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Springer-Verlag 1997 Trees (1997) 11: 363 – 369 O R I G I N A L A RT I C L E Eduardo A. de Mattos ? Thorsten E. E. Grams Erika Ball ? Augusto C. Franco ? Angela Haag-Kerwer Britta Herzog ? Fabio R. Scarano ? Ulrich Lüttge Diurnal patterns of chlorophyll a fluorescence and stomatal conductance in species of two types of coastal tree vegetation in southeastern Brazil Received: 29 April 1996 / Accepted: 14 November 1996 AbstractmDiurnal measurements of chlorophyll fluorescence parameters and stomatal conductance to water vapour were carried out in five woody species and a bromeliad from two coastal vegetation types in Brazil, the rock outcrop of Pão de Açúcar and the sand dunes of Macaé. The environmental conditions of both study sites are characterized by high temperatures and light levels. The studied species comprised C3 plants with different degrees of stomatal closure during the day, overall daily stomatal conductance and a plant with a typical CAM pattern. Plants on Pão de Açúcar exhibited only a small decline in potential quantum yield throughout the day. The nonphotochemical quenching and the approximate photosynthetic electron transport rates were maximal during the peak of irradiance. In Macaé, light response curves of fluorescence parameters in the CAM-tree Clusia hilariana showed a clear differentiation between phases III and IV of CAM. In phase III, decarboxylation of organic acids probably maintained high internal CO2 levels and there was only a small decrease in photochemical quenching with saturating light levels. In phase IV, the depletion of the organic acid E.A. de Mattos Departamento de Botânica, Universidade Federal de São Carlos, caixa postal 676, São Carlos, SP, 13565-090, Brazil T.E.E. Grams1 ? E. Ball ? A. Haag-Kerwer2 ? B. Herzog U. Lüttge ( ) Institut für Botanik, Technische Hochschule Darmstadt, Schnittspahnstrasse 3 – 5, D-64287 Darmstadt, Germany A.C. Franco Departamento de Botânica, Universidade de Brası́lia, caixa postal 04631, Brası́lia, DF 70919-970, Brazil F.R. Scarano Departamento de Ecologia, Universidade Federal do Rio de Janeiro, Rio de Janeiro, RJ 21941-970, Brazil Present address: GSF-Forschungszentrum für Umwelt und Gesundheit, Expositionskammern, Ingolstaedter Landstrasse 1, D-85764 Oberschleissheim, Germany 2 Botanisches Institut, Ruprecht-Karls-Universität, Im Neuenheimer Feld 360, D-69120 Heidelberg, Germany 1 pool and low stomatal conductances resulted in much lower levels of effective quantum yield and a substantial increase in both 1-qP and non-photochemical quenching with increasing light levels. This behaviour during phase IV in the CAM-tree C. hilariana was comparable to the performance of the C3-Clusia C. aff parviflora at Pão de Açúcar. It is seen that both the C3 species and the CAM tree occurring in the two coastal communities effectively adjust their photochemical efficiency to environmental conditions and especially to diurnal variations of stress. Key wordsmChlorophyll fluorescence ? Stomatal conductance ? Rock outcrops ? Sand dune formations Photosynthesis diurnal changes ? Introduction Evaluations of chlorophyll a fluorescence have been used to describe and detect the effects of multiple environmental stresses in plants of diverse habitats (Demmig-Adams et al. 1989, Lovelock et al. 1994; Larcher 1995), and as pointed out by Ball et al. (1995) the functioning of photosystem II (PS II) is one of the most sensitive indicators of environmental stress in plants. Plants occurring in environments of high irradiance are more prone to photoinhibition, i.e., a sustained decrease in the efficiency of photosynthetic energy conversion, when high quantum fluxes are concomitant with other kinds of stress, such as water deficit, nutrient depletion or extremes of temperature (Demmig-Adams and Adams 1992; Osmond 1994). Photoinhibition develops when the capacity of the photosynthetic apparatus to utilize the excitation energy reaching the photosynthetic reaction centres or to avoid excess excitation is limited or reduced. Over the course of a day, a reversible decline in PS II efficiency is generally accompanied by an increase in nonradiative energy dissipation. This protects the photosystems against irreversible damage. The larger fraction of energy dissipated before it reaches the PS II centres is thought to be mediated by an increase in the xanthophyll cycle-dependent 364 energy dissipation in the light-harvesting antennae (Demmig-Adams 1990). In terms of comparative ecophysiology of tropical plants it is important to investigate how species are able to cope