<i>Jatropha curcas</i>and<i> Ricinus
					communis</i>display contrasting photosynthetic mechanisms in response to
					environmental conditions

Lima Neto, Milton Costa; Martins, Marcio de Oliveira; Ferreira-Silva, Sérgio Luiz; Silveira, Joaquim Albenísio Gomes

doi:10.1590/0103-9016-2014-0325

Abstract

Higher plants display different adaptive strategies in photosynthesis to cope with abiotic stress. In this study, photosynthetic mechanisms and water relationships displayed byJatropha curcasL. (physic nuts) andRicinus communisL. (castor bean), in response to variations in environmental conditions, were assessed.R. communis showed higher CO₂ assimilation, stomatal and mesophyll conductance thanJ. curcas as light intensity and intercellular CO₂ pressure increased. On the other hand,R. communis was less effective in stomatal control in response to adverse environmental factors such as high temperature, water deficit and vapor pressure deficit, indicating lower water use efficiency. Conversely,J. curcas exhibited higher photosynthetic efficiency (gas exchange and photochemistry) and water use efficiency under these adverse environmental conditions.R. communisdisplayed higher potential photosynthesis, but exhibited a lowerin vivo Rubisco carboxylation rate (Vcmax) and maximum electron transport rate (Jmax). During the course of a typical day, in a semiarid environment, with high irradiation, high temperature and high vapor pressure deficit, but exposed to well-watered conditions, the two studied species presented similar photosynthesis. Losing potential photosynthesis, but maintaining favorable water status and increasing non-photochemical quenching to avoid photoinhibition, are important acclimation mechanisms developed byJ. curcas to cope with dry and hot conditions. We suggest thatJ. curcas is more tolerant to hot and dry environments thanR. communis but the latter species displays higher photosynthetic efficiency under well-watered and non-stressful conditions.

abiotic stress; castor bean; photosynthesis; physic nut; acclimation

Introduction

Photosynthetic performance in higher plants under adverse environmental conditions is largely dependent on plant species, which are able to trigger distinct adaptive mechanisms to deal with specific stressful conditions (Cousins et al., 2014Cousins, A.B.; Johnson, M.; Leakey, A.D.B. 2014. Photosynthesis and the environment. Photosynthesis Research 119: 1-2.). Plants display a set of acclimation strategies to maintain adequate photosynthesis rates in response to abiotic stress-inducers such as high temperature, drought and high light levels (Liu and Huang 2008Liu, X.; Huang, B. 2008. Photosynthetic acclimation to high temperatures associated with heat tolerance in creeping bentgrass. Journal of Plant Physiology 165: 1947-1953.;Chaves et al., 2009Chaves, M.M.; Flexas, J.; Pinheiro, C. 2009. Photosynthesis under drought and salt stress: regulation mechanisms from whole plant to cell. Annals of Botany 103: 551-560.;Gonzalez-Cruz and Pastenes, 2012Gonzalez-Cruz, J.; Pastenes, C. 2012. Water-stress induced thermotolerance of photosynthesis in bean (Phaseolus vulgaris). Enviromental and Experimental Botany 77: 127-140.). To reach their potential or maximum photosynthesis, plants employ a fine metabolic coordination involving several inter-related processes, especially a close balance between photochemical activity and Calvin cycle reactions (Goh at al., 2012Goh, C.H.; Ko, S.M.; Koh, S.; Kim, Y.J.; Bae, H.J. 2012. Photosynthesis and environments: photoinhibition and repair mechanisms in plants. Journal of Plant Biology 55: 93–101.).

Abiotic stresses are able to disturb this balance, and affect especially CO₂ assimilation due to stomatal and biochemical limitations (Adams III et al., 2013Adams III, W.W.; Muller, O.; Cohu, C.M.; Demmig-Adams, B. 2013. May photoinhibition be a consequence, rather than a cause, of limited plant productivity? Photosynthesis Research 117: 31-44.). The degree of preservation of adequate synchrony between light harvest, energy conversion in photosystems and CO₂ assimilation, under stress conditions, is species-dependent and important to plant productivity (Athanasiou et al., 2010Athanasiou, K.; Dyson, B.C.; Webster, R.E.; Johnson, G.N.; 2010. Dynamic acclimation of photosynthesis increases plant fitness in changing environments. Plant Physiology 152: 366–73.;Kramer and Evans, 2011Kramer, D.M.; Evans, J.R. 2011. The importance of energy balance in improving photosynthetic productivity. Plant Physiology 155: 70-78.;Murchie and Niyogi, 2011Murchie, E.H.; Niyogi, K.K. 2011. Manipulation of photoprotection to improve plant photosynthesis. Plant Physiology 155: 86–92.;Yamori et al., 2014Yamori, W.; Hisosaka, K.; Way, D.A. 2014. Temperature response of photosynthesis in C3, C4 and CAM plants: temperature acclimation and temperature adaptation. Photosynthesis Research 119: 101-117.).

