd 16.6 cdef 0.041 efg 107.8 cd 4.4 cde 0.64 ef 0.792 cd 64.9 fgh 3.6 cde 25.3 cdefg 9.9 abc Effects of drought treatment and species on photosynthetic parameters Because Pearson’s correlation analyses indicated that φ, k and RD were not correlated with other parameters, including RWC and g, these parameters were not considered further. Several parameters that were significantly correlated with g were also significantly correlated with other parameters (P < 0.001). Among these, ETR showed a highly significant negative cor- relation with NPQ, whereas Amax, ε and Γ were all strongly interrelated. Moreover, Amax, ε and Γ were significantly correlated with ETR. A summary of the ANOVA of the effects of treatment, species and treatment × species interaction on selected photosynthetic parameters is shown in Table 3. Drought significantly affected each parameter presented in Table 3, whereas the interspecific variation was only significant for RL and Fv /Fm. TREE PHYSIOLOGY ONLINE at http://heronpublishing.com 692 GULÍAS, FLEXAS, ABADÍA AND MEDRANO Table 2. Two-way ANOVA of the effects of treatment, species and treatment × species interaction on mid-morning stomatal conductance (g), predawn leaf relative water content (RWC), leaf mass area (LMA) and leaf nitrogen concentration on a dry mass basis ([N]). Parameter Treatment P-value Species P-value Treatment × species P-value g RWC LMA [N] < 0.001 0.104 0.077 < 0.001 0.044 0.059 < 0.001 < 0.001 0.024 < 0.001 < 0.001 < 0.001 The treatment × species interaction had a significant effect on all parameters presented in Table 3, except RL, suggesting species-dependent differences in the RL response to drought. Figures 3 and 4 show parameters that were significantly affected by treatment × species interaction. The response of AN to drought followed that of g (Figures 3A–C), except in drought-treated plants of R. ludovicisalvatoris, which maintained an almost constant AN in control plants and in plants subjected to mild drought (Figure 3A). Among species in the well-watered treatment, R. ludovicisalvatoris had the lowest intrinsic water-use efficiency (AN /g) (Figure 3D). In all species, AN /g increased with decreasing g and AN (Figures 3D–F), reaching maximum values in plants in the severe drought treatment. Among species in the mild and severe drought treatments, the highest AN /g values were found in R. alaternus and P. lentiscus, and the lowest values were found in P. terebinthus. Stomatal limitation (l ), calculated from AN –Ci curves, showed a similar pattern to that of AN /g (Figure 3G–I). Drought caused decreases in Amax (Figure 4A–C), ε (Figure 4D–F) and ETR (Figure 4G–I). The drought-induced declines in these parameters followed a similar pattern in all species, although the relative decreases were slightly higher in Figure 2. Relationship between predawn leaf relative water content (RWC) and mid-morning stomatal conductance (g) for: 䉮, Rhamnus ludovici-salvatoris; 䊊, R. alaternus; 䉭, Quercus ilex; 䉱, Q. humilis; 䊐, Pistacia lentiscus; and 䊏, P. terebinthus. Table 3. Two-way ANOVA of the effects of treatment, species and treatment × species interaction on the photosynthetic parameters found to correlate with stomatal conductance. Abbreviations: AN (µmol m –2 s –1) = net CO2 assimilation; A/g (µmol mol –1) = intrinsic water-use efficiency; Amax (µmol CO2 m –2 s –1) = light- and CO2-saturated photosynthesis; RL (µmol m –2 s –1) = the sum of photorespiration and mitochondrial respiration in the light; l (dimensionless) = stomatal limitation to photosynthesis; ETR (µmol m –2 s –1) = electron transport rate; Fv /Fm (dimensionless) = maximum quantum yield of Photosystem II. Parameter Treatment P-value Species P-value Treatment × species P-value AN AN /g Amax RL l ETR (NPQ) Fv /Fm < 0.001 0.025 < 0.001 0.004 0.010 < 0.001 0.031 0.266 0.201 0.191 0.024 0.089 0.244 0.015 < 0.001 0.027 < 0.001 0.069 0.007 < 0.001 < 0.001 the Quercus and Pistacia species (60–80%) than in the Rhamnus species (40–50%). Pigment composition and its relationship with photochemistry Some interspecific and treatment-dependent differences were observed in leaf pigment composition. Area-based total chlorophyll concentration differed markedly among species (Table 1), but variations between drought treatments were small. For the two Rhamnus species, there was a progressive increase in chlorophyll concentration paralleling the increase in soil water depletion; however, this could simply be a consequence of interannual differences. The total VAZ (sum of violaxanthin, antheraxanthin and zeaxanthin) pool as a proportion of chlorophyll concentration was species-dependent, but was hardly affected by the drought treatments (Table 1). All of the species had a drought-induced sustained DPS at predawn (Figure 5A), ranging from 0.12 to 0.23. Predawn DPS was related to low Fv /Fm only in the three shrub species, whereas the tree species maintained an Fv /Fm close to 0.8, irrespective of DPS (Figure 5A). A correlation between midmorning NPQ and DPS was observed when the six species were considered together (Figure 5B); however, there was no correlation between these parameters if only the Rhamnus species were considered. The two Rhamnus species had maximum DPS values even during