with the high light levels that are common in these habitats. For most of the atlantic coast of southeastern Brazil the presence of rock outcrops and sand dune formations is characteristic. The plants occurring in these areas are often subjected to high light levels and water shortage. In this report, with focus on the trees of these vegetation types we aim to address the following questions: (1) Are different modes of photosynthesis (C3 or CAM) expressed among trees ? (2) How are the species equipped to adjust their stomatal conductance and photochemical efficiency to environmental conditions and especially potential diurnal variations of stress ? Materials and methods Study site and plant material Field studies were conducted on the rock outcrop of Pão de Açúcar (22° 579S, 43° 599W) in the municipality of Rio de Janeiro and in the Cabiúnas sand dune formation (22° 149S, 41° 349W) in the municipality of Macaé, approximately 200 km NE of the city of Rio de Janeiro. The distribution of plants in both types of vegetation is characterized by the presence of hemispherical clumps of different sizes. In the case of Pão de Açúcar the size of the clumps is more or less related to the inclination of the rock and some species (as atmospheric bromeliads “sensu” Pittendrigh 1948) have the capacity of establishment directly on bare rock. Clusia aff parviflora Saldanha & Engl. (Clusiaceae) and Stilingia dichotoma Muell. Arg. (Euphorbiaceae) are the most abundant trees. Vriesia geniculata (Wawra) Wawra (Bromeliaceae) is one of the most common tank bromeliads in this type of habitat. It is found on bare rock of low inclination, on the border or underneath the hemispherical clumps of trees like C. aff parviflora (Meirelles et al. 1996a). Annual rainfall is about 1500 mm and mean air temperature is 24 °C (Niemer 1979). Clusia hilariana Planchon & Triana (Clusiaceae) is the dominant woody species in the sand dune formation of Cabiúnas. This species forms hemispherical clumps with other trees like Protium icicariba (DC) March and Andira legalis (Vell. Conc.) Toledo (Henriques et al. 1986). In contrast to Pão de Açúcar the climate is characterized by a dry period from June to August and a mean annual rainfall of 1164 mm, whereas mean air temperature is 22.6 °C (Henriques et al. 1986). obtained with a NiCr-Ni thermocouple pressed against the lower leaf surface. The chlorophyll a fluorescence measurements were performed with a pulse-amplitude modulation fluorometer (PAM 2000, Walz, Effeltrich, Germany). The leaf was kept at a constant distance (ca. 1 cm) and angle (60 °) to the fiber optics by the leaf clip that comes with the instrument. Measurements of light intensity close to the leaf surface were taken by a micro-quantum sensor calibrated against a LI-COR quantum sensor (Neb., USA). For measurements of fluorescence parameters in the light adapted state care was taken not to shade the leaves by the fibre optics and the leaf clip. Readings of potential quantum yield of photosystem II (Fv/Fm) were taken on a different set of leaves following a 10 min dark period. This time interval was checked to be sufficient to relax all fast components of total nonphotochemical quenching (qN) prior to the measurements. qN, photochemical quenching (qP) and the term 1-qP, which was used as a measure of the reduction state of QA, the primary electron acceptor of photosystem II (PSII), were calculated according to van Kooten and Snel (1990). The pre-dawn measurements of maximum fluorescence (Fm) and ground-level fluorescence (Fo) were used to calculate these quenching parameters. The effective quantum yield of PSII (∆F/F9m) was calculated as (F9m-F)/F9m, where F is fluorescence of the lightadapted sample and F9m is the maximum light-adapted fluorescence when a saturating light pulse of 600 ms duration is superimposed to the prevailing environmental light levels (Schreiber and Bilger 1993). Approximate rates of photosynthetic electron transport (ETR) were obtained as ∆F/F9m × PPFD and Stern-Volmer non-photochemical quenching (NPQ) was calculated as NPQ = (Fm-F9m)/F9m. A correction for changes in the temperature of the PAM-2000 that affected the output of the measuring beam over the course of the day was applied to the fluorescence data (Bilger et al. 1995). In addition to diurnal measurements, light response curves were performed with readings on individual leaves during different times of the day to examine the potential effects of reduced gH2O in the middle of the day or different phases of CAM on ∆F/F9m, qN and 1-qP. Leaves adjacent to the ones that were used in the transpiration and fluorescence