In general, native species are able to survive under stressful environment conditions. These organisms are an important source of genes involved in stress tolerance and models for elucidating the steps that result in the limitation of photosynthesis efficiency. This feature is more relevant when these native plants have great agronomical potential likeJatropha curcasL. (physic nuts), a biofuel source of high quality (Achten et al., 2010Achten, W.M.J.; Maes, W.H.; Aerts, R.; Verchot, L.; Trabucco, A.; Mathijs, E.; Singh, V.P. 2010. Jatropha: from global hype to local opportunity. Journal of Arid Environments 74: 164-165.).

Ricinus communisL. (castor beans) is widely cultivated worldwide as a source of special non-edible oil (Barbour and Buckley, 2007Barbour, M.M.; Buckley, T.H.; 2007. The stomatal response to evaporative demand persists at night in Ricinus communis plants with high nocturnal conductance. Plant Cell and Environment 30: 711-721.). These species are C3 plants and display contrasting tolerances in response to abiotic stress (Aragão et al., 2012Aragão, R.M.; Silva, E.N.; Vireira, C.F.; Silveira, J.A.G. 2012. High supply of NO3-mitigates salinity effects through an enhancement in the efficiency of photosystem II and CO2 assimilation in Jatropha curcas plants. Acta Physiologiae Plantarum 34: 2135-43.;Babita et al., 2010Babita, M.; Maheswari, M.; Rao, L.M.; Shanker, A.K.; Rao, D.G. 2010. Osmotic adjustment, drought tolerance and yield in castor (Ricinus communis L.) hybrids. Environmental and Experimental Botany 69: 243–249.;Dai et al., 1992Dai, Z.; Edwards, G.E.; Ku, M.S. 1992. Control of photosynthesis and stomatal conductance in Ricinus communis L. (Castor Bean) by leaf to air vapor pressure deficit. Plant Physiology 99: 1426-1434.;Silva et al., 2012Silva, E.N.; Vieira, S.A.; Ribeiro, R.V.; Ponte, L.F.A.; Ferreira-Silva, S.L.; Silveira, J. A.G. 2012. Contrasting physiological responses of Jatropha curcas plants to single and combined stresses of salinity and heat. Journal of Plant Growth Regulation 32: 159–169.). However, in these studies, the focus was on one of the species’ response to isolated stresses. As an exception,Lima Neto et al. (2014)Lima Neto, M.C.; Lobo, A.K.M.; Martins, M.O.; Fontenele, A.V.; Silveira, J.A.G. 2014. Dissipation of excess photosynthetic energy contributes to salinity tolerance: a comparative study of salt-tolerantRicinus communis and salt-sensitiveJatropha curcas. Journal of Plant Physiology 171: 23–30. demonstrated thatJ. curcasand R. communisare contrasting in terms of salt tolerance and that the performance achieved by these species was related to distinct photosynthetic mechanisms. In this study, the photosynthetic mechanisms of the two species in response to different environmental conditions were compared.

Materials and Methods

Plant material

Jatropha curcas (L.) seeds, cultivar FT2, andRicinus communis(L.) seeds, cultivar BRS 149 (nordestina), were utilized. The seeds were previously selected by size and weight and germinated in sand. Fifteen days after germination, the seedlings were transferred to plastic pots (4 L) containing vermiculite as substrate. Plants were grown for 45 days under natural conditions in a greenhouse situated in a semiarid region in Fortaleza, in the state of Ceará, Brazil (3°44' S; 38°34' W; 31 m altitude) between Jan and Mar 2012. The averages of the environmental parameters inside the greenhouse over the experimental period were as follows: 29 °C / 24 °C mean/minimum temperature, 62 % relative humidity, 1500 µmol m⁻² s⁻¹ maximum photosynthetic photon flux density (PPFD) and 12 h photoperiod. The plants were watered every two days with 300 mL of half-strengthHoagland and Arnon (1950)Hoagland, D.R.; Arnon, D.L. 1950. The water culture method for growing plants without soil. UCLA, Berkeley, CA, USA. (California Agricultural Experimental Extension Circular, 347). nutrient solution.

Dry matter, water status and cell integrity

Leaves were harvested at the end of experiment and weighed at freshly picked weight, then dried until constant weight in drying chambers. The relative water content (RWC) was calculated from the fresh, turgid and dry weight of leaf discs, as previously based onLima Neto et al., 2014Lima Neto, M.C.; Lobo, A.K.M.; Martins, M.O.; Fontenele, A.V.; Silveira, J.A.G. 2014. Dissipation of excess photosynthetic energy contributes to salinity tolerance: a comparative study of salt-tolerantRicinus communis and salt-sensitiveJatropha curcas. Journal of Plant Physiology 171: 23–30.. The leaf pre-dawn water potential (Ψw) was evaluated immediately after sampling using the pressure chamber method (Scholander et al., 1965). Electrolyte leakage was assessed as described byLima Neto et al. (2014)Lima Neto, M.C.; Lobo, A.K.M.; Martins, M.O.; Fontenele, A.V.; Silveira, J.A.G. 2014. Dissipation of excess photosynthetic energy contributes to salinity tolerance: a comparative study of salt-tolerantRicinus communis and salt-sensitiveJatropha curcas. Journal of Plant Physiology 171: 23–30. through the electrical conductivity of the leaf extract.