irrigation. If only the four desiccation-avoiding species are considered, the correlation improves (r 2 = 0.67, P < 0.01). Maximum DPS was similar (0.8–0.9) for five of the study species, but was lower (0.65) for R. ludovici-salvatoris, which was also the only species that showed no increase in NPQ in response to drought, and high ETR even during severe drought (Figure 4G). Discussion Relationship between g and RWC The study species fell into two groups on the basis of their re- TREE PHYSIOLOGY VOLUME 22, 2002 DROUGHT AND PHOTOSYNTHESIS IN MEDITERRANEAN SPECIES 693 Figure 3. Drought effects on mean values of net CO2 assimilation (AN; A–C), intrinsic water-use efficiency (AN /g; D–F) and stomatal limitation (l; G–I) in the two Rhamnus species (A, D, G), the two Quercus species (B, E, H) and the two Pistacia species (C, F, I). Values are means ± SE of four replicates. Within a species and parameter, different letters indicate significant differences between treatments (P < 0.05). sponse to soil water depletion; dessication-tolerant species and dessication-avoiding species. Both Rhamnus species exhibited simultaneous decreases in g and RWC, which is typical of desiccation-tolerant species (Gucci et al. 1997, Martínez-Ferri et al. 2000). The Quercus and Pistacia species achieved 50% stomatal closure before showing a reduction in predawn RWC. This rapid stomatal response to soil drying may enable these species to delay dehydration so, at least with respect to this characteristic, they can be considered desiccation-avoiding species. Other studies have identified P. lentiscus (Tenhunen et al. 1987, Gucci et al. 1997), Q. humilis (Damesin et al. 1998, Schwanz and Polle 1998, Nardini and Pitt 1999) and Q. ilex (Sala and Tenhunen 1996, Damesin et al. 1998) as drought-avoiding species, although the latter species has also been described as desiccation-tolerant (Sala and Tenhunen 1994). The desiccation-avoiding trait may impose a serious constraint on the winter deciduous species P. terebinthus and Q. humilis, because it implies that they close their stomata rapidly at the onset of drought, thus severely limiting carbon assimilation during the summer. For the evergreen species, P. lentiscus and Q. ilex, this trait may not constrain year-round assimilation as much as it does in the two deciduous species because the evergreen species maintain photosynthetic activity during winter (Damesin et al. 1998, Joffre et al. 1999). These photosynthetic differences may explain why P. terebinthus is rare and limited to humid places (Castro-Díez et al. 1998), and why Q. humilis is absent in Mallorca and other arid Mediterranean zones (Ne’eman and Goubitz 2000). Desiccation tolerance in the Rhamnus species facilitates maintenance of high assimilation rates during the onset of water deficit. However, the disadvantage is that the plants desiccate progressively during the summer. In the present study, R. ludovici-salvatoris saplings lost 15% of leaf RWC in 5 days. During especially dry and long summers, survival of adult trees as well as seedlings may be threatened. Leaf photosynthetic capacity The photosynthetic characteristics of Mediterranean evergreen trees and shrubs are reported to be similar (Ehleringer and Mooney 1982). However, although we found that Amax was similar in well-watered plants of all the study species, the highest g, AN and ε were found in the tree species, and the highest intrinsic water-use efficiency (AN /g) was found in the shrub species. Our findings suggest that g and perhaps mesophyll conductance, but not photosynthetic capacity, were the main determinants of interspecific differences in AN (cf. Epron et al. 1995, Syversten et al. 1995). TREE PHYSIOLOGY ONLINE at http://heronpublishing.com 694 GULÍAS, FLEXAS, ABADÍA AND MEDRANO Figure 4. Drought effects on mean values of light- and CO2-saturated CO2 assimilation (Amax; A–C), apparent carboxylation efficiency (ε; D–F) and electron transport rate (ETR; G–I) in the two Rhamnus species (A, D, G), the two Quercus species (B, E, H) and the two Pistacia species (C, F, I). Values are means ± SE of four replicates. Within a species and parameter, different letters indicate significant differences between treatments (P < 0.05). Rhamnus ludovici-salvatoris was an exception among the study species, with both low maximum photosynthetic rates and intrinsic water-use efficiency under irrigation. Moreover, it had the highest light respiration rates, indicating a disadvantageous carbon balance and low electron-use efficiency. These photosynthetic characteristics imply that R. ludovici-salvatoris has relatively low resource-use efficiency, in addition to low rates of Amax. Together these ecophysiological characteristics could account for the low competitiveness of this species, even under favorable conditions, compared with the others studied. The adjustments in Amax and ε to drought were similar in all the species, suggesting that these non-stomatal limitations to photosynthesis do not determine interspecies differences in acclimation to arid conditions. This is consistent with the progressive increases in AN /g and l as drought progressed. Only P. lentiscus had a decrease in AN/g in response to severe drought, but this species had the