measurements were collected for biochemical analyses at dawn and dusk. The leaves were enclosed in plastic bags and immediately stored on ice for 1 – 2 h, until it was possible to transport the samples to the field station where the fresh weight of the leaves was determined and the material was dried in a microwave oven for subsequent measurements of dry weight, titratable protons, malate, citrate and carbon isotope composition. Prior to organic acid determinations, the material was boiled in distilled water. Malate and citrate were determined enzymatically according to Hohorst (1965) and Möllering (1985), respectively. Composite samples of the dry leaf material of exposed and shade plants were ground for carbon isotope analysis and combusted in an oxygen bomb. Carbon isotope ratios were determined as described by Osmond et al. (1975). Results Gas exchange, chlorophyll a fluorescence and biochemical analyses Transpirational loss of water vapour from the leaves was determined with a portable gas exchange system (CID, Vancouver, USA). Measurements were carried out with six mature leaves of three individuals of each species studied. The CID system uses dew point sensors to monitor changes in relative humidity (RH), an infra-red thermometer to measure leaf temperature (Tleaf) and a thermistor to measure air temperature (Tair). These parameters were used to calculate leaf conductance to water vapour (gH2O). The high humidity levels prevented a reasonable estimate of gH2O during most of the night period. At each sampling time the leaf remained clamped in the porometer chamber for 1 – 2 min. Air temperature and relative humidity were measured with a portable Cole-Parmer thermohygrometer (Niles, USA) and photosynthetic photon flux density (PPFD) with a silicium photodiode calibrated against a LI-COR (Neb., USA) quantum sensor. In addition to the measurements of leaf temperature by the infra-red thermometer of the porometer chamber, leaf temperatures were also Diurnal patterns of environmental variables and stomatal conductance Figure 1 depicts environmental variables measured on the rock outcrop of the Pão de Açúcar and in the sand dunes of Macaé. There were differences in the pattern of PPFD between the two localities. Because the plants studied are located at the bottom of the Pão de Açúcar, the inselberg itself affected the radiation level reaching the plants. Thus, light intensity changed very abruptly in the early morning and in the early afternoon on Pão de Açúcar (Fig. 1A), but not in the sand dune site (Fig. 1B). Relative humidity reached lower values in the sand dunes of Macaé. Although air temperature was somewhat variable at Pão de Açúcar 365 Fig. 1mDaily courses of environmental conditions, photosynthetic photon flux density (PPFD) at a plane surface, relative air humidity (RH) and air temperature (Tair) on 8 August 1994 at Pão de Açúcar (A) and on 16 August 1994 at Macaé (B) maximum values were comparable to those from Macaé, where maximal values of about 32 °C occurred between 1000 to 1200 hours (Fig. 1). The daily pattern of gH2O of all species studied at the two sites was typical for the C3 photosynthetic pathway (Fig. 1A – C and E – F), except in C. hilariana in the sand dunes of Macaé which showed a clear CAM pattern with the four typical CAM phases (Fig. 1D). Maximum leaf temperatures (Tleaf) and leaf to air vapour pressures (VPD) reached during the days of measurements together with other leaf characteristics of the C3 species are given in Table 1. At Pão de Açúcar gH2O of the plants increased in the morning and declined again during the middle of the day with some recovery later in the afternoon. By contrast to the Pão de Açúcar site gH2O of the C3 plants at Macaé was already high in the early morning, but again there was a tendency of a decline of gH2O during the hotter and drier times of the day. The differences in early morning gH2O between the two sites may be due to the differences in PPFD at this time of the day (Fig. 1). At Pão de Açúcar maximum Tleaf and VPD varied to some extent among the three plants studied, and this was correlated with the minimum gH2O reached at the middle of the day, i.e. between shortly before 1200 and 1300 hours. At Macaé maximum VPD was more similar for the two plants and minimum gH2O was identical (Table 1). The three day-time phases of the CAM-type pattern of gH2O, i. e. some stomatal opening in the morning and in the afternoon and stomatal Table 1mSome characteristics of leaves with C3-photosynthesis-type pattern of gH2O studied at the two sites. Tleaf-max (°C) and VPD-max (kPa ? MPa–1) are the maximal