Gas exchange measurements

Gas exchange was monitored and photochemical measurements taken in plants grown under natural conditions of temperature, vapor-pressure deficit (VPD) and PPFD inside a greenhouse. The third fully expanded leaf from the bottom to the top was monitored throughout the experiment. The net CO₂ assimilation rate (P_N), transpiration (E), stomatal conductance (g_s) and intercellular CO₂ partial pressure (C_i) were regularly monitored with a portable gas exchange system.

Net photosynthesis was measured in response to photosynthetic photon flux density (PPFD), leaf-to-air vapor-pressure deficit (VPD_leaf-to-air), leaf temperature and intercellular CO₂ partial pressure (C_i). Each of these conditions was separately isolated in the infrared gas analyzer (IRGA) leaf chamber. Changes in VPD were achieved by controlling the leaf and air temperature in the chamber, and the relative humidity through a drying column coupled to the IRGA. For the P_N-VPD response curve, gas exchange was measured after 20 min at each step (Young et al., 1997).

For instantaneous measurements, the PPFD was fixed at 1500 μmol m⁻² s⁻¹, 29 °C, a leaf-to-air vapor-pressure difference (VPD_leaf-to-air) between 1.0 and 1.5 kPa, and external CO₂ at atmospheric partial pressure (38 Pa). The P_N-PPFD and P_N-Ci curves were determined according toLieth and Reynolds (1987)Lieth, J.H.; Reynolds, J.F. 1987. The Nonrectangular hyperbola as a photosynthetic light response model: geometrical interpretation and estimation of the parameter θ. Photosynthetica 101: 363-366. andSharkey et al. (2007)Sharkey, T.D.; Bernacchi, C.J.; Farquhar, G.D.; Singsaas, E.L. 2007. Fitting photosynthetic carbon dioxide response curves for C3 plants. Plant, Cell & Environment 30: 1035-1040., respectively. For the P_N-PPFD curve (0 – 1800 µmol m⁻² s⁻¹), the VPD_leaf-to-air was controlled between 1.0 and 1.5 kPa, and external CO₂ at atmospheric partial pressure (38 Pa). For the P_N-Ci curve (0 – 160 Pa) the PPFD was fixed at 1500 μmol m⁻² s⁻¹ and VPD_leaf-to-air between 1.0 and 1.5 kPa. From these curves, several parameters were calculated including maximum photosynthetic rate (P_Nmax), maximum Rubisco carboxylation rate (V_cmax), maximum photosynthetic electron transport (J_max) and mesophyll conductance (g_m).

Chlorophylla fluorescence measurements, P700 activity and estimation of photorespiratory rate

In vivo chlorophyll fluorescence was measured using a LI-6400-40 leaf Chamber Fluorometer coupled to the IRGA. The fluorescence measurements were taken by means of the saturation pulse method (Schreiber et al., 1994Schreiber, U.; Bilger, W.; Neubauer, C. 1994. Chlorophyll fluorescence as a nonintrusive indicator for rapid assessment of in vivo photosynthesis. p. 49-70. In: Schulze, E.D.; Caldwell, M.M., eds. Ecophysiology of photosynthesis. Springer, Berlin, Germany.) in leaves exposed to light and 30 min-dark-adapted conditions. The intensity and duration of the saturation light pulse were 8,000 µmol m⁻² s⁻¹ and 0.7 seconds, respectively. The amount of blue light was set up to 10 % of the PPFD to maximize stomatal aperture (Flexas et al., 2007Flexas, J.; Diaz-Espejo, A.; Galmés, J.; Kaldenhoff, R.; Medrano, H.; Ribas-Carbo, M.; 2007. Rapid variations of mesophyll conductance in response to changes in CO2 concentration around leaves. Plant Cell and Environment 30: 1284-1298.).

The following parameters were assessed: (i) the maximum quantum yield of photosystem II (PSII) [F_v/F_M = (F_m-F_o)/F_m], (ii) the effective quantum yield of PSII [∆F/F_m’ = (F_m’- F_s)/F_m’], (iii) the non-photochemical quenching coefficient [NPQ = (F_m-F_m’)/F_m’], and (iv) the actual flux of photons driving photosystem II [ETR = (∆F/F_m’ x PPFD x 0.5 x 0.84)]. To evaluate the apparent electron transport rate at PSII level (ETR), 0.5 was used as the fraction of excitation energy distributed to PSII, and 0.84 was used as the fraction of incoming light absorbed by the leaves.

The F_m and F_o are the maximum and minimum fluorescence of dark-adapted leaves, respectively; F_m’ and F_s are the maximum and steady state fluorescence in the light-adapted state, respectively, and F_o’ is the minimum fluorescence after the far-red illumination of the previously light-exposed leaves (Schreiber et al., 1994Schreiber, U.; Bilger, W.; Neubauer, C. 1994. Chlorophyll fluorescence as a nonintrusive indicator for rapid assessment of in vivo photosynthesis. p. 49-70. In: Schulze, E.D.; Caldwell, M.M., eds. Ecophysiology of photosynthesis. Springer, Berlin, Germany.;Maxwell and Johnson, 2000Maxwell, K.; Johnson, G.N. 2000. Chlorophyll fluorescence: a practical guide. Journal of Experimental Botany 51: 659–668.). The estimation of the photorespiratory rate (P_R) was determined as described inBagard et al. (2008)Bagard, M.; Le Thiec, D.; Delacote, E.; Hasenfratz-Sauder, M.P.; Banvoy, J.; Gérard, J.; Dizengremel, P.; Jolivet, Y. 2008. Ozone-induced changes in photosynthesis and photorespiration of hybrid poplar in relation to the developmental stage of the leaves. Physiologia Plantarum 134: 559-574. from the measurements of gas exchange (P_N and R_d) and chlorophylla fluorescence-derived ETR parameter by the equation: P_R = 1/12[ETR-4(A+R_d)].