lowest g (37 mmol H2O m –2 s –1), which may have been below the inflexion point of the response of AN/g to g (Martin and Ruiz-Torres 1992, Flexas et al. 2002). High values of AN/g (up to 120) have been measured in field-grown P. lentiscus at g values of 50 mmol H2O m –2 s –1 in midsummer (Flexas et al. 2001). Leaf photochemistry and xanthophyll cycle The relationship between midday DPS and NPQ differed between the desiccation-avoiding and desiccation-tolerant species. In the four desiccation-avoiding species, there was a high correlation between DPS and NPQ at mid-morning, as previously described for many species (Demmig et al. 1988, Johnson et al. 1993, García-Plazaola et al. 1997). However, this correlation was not observed in the two desiccation-tolerant Rhamnus species, which showed maximum DPS regardless of their water status. Similar findings have been reported by Munné-Bosch and Alegre (2000) for the Mediterranean species Lavandula stoechas L. However, the two Rhamnus species showed distinct de-epoxidation patterns. Among the study species, R. alaternus had the highest DPS values, and increased NPQ in response to drought. We hypothesize that, in this species, as in L. stoechas (Munné-Bosch and Alegre 2000), a high DPS, even in well-watered plants, represents a strategy for coping with rapidly induced (days to weeks) drought events typical of Mediterranean climates. In contrast, R. ludovici-salvatoris had the lowest de-epoxidation capacity among the study species, which was accompanied by low NPQ and, consequently, a high electron transport rate even TREE PHYSIOLOGY VOLUME 22, 2002 DROUGHT AND PHOTOSYNTHESIS IN MEDITERRANEAN SPECIES 695 Conclusions We analyzed several photosynthetic characteristics and their response to drought in Rhamnus ludovici-salvatoris, an endemic shrub of the Balearic Islands that is declining in distribution, and compared the values with those of several widely distributed species. We found that R. ludovici-salvatoris displayed several traits that limit plant biomass production under semi-arid conditions, including high ratios of respiration and photorespiration to photosynthesis and a low intrinsic water-use efficiency that was not linked to a high photosynthetic rate. Stomatal closure at the onset of water deficit was also delayed in this species. Moreover, among the six study species, R. ludovici-salvatoris had the lowest de-epoxidation state of the xanthophyll cycle and the lowest thermal dissipation. These unfavorable photosynthetic traits may result in lower carbon gains under favorable conditions, a lower capacity to adjust photosynthesis under drought conditions, and lower photoprotection ability even during drought, compared with the other study species. It is well known that anthropogenic factors account for most landscape degradation in the Balearic Islands (Morey and Martínez 2000). Thus, the photosynthetic traits displayed by R. ludovici-salvatoris may contribute to its low rates of establishment and recovery after degradation. The deciduous species studied did not display the same photosynthetic traits as R. ludovici-salvatoris, therefore, their low distribution in the Balearic Islands is probably related to the absence of carbon gain during winter. In addition, their droughtavoiding characteristics will strongly limit their ability to accumulate carbon during summer in arid locations. Figure 5. (A) Relationship between predawn Fv /Fm and predawn deepoxidation state of the xanthophyll cycle (DPS) for the six species studied. Separate correlations are shown for microphyll trees and nanophyll shrubs. (B) Relationship between mid-morning NPQ and mid-morning DPS for the six species studied. Separate correlations are shown for drought-avoiding species and drought-tolerant species. Each value is the mean of six measurements. Symbols: 䉮, Rhamnus ludovici-salvatoris; 䊊, R. alaternus; 䉭, Quercus ilex; 䉱, Q. humilis; 䊐, Pistacia lentiscus; and 䊏, P. terebinthus. Acknowledgments This work is part of Projects CICYT PB97-1174 and PB97-1176, supported by the Spanish Ministry of Education and Science. J.F. was supported by the UIB with a Beca d’Investigació. J.G. was supported by the Project FEDER IFD97-0551. We are indebted to Dr. E. Descals and to Dr. M. Ribas-Carbó for grammar corrections. References during severe drought with almost no CO2 assimilation. This might explain the sustained high photorespiration rates of R. ludovici-salvatoris under drought conditions. The three shrub species showed some degree of permanent photoinhibition under drought conditions, as assessed by decreased predawn Fv/Fm, which was correlated with droughtinduced sustained DPS during the night, as previously observed in other Mediterranean sclerophyll species (Demmig et al. 1988, Martínez-Ferri et al. 2000). This suggests that a highly efficient, long-lasting photoprotective mechanism, rather than photodamage, was responsible for decreased Fv /Fm in the shrub species. In contrast, the tree species had a constant Fv /Fm irrespective of drought. Constant Fv /Fm values were also found in the two Quercus species even when drought completely stopped photosynthesis (Damesin and Rambal 1995, Méthy et al. 1996). 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