leaf temperatures and leaf to air vapour pressure differences, respectively, reached during the day; gH2O-min (mmol ? m–2 ? s–1) is the minimal leaf conductance to water vapour attained during times of maximal Tleaf and VPD; gH2O-int (mol- closure in the middle of the day (Osmond 1978), in C. hilariana can be better demonstrated when additional data from 15 August are plotted together with the measurements carried out on 16 August, even though the leaf to air VPD of the previous day was clearly lower (Fig. 2D). During the phase III stomatal closure in the middle of the day leaf temperatures reached 38 °C (not shown). Leaf characteristics and organic acid levels None of the five species with a C3-photosynthesis type pattern of gH2O (Fig. 2A – C, E – F; Table 1) showed any significant day-night oscillations of organic acids (malate and citrate), nor any substantial changes in the amount of titratable protons (data not shown). It is interesting to note, however, that for C. aff parviflora the citrate levels were relatively high, i.e. about 90 mmol m – 2, but without significant variation in dawn/dusk levels, and malate levels were below 10 mmol m – 2 as in the other four species (data not shown). The carbon isotope signatures of all the five species were typical of the C3 photosynthetic pathway. Conversely, C. hilariana showed the pronounced day/ night oscillations of organic acid levels, which are characteristic of CAM (Table 2). Both levels of malate and citrate participated in these oscillations as commonly observed in CAM species of the genus Clusia (Franco et al. 1992; Haag-Kerwer et al. 1992; Lüttge 1988). The carbon isotope ratio of the dried leaf material was – 14.36 , i.e. % m–2 ? day) is the integrated stomatal conductance for the daily courses given in Fig. 1; δ13C (‰) is carbon isotope ratio of dried leaf material; FW/A (g ? m–2) is the fresh weight to area ratio. Numbers in brackets for VPD-max, gH2O-min and FW/A are the standard deviations for n = 6 leaves Sites and species Tleaf-max VPD-max gH2O-min gH2O-int δ13C FW/A Pao de Acucar C. parviflora S. dichotoma V. geniculata 30.7 36.3 39.1 24 (4) 39 (4) 49 (6) 138 (38) 82 (59) 31 (20) 3371 2942 2049 –30.12 –26.89 –25.72 535 (15) 490 (15) 590 (70) Macaé P. icicariba A. legalis 40.7 42.5 49 (3) 56 (9) 160 (28) 161 (14) 7046 6040 –29.76 –26.27 238 ( 7) 278 (20) 366 Fig. 2mDiurnal changes in leaf conductance to water vapour (gH2O) and leaf to air vapour pressure difference (VPD) for the studied species in both localities and on the 2 days presented in Fig. 1. For C. hilariana (D) closed symbols give additional data obtained on 15 August 1994. Vertical bars indicate standard deviations much less negative than for the other five species (Table 1) and also typical of CAM. These data confirm the conclusion drawn from the daily pattern of gH2O that C. hilariana is a CAM performing plant in the sand dunes of Macaé. Its degree of succulence, i.e. FW/A ratio was also much higher than for the other five species; with 1390 85 g m– 2 (SD, n = 6) FW/A in C. hilariana was about 2.5 fold the value obtained for the other Clusia species studied, the C3 species C. aff parviflora at Pão de Açúcar, showing the increased succulence typical of CAM leaves. + Diurnal course of chlorophyll a fluorescence in the plants on Pão de Açúcar Plants on the Pão de Açúcar exhibited only a small decline of the Fv/Fm ratio throughout the day (Fig. 3). The ratio of variable to maximal fluorescence (Fv/Fm) remained fairly constant, around 0.80, all day long in C. aff parviflora whilst S. dichotoma showed slightly lower mean values, i.e. Table 2mDawn and dusk analyses of malate and citrate (mmol ? m–2) for C. hilariana at Macaé. The values are presented as average of six leaves with standard deviations in brackets Dawn Dusk Dawn minus dusk Malate Citrate 286 (40) 45 (12) 241 (30) 164 (10) 68 (20) 96 (16) 0.78, and in V. geniculata there was a decrease from 0.80 to about 0.73 at midday. Although Clusia aff parviflora was exposed to slightly lower mean irradiance levels during the middle of the day, it presented a similar reduction in ∆F/F9m as observed in V. geniculata (lowest values around 0.20). In contrast, leaves of S. dichotoma did not show values of ∆F/F9m below 0.26. These differences were enough to cause large differences in the photosynthetic electron transport rates (ETR) between the three species. Thus, S. dichotoma showed the highest rates of photosynthetic activity as given by ETR (around 660 42 µmol m – 2 s – 1). In contrast, maximum ETR were around 350 127 and 400 68 µmol m – 2 s – 1 for C. aff parviflora and