Statistical analysis and experimental design

The experiments were arranged in a completely randomized design with five independent replicates for each species consisting of an individual pot containing a plant. Data were analyzed using one–way ANOVA and means were compared using the t-test (p< 0.05) with SigmaPlot (Systat Software, San Jose, CA).

Results

In order to compare the photosynthetic characteristics ofJ. curcas andR. communis plants in response to adequate and stressful environmental conditions, we performed a set of individual experiments. These assays involved changes in gas exchange parameters in response to varying light intensity, CO₂partial pressure, temperature and a leaf-to-air vapor pressure deficit. Additionally, we reproduced the conditions of seasonal variation in the major parameters of PSII and gas exchange and made evaluations over a typical day in a semiarid region.

Light and CO2 response curves

The P_N-PPFD and P_N-Ci curves produced byJ. curcas andR. communis leaves showed a pattern typical of C3 plants (Figure 1A-B) adequate for fitting in the models proposed byLieth and Reynolds (1987)Lieth, J.H.; Reynolds, J.F. 1987. The Nonrectangular hyperbola as a photosynthetic light response model: geometrical interpretation and estimation of the parameter θ. Photosynthetica 101: 363-366. andSharkey et al. (2007)Sharkey, T.D.; Bernacchi, C.J.; Farquhar, G.D.; Singsaas, E.L. 2007. Fitting photosynthetic carbon dioxide response curves for C3 plants. Plant, Cell & Environment 30: 1035-1040.. All parameters calculated from these curves are presented inTable 1. The light compensation point ofR.communis plants was higher than inJ. curcas, indicating that the former species requires more light to produce a similar net CO₂assimilation, compared with the latter (Figure 1 andTable 1). When exposed to increasing light intensity,J. curcas andR. communis plants presented light saturation points close to 1000 and 1500 µmol m⁻² s⁻¹, respectively, with maximum CO₂ assimilation rates (P_Nmax) of 19 and 24 µmol m⁻² s⁻¹, respectively (Figure 1A,Table 1). These responses indicated thatR. communis is more able to use high light thanJ. curcas under well-watered conditions.

Figure 1
– Curves of (A) CO2 assimilation rates in response to increasing photosynthetic photon flux density, (B) to intercellular CO2 partial pressure and (C) stomata conductance in response to increasing photosynthetic photon flux density and (D) to intercellular CO2 partial pressure in young J. curcas and R. communis plants. For the PN/PPFD curve the CO2 partial pressure was maintained at (38 Pa) and in the PN/Ci curve of the PPFD was fixed at 1,500 μmol m−2 s−1. Each point represents the mean of five replicates (± SD). The standard deviation is shown when higher than the symbol.

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Table 1
– Parameters associated with photosynthetic efficiency calculated from the PN/PPFD and PN/Ci fitting curves inJ. curcas andR. communis plants grown under optimal conditions. Light Γ* is the light compensation point, PNmax the maximum CO2 assimilation rate, CO2 Γ* the CO2 compensation point, CO2 PNmax the maximum CO2 assimilation rate, Vcmax the maximum Rubisco carboxylation rate, Jmax the maximum photosynthetic electron transport rate, gm the mesophyll conductance, and PR the photorespiration rate. Each point represents the mean of five replicates. Different letters represent differences between species (t test (p< 0.05).

Increases in light intensity induced different responses in stomatal conductance (g_s) of the species studied. InR. communis, g_s rose steadily in response to the increasing light, while inJ. curcas the stomatal conductance was not dependent on light intensities above 150 µmol m⁻² s⁻¹, indicating that this species required only a narrow range of intensity of low light to trigger stomatal opening, whereasR. communis maintained its stomata opening over a wide range of light intensity (Figure 1C). In response to increases in the intercellular CO₂ partial pressure, g_s did not change in either species, butR. communis showed much higher values (by 3-fold) compared withJ. curcas(Figure 1D).

J. curcas presented a higher CO₂compensation point (by 45 %) compared withR. communis (Table 1) but, in contrast,R. communis showed a higher maximum CO₂ assimilation rate thanJ. curcasunder optimum external conditions. The maximum carboxylation rate of Rubisco (V_cmax), calculated from the P_N-Ci curves (Sharkey et al., 2007Sharkey, T.D.; Bernacchi, C.J.; Farquhar, G.D.; Singsaas, E.L. 2007. Fitting photosynthetic carbon dioxide response curves for C3 plants. Plant, Cell & Environment 30: 1035-1040.), was 58 % higher inJ. curcas compared withR. communis and a similar trend was found for the maximum rate of photosynthetic electron transport (J_max), which was approximately 33 % higher inJ. curcas plants (Table 1). Conversely, mesophyll conductance (g_m) was 157 % higher inR. communis compared withJ. curcas, whereas the photorespiratory rate (P_R) was approximately twofold higher inJ. curcas compared withR. communis (Table 1).