V. geniculata, respectively. With regard to the capacity for energy dissipation, the highest values of both total non-photochemical quenching (qN) and Stern-Volmer equation (NPQ) were found in Clusia aff parviflora (Fig. 3). The lowest capacity for energy dissipation in the pigment bed of PSII was measured on V. geniculata, (NPQ = 3.1 1.4), but only slightly lower than for S. dichotoma (NPQ = 3.4 1.0). It is interesting to note that the differences were slightly higher if they were based on NPQ instead of qN. In both Clusia aff parviflora and S. dichotoma qN started to increase faster than NPQ during the morning. However, this was not the case for V. geniculata. Maximum average levels of the reduction state of the primary electron acceptor, QA, estimated as 1-qP, were 0.52 0.22 in C. aff parviflora, 0.40 0.01 in S. dichotoma and 0.56 0.23 in V. geniculata. + + + + + + + + 367 Light response curves of fluorescence parameters of the C3Clusia and the CAM-Clusia Figure 4 depicts the light response curves for some of the chlorophyll a fluorescence parameters in the C3-Clusia C. aff parviflora at Pão de Açúcar and the CAM-Clusia C. hilariana at Macaé. Light response curves for chlorophyll a fluorescence parameters of C. hilariana during phases III and IV of CAM were substantially different (Fig. 4B). A more pronounced drop of ∆F/F9m with increasing PPFD was observed in phase IV in comparison to phase III. At a PPFD of around 1600 µmol m – 2 s – 1 the value observed during phase IV was approximately 4-fold lower than the lowest value measured in phase III. In contrast, qN values were substantially higher in phase IV. In response to increasing light levels qN in phase IV rapidly approached saturation values of about 0.90 at PPFD levels around 750 µmol m – 2 s – 1. The maximum value of qN in phase III was about 0.50 at the highest PPFD level (about 1600 µmol m – 2 s – 1). High light intensities resulted in only a small increase in 1-qP in phase III (maximal average values around 0.30). However, 1-qP began to increase clearly at PPFD above 250 µmol m–2 s – 1 and reached the highest value (0.80) at about 2100 µmol m – 2 s – 1 in phase IV. As known from studies with other CAM plants (Winter and Demmig 1987; Guralnick et al. 1992) including other CAM species of Clusia (Winter et al. 1992; Franco et al. 1996) these differences between CAM phases are due to the fact that in phase III photosynthesis occurs at high internal CO2 concentrations built up behind closed stomata due to decarboxylation of organic acids while in phase IV CO2 is obtained from the atmosphere via open stomata as in C3photosynthesis. Indeed, the light response curves of fluorescence parameters obtained from the C3-Clusia C. parviflora between 1000 – 1300 hours (Fig. 4A) when gH2O was Fig. 3mDiurnal time courses of photosynthetic photon flux density at the leaf level (PPFD), potential quantum yield (Fv/Fm), effective quantum yield (∆F/F9m), apparent electron transport rate (ETR), the reduction state of the primary electron acceptor of photosystem II (1-qp), total non-photochemical quenching (qN) and Stern-Volmer nonphotochemical quenching (NPQ) from sun leaves of C. parviflora, S. dichotoma and V. geniculata at Pão de Açúcar on 8 August 1994. Vertical bars indicate standard deviations high and almost constant (Fig. 2A) are much more closely comparable to those of phase IV than to those of phase III in C. hilariana. Discussion There were clear differences in the diurnal patterns of gH2O among the species in the two coastal habitats. Their performance comprised C3 patterns with different values of integrated stomatal conductance, gH2O-int, over the day and with gH2O declining by various degrees towards midday and a typical CAM pattern (Fig. 2; Tables 1, 2). In the C3 species both at Pão de Açúcar and at Macaé the carbon isotope ratio was in tendency correlated with the degree of stomatal aperture, i.e., those species showing lower values of daily integrated gH2O also showed lower 13C discrimination (less negative δ13C values; Table 1). Less negative values for the carbon isotope ratios would be indicative of higher water use efficiency (WUE) of carbon assimilation or at least may indicate a lower operational range for the ratio between CO2 concentration at sites of evaporation within substomatal cavities to the CO2 concentration in bulk air (Farquhar et al. 1989). 