Taken together, these results indicate that photosynthesis inR. communis was more efficient in response to increases in both light intensity and CO₂ partial pressure compared withJ. curcas,where the other environmental factors were non-limiting. This higher level of photosynthetic efficiency was closely associated with higher stomatal and mesophyll conductance. In contrast,J. curcasseedlings exhibited higher efficiency in transporting electrons from the photosystems to the Calvin cycle and a higher turnover rate of Rubisco.

Photosynthetic responses to increasing temperature and leaf-to-air vapor pressure deficit

Plants of both species exposed to increasing leaf temperatures had maximum photosynthesis at approximately 30 °C (Figure 2A). However, increasing the leaf temperature from 35 °C to 40 °C resulted in a decrease of 30 % in the P_N inJ. curcasbut the P_N remained unchanged inR. communis (Figure 2A). The intercellular CO₂ (C_i) partial pressure decreased in both species from 22 °C to 28 °C and did not change from 28 °C to 39 °C (Figure 2B). This early decrease in Ci in both species was correlated with the increase in P_N until it reached maximum CO₂ assimilation (Figure 2A-B).

Figure 2
– (A) CO2 assimilation rates, (B) intercellular CO2 partial pressure, (C) transpiration rate and (D) stomatal conductance in response to increasing leaf temperature in young J. curcas and R. communis plants. The PPFD was fixed at 1,500 μmol m−2 s−1, VDPleaf-to-air between 1.0 and 1.5 kPa, and external CO2 at atmospheric partial pressure (38 Pa). Each point represents the mean of five replicates (± SD). The standard deviation is shown when higher than the symbol.

The transpiration rate was positively correlated with increases in leaf temperature for both species, butR. communisshowed higher transpiration rates at all temperatures (Figure 2C). The stomatal conductance (g_s) decreased steadily as the leaf temperature increased in both species. Overall,J. curcas showed a lower g_s compared withR. communis, indicating that the first one displays a more effective stomatal closing in response to increases in leaf temperature (Figure 2D).

Interestingly, when the leaf-to-air vapor-pressure deficit (VPD_leaf-to-air) increased from 1.0 to 5.5 kPa the P_N of both species did not change and both species had a similar increase in photosynthesis from 2.0 to 5.5 kPa (Figure 3A). In contrast to P_N, the C_ivalues were higher inR. communiscompared to J. curcas over the VPD range studied (Figure 3B). Transpiration rates and g_s were also comparatively higher inR. communisthan inJ. curcas, increasing almost linearly from 0.5 to between 2.0 kPa in both species and remained practically constant from 2.0 to 4.0 kPa (Figure 3C). Overall, the g_s displayed a similar trend compared with E when the VPD changed from 0.5 to 2.5 kPa. Beyond this the g_s decreased in both species from 2.5 to 5.5 kPa. However,R. communisexhibited higher g_s values thanJ. curcas in response to the VPD range studied (Figure 3D).

Figure 3
– (A) CO2 assimilation rates, (B) intercellular CO2 partial pressure, (C) transpiration rate and (D) stomatal conductance in response to increasing air VPD (kPa) in young J. curcas and R. communis plants. The PPFD was fixed at 1,500 μmol m−2 s−1 and external CO2 at atmospheric partial pressure (38 Pa). Each point represents the mean of five replicates (± SD). The standard deviation is shown when higher than the symbol.

The two species studied display contrasting responses to stomatal mechanisms regarding the changes in temperature and VPD (or heat and dry conditions).R. communisdisplayed a less effective mechanism to stomatal closure in response to heat and high VPD. However, the higher stomatal conductance shown by this species was not enough to allow CO₂ assimilation rates higher than those presented byJ. curcaswhen both species were exposed to water restrictive conditions. Thus, the latter species presents higher water use efficiency under stomatal restriction conditions compared withR. communis.

Changes in gas exchange and photosystem II parameters over a typical day in a tropical semiarid region

The variations in a number of gas exchange and photosystem II parameters were evaluated over a day in plants cultivated under natural conditions where VPD and PPFD changed as on a typical day in a hot and dry tropical semiarid region. Under these conditions, the air temperature and VPD varied from a minimum of 27 °C and 0.9 kPa, respectively, at 9h00, to a maximum of 35 °C and 2.0 kPa, respectively at 13h00, while the PPFD reached maximum values (~1800 µmol m⁻² s⁻¹) between 11h00 and 14h00 (Figure 4). Photosynthesis was similar forJ. curcas andR. communis, increasing slightly from 7h00 to 13h00 and decreasing afterwards. The decrease in P_N rate was directly correlated with the decrease in PPFD (Figure 5A).

Figure 4
– Changes in environmental parameters over a typical day in the greenhouse. (-•-) Air temperature, (-◊-) photosynthetic photon flux density (PPFD) and (--) vapor pressure deficit (VPD). Each point represents the mean of three independent measurements taken on different days. The standard deviation is shown when higher than the symbol.