368 Fig. 4mLight response curves of effective quantum yield (∆F/F9m), total non-photochemical quenching (qN) and the reduction state of the primary electron acceptor of photosystem II (1-qP) for C. parviflora (A) at Pão de Açúcar and C. hilariana (B) at Macaé. For C. parviflora open and closed symbols represent two separate measurements on two different leaves taken between 1000 and 1300 hours and the line drawn indicates the average; for C. hilariana open symbols are measurements during phase III of CAM (1400 – 1500 hours) and closed symbols are measurements during phase IV of CAM (1700 – 1800 hours) performed on one leaf. Squares are ∆F/F9m, circles qN and triangles 1-qP Differences in the degree of control of gH2O between the studied species were observed after some rainy days. Hence, regardless of the differences in substrate between the granitic outcrop and the sand dune vegetations, we cannot explain the different patterns of gH2O by the establishment of a pronounced soil water deficit. However, leaf temperatures and leaf to air VPD reached fairly high values during the middle of the day. Several investigations have shown depression of leaf gas exchange in plants growing in hot and arid environments, during periods when leaf temperatures and leaf to air VPD are greatest (Mooney et al. 1975; Tenhunen et al. 1981; Roessler and Monson 1985). In this study, in C3 plants growing on the granitic outcrop of Pão de Açúcar, we observed a close relationship between ETR and NPQ, which could keep the reduction state of QA on the safe side even during some midday depression of gH2O, as evidenced by high Fv/Fm values during the day. Demmig-Adams et al. (1989) in water stressed plants of Arbutus unedo, observed marked reductions in Fv/Fm concomitantly with increased levels of non radiative energy dissipation during midday depression of gH2O and net CO2 uptake. However, this decline was reversible and at the end of the day Fv/Fm showed a pronounced recovery reaching the values prior to the midday depression. These results suggests that the controlled utilization or dissipation of a high excitation pressure within PS II, which can lead to a high degree of reduction state of QA, the primary electron acceptor of PS II, may prevent irreversible damage to the photosynthetic apparatus by high irradiance. In CAM plants, as observed by Adams et al. (1989) in three species of cacti in northern Venezuela and Franco et al. (1996) in exposed leaves of seedlings of C. hilariana in natural conditions, the phase IV of CAM seems more prone to sustained decreases in Fv/Fm. Some authors have postulated that nocturnal accumulation of organic acids in CAM plants may alleviate photoinhibition (Franco et al. 1992; Haag-Kerver et al. 1992 Maxwell et al. 1992). The light response curves presented here showed a clear differentiation between phase III and phase IV of CAM in C. hilariana, when higher 1-qP and qN were observed in this latter phase. It is believed that as the organic acid decarboxylation during phase III raises the internal CO2 concentration, a higher photosynthetic electron use should help to maintain a low reduction state of QA even at high PPFD levels. During phase IV, lower values for ∆F/F9m and the increase in qN and 1-qP at high PPFD levels in C. hilariana may be explained by the depletion of the organic acid pool. The capacity to ordered use and/or safe dissipation of excitation energy may be limited at high PPFD approaching full sunlight when 1-qP values greater than 0.50 were measured for some of the studied species. It is interesting to note that the small declines observed in photochemical efficiency occurred without soil water deficit. Both vegetation types are probably more subjected to some limitation of water availability mainly during the hot summers that are characteristic of this part of Brazil. Over the summer, even 1 or 2 weeks without rain are enough to elicit leaf rolling and dehydration of small clumps of desiccation tolerant species on rock outcrops of southeastern Brazil (Meirelles et al. 1996b). In conclusion, it seems clear from this study that both the C3 species and the CAM plants occurring in these two coastal communities are able to effectively adjust their photochemical efficiency to environmental conditions. In wet soils these plants are apparently not prone to an irreversible damage of their photosynthetic apparatus induced by an intense photoinhibitory situation. However, these habitats are frequently subjected to high irradiance levels concomitantly with other environmental stress such as water deficits, high temperature and salinity. Further studies are necessary to address these questions. AcknowledgementsmWe thanks Escola de Comando e Estado Maior do Exército for providing us with logistic support in the Pão de Açúcar rock outcrop. 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