Figure 5
– Daily courses of (A) CO2 assimilation rates, (B) intercellular CO2 concentrations, (C) transpiration rates and (D) stomatal conductance, in youngJ. curcas andR. communis plants. The average environmental parameters over the experimental period were as follows: 29 °C / 24 °C mean/minimum temperature, 62 % relative humidity, 1,500 µmol m−2 s−1 maximum photosynthetic photon flux density (PPFD). Each point represents the mean value of five replicates (± SD). The standard deviation is shown when higher than the symbol.

The C_i changed slightly throughout the day in both species butR. communis displayed higher C_i values compared withJ. curcas (Figure 5B), corroborating the data previously observed (Figure 3B). The transpiration showed a variation pattern close to a parabolic function, similar to that observed for CO₂ assimilation, increasing from 7h00, reaching a maximum between 11h00 and 13h00 and decreasing afterwards (Figure 5C). The transpiration rates over the course of the day were slightly higher inR. communis compared withJ. curcas. The former species presented higher g_s values from 7h00 until 13h00 thanJ. curcas but from 15h00 to 17h00 the two species studied showed similar stomatal conductance (Figure 5D).J. curcasexhibited higher water use efficiency (WUE), as expressed by μmol CO₂ fixed per mmol H₂O transpired, but mainly if the WUE is expressed on a stomatal conductance basis, thereby corroborating the previous data shown inFigure 3.

Both species displayed a similar trend in photochemical modulation during the course of the day (Figure 6 A-D). Fv/Fm, a ratio that expresses the potential yield of PSII, decreased during the driest and hottest hours of the day in both species, recovering late afternoon (Figure 6A). The effective quantum yield (∆F/Fm’) and the apparent electron transport of PSII (ETR) exhibited similar trends in both species, decreasing until 14h00 and recovering steadily afterwards (Figure 6 B-C). However,R.communis displayed higher photochemical efficiency and electron transport rate until 14h00 compared withJ. curcas. The non-photochemical quenching (NPQ), an indicator of heat dissipation at PSII level, was triggered steadily in both species from 6h00 to 13h00, decreasing afterwards and reaching values near to those observed in the early morning.

Figure 6
– Daily courses of (A) potential yield of PSII, (B) effective yield of PSII, (C) electron transport rate of PSII and (D) non-photochemical quenching, in youngJ. curcas andR. communis plants. The average environmental parameters over the experimental period were as follows: 29 °C / 24 °C mean/minimum temperature, 62 % relative humidity, 1,500 µmol m−2 s-1 maximum photosynthetic photon flux density (PPFD). Each point represents the mean value of five replicates (± SD). The standard deviation is shown when higher than the symbol.

Interestingly,J. curcas presented NPQ much higher thanR. communis for most of the day (Figure 6D), indicating a great contrast between these species in terms of coping with excess energy. Altogether, the data obtained over a typical day in a semiarid region indicated that the two species had a significant contrast in photosynthesis under well-watered conditions and when exposed to varying conditions of PPFD and VPD (air temperature and humidity). The most contrasting mechanisms were stomatal control in whichR. communisexhibited much higher stomatal conductance associated with higher Ci compared withJ. curcas. However, these two mechanisms were not closely correlated with CO₂assimilation, indicating a certain biochemical limitation inR. communis. In contrast,J. curcas plants were more efficient in terms of photosynthesis per unit of water transpired, Ci and extent of stomatal opening. Both species exhibited good plasticity in PSII modulation butJ. curcas was more efficient in terms of excess energy dissipation as heat by the NPQ mechanism.

R. communis displays under these environmental conditions higher leaf dry matter, relative water content and lower water potential compared withJ. curcas plants exposed to the same condition. The electrolyte leakage, a common parameter for estimating membrane damage was practically the same in both species (Table 2).

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Table 2
– Leaf dry matter, relative water content, water potential and electrolyte leakage inJ. curcas andR. communis plants grown under greenhouse conditions in a semiarid region. Each point represents the mean of five replicates. *represents a difference between species (t test,p< 0.05).

Discussion

Our data strongly suggest thatJ. curcas andR. communis plants display contrasting photosynthetic mechanisms in response to different environmental conditions. Apparently,J. curcas is better adapted to dry and hot conditions like those that prevail in semiarid regions. Indeed, this species displays efficient stomatal control to avoid water loss and high excess energy dissipation by NPQ, corroborating previous results in response to water deficit alone (Maes et al., 2009aMaes, W.H.; Achten, W.M.; Reubens, B.; Raes, D.; Samson, R.; Muys, B. 2009a. Plant-water relationships and growth strategies ofJatropha curcas L. seedlings under different levels of drought stress. Journal of Arid Environments 73: 877-884.;Maes et al., 2009bMaes, W.H.; Trabucco, A.; Achten, W.M.J; Muys, B. 2009b. Climatic growing conditions ofJatropha curcas L. Biomass & Bioenergy 33: 1481-1485.;Silva et al., 2010aSilva, E.N.; Ribeiro, R.V.; Ferreira-Silva, S.L.; Viégas, R.A.; Silveira, J.AG.; 2010a. Comparative effects of salinity and water stress on photosynthesis, water relations and growth of Jatropha curcas plants. Journal of Arid Environments 74: 1130-1137.), drought combined with high temperature (Silva et al., 2012Silva, E.N.; Vieira, S.A.; Ribeiro, R.V.; Ponte, L.F.A.; Ferreira-Silva, S.L.; Silveira, J. A.G. 2012. Contrasting physiological responses of Jatropha curcas plants to single and combined stresses of salinity and heat. Journal of Plant Growth Regulation 32: 159–169.), drought with high CO₂ (Meng et al., 2013Meng, G.; Li, G.; He, L.; Chai, Y.; Kong, J.; Lei, Y. 2013. Combined effects of CO2 enrichment and drought stress on growth and energetic properties in the seedlings of a potential bioenergy cropJatropha curcas. Journal of Plant Growth Regulation 32: 542–550.) and salinity alone or in combination with high temperature (Silva et al., 2010aSilva, E.N.; Ribeiro, R.V.; Ferreira-Silva, S.L.; Viégas, R.A.; Silveira, J.AG.; 2010a. Comparative effects of salinity and water stress on photosynthesis, water relations and growth of Jatropha curcas plants. Journal of Arid Environments 74: 1130-1137.;Silva et al., 2010bSilva, E.N.; Ferreira-Silva, S.L.; Fontenele, A.V.; Ribeiro, R.V.; Viégas, R.A.; Silveira, J.A.G. 2010b. Photosynthetic changes and protective mechanisms against oxidative damage subjected to isolated and combined drought and heat stresses in Jatropha curcas plants. Journal of Plant Physiology 167: 1157-1164.).

In contrast toJ. curcas, R. communis display less effective stomatal control and NPQ triggering under dry and hot conditions. This species has more efficient photosynthesis under non-limiting conditions of soil water availability, light and temperature.Dai et al. (1992)Dai, Z.; Edwards, G.E.; Ku, M.S. 1992. Control of photosynthesis and stomatal conductance in Ricinus communis L. (Castor Bean) by leaf to air vapor pressure deficit. Plant Physiology 99: 1426-1434. reported thatR. communis presents high photosynthetic capacity under low VPD conditions which was comparable to a C4 plant (maize). However, similar to the data we obtained, photosynthesis was remarkably reduced as VPD increased in parallel to an excessive loss of water by transpiration. Our data are also corroborated byBarbour and Buckley (2007)Barbour, M.M.; Buckley, T.H.; 2007. The stomatal response to evaporative demand persists at night in Ricinus communis plants with high nocturnal conductance. Plant Cell and Environment 30: 711-721., who have suggested thatR. communis is a “mal-adaptive” species when faced with dry conditions since it maintains high stomatal conductance even under high VPD.R. communis plants presented stomatal limitation to photosynthesis under drought and maintained high g_s, resulting in low water use efficiency (Babita et al., 2010Babita, M.; Maheswari, M.; Rao, L.M.; Shanker, A.K.; Rao, D.G. 2010. Osmotic adjustment, drought tolerance and yield in castor (Ricinus communis L.) hybrids. Environmental and Experimental Botany 69: 243–249.).

Under field conditions R. communis andJ. curcas require different crop management and climate conditions to reach optimum productivity. The former species require good soil water supply and low VPD to express their genetic potential for high photosynthesis. In contrast,J. curcasis less able to exhibit similar photosynthetic efficiency under the conditions required by R. communis but, in contrast, it adapts better to hot and dry conditions. Thus, the photosynthetic characteristics presented by these two species are typical for both the more tolerant (J. curcas) as well as the less tolerant (R. communis) to drought condition (Flexas and Medrano, 2002Flexas, J.; Medrano, H. 2002. Drought-inhibition of photosynthesis in C3 plants: stomatal and non-stomatal limitations revisited. Annals of Botany 89: 183-189.;Chaves et al., 2003Chaves, M.M.; Maroco, J.P.; Pereira, J.S. 2003. Understanding plant responses to drought: from genes to the whole plant. Functional Plant Biology 30: 239-264.).

To display favorable stomatal mechanisms to cope with drought,J. curcas exhibits another important adaptive characteristic, that is, a rapid and efficient triggering of excess energy dissipation by NPQ at PSII level. Indeed, this response is very important for adaptation to a wide range of stressful conditions (Niyogi 1999Niyogi, K.K. 1999. Photoprotection revisited: genetic and molecular approaches. Annual Review of Plant Physiology and Plant Molecular Biology 50: 333-359.;Chaves et al., 2009Chaves, M.M.; Flexas, J.; Pinheiro, C. 2009. Photosynthesis under drought and salt stress: regulation mechanisms from whole plant to cell. Annals of Botany 103: 551-560.;Driever and Baker, 2011Driever, S.M.; Baker, N.R. 2011. The water-water cycle in leaves is not a major alternative electron sink for dissipation of excess excitation energy when CO2 assimilation is restricted. Plant Cell and Environment 34: 837-846.;Takahashi and Badger, 2011Takahashi, S.; Badger, M.R. 2011. Photoprotection in plants: a new light on photosystem II damage. Trends in Plant Science 16: 53-60.). Under drought conditions, the impairment of CO₂ assimilation causes an imbalance between the electron transport rate in the photosynthetic electron transport (PET) chain and the plant's capacity to utilize NADPH (reduced nicotinamide adenine dinucleotide phosphate) and ATP (adenosine tri-phosphate) in the Calvin cycle (Chaves et al., 2009Chaves, M.M.; Flexas, J.; Pinheiro, C. 2009. Photosynthesis under drought and salt stress: regulation mechanisms from whole plant to cell. Annals of Botany 103: 551-560.). Under this CO₂-limiting condition, photorespiration is proposed as an important alternative pathway for consuming the excess reducing equivalents from the photochemical reactions, avoiding photoinhibition (Bagard et al., 2008Bagard, M.; Le Thiec, D.; Delacote, E.; Hasenfratz-Sauder, M.P.; Banvoy, J.; Gérard, J.; Dizengremel, P.; Jolivet, Y. 2008. Ozone-induced changes in photosynthesis and photorespiration of hybrid poplar in relation to the developmental stage of the leaves. Physiologia Plantarum 134: 559-574.;Takahashi and Badger, 2011)Takahashi, S.; Badger, M.R. 2011. Photoprotection in plants: a new light on photosystem II damage. Trends in Plant Science 16: 53-60..

Plants must achieve a fine balance between photochemistry, CO₂ assimilation, and alternative electron sinks in order to cope with different environment conditions and avoid photoinhibition (Murchie and Niyogi, 2011Murchie, E.H.; Niyogi, K.K. 2011. Manipulation of photoprotection to improve plant photosynthesis. Plant Physiology 155: 86–92.). Any disturbance of this equilibrium will disrupt the photosynthetic efficiency and result in excess energy on the thylakoid membranes (Niyogi 1999Niyogi, K.K. 1999. Photoprotection revisited: genetic and molecular approaches. Annual Review of Plant Physiology and Plant Molecular Biology 50: 333-359.). This excess energy might produce reactive oxygen species that in high concentrations can be harmful to lipids, and protein structure in chloroplasts and the whole cell (Osmond and Förster, 2006Osmond, B.; Förster, B. 2006. Photoinhibition: then and now. p. 11-22. In: Demmig-Adams, B.; Adams III, W.W.; Mattoo, A.K., eds. Photoprotection, photoinhibition, gene regulation, and environment. Springer, Dordrecht, The Netherlands.). However, plants have developed distinct photo-protective mechanisms that control the excess energy to preserve the structures of chloroplasts and metabolism.Aragão et al. (2012)Aragão, R.M.; Silva, E.N.; Vireira, C.F.; Silveira, J.A.G. 2012. High supply of NO3-mitigates salinity effects through an enhancement in the efficiency of photosystem II and CO2 assimilation in Jatropha curcas plants. Acta Physiologiae Plantarum 34: 2135-43. have previously reported thatJ. curcas plants exposed to salinity use nitrate assimilation as an alternative excess energy dissipation mechanism. In addition,Lima Neto et al. (2014)Lima Neto, M.C.; Lobo, A.K.M.; Martins, M.O.; Fontenele, A.V.; Silveira, J.A.G. 2014. Dissipation of excess photosynthetic energy contributes to salinity tolerance: a comparative study of salt-tolerantRicinus communis and salt-sensitiveJatropha curcas. Journal of Plant Physiology 171: 23–30. demonstrated thatR. communisdisplayed higher increases in photorespiration compared withJ. curcas after exposure to high salinity.

J. curcas has lower potential photosynthesis but higherin vivo Rubisco activity (Vcmax) and maximum electron transport rate (Jmax) compared withR. communis under optimum growth conditions. Moreover, over a typical day in a semiarid environment, with high irradiance, VPD and temperature, but exposed to well-watered conditions,J. curcas had similar photosynthesis and higher water use efficiency, compared withR. communis. These responses were related to efficient stomata control and the increase in NPQ to prevent photoinhibition inJ. curcas. The maintaining of high P_N during the driest hours of the day (high VPD levels) is related to low stomata control inR. communis in response to VPD as described previously byBarbour and Buckley (2007)Barbour, M.M.; Buckley, T.H.; 2007. The stomatal response to evaporative demand persists at night in Ricinus communis plants with high nocturnal conductance. Plant Cell and Environment 30: 711-721.. A high transpiration rate linked with low photosynthesis is not an advantageous physiological characteristic for plants that face abiotic stress factors like those predominating in semiarid environments.

DoesR. communishave stomatal characteristics suitable for coping with dry and hot environments such as those found in semiarid regions? In fact, the stomatal conductance and water use efficiency presented byR. communis are less effective in dealing with drought compared withJ. curcas. Thus, apparently, the initial growth phase is critical toR. communis for survival and it will grow under dry conditions. In contrast, this species requires good water supply and mild vapor pressure deficit to achieve maximum photosynthetic efficiency. However, as both R. communisandJ. curcas are deciduous species, they could display low photosynthetic efficiency under the very dry conditions prevailing in semiarid regions. In practical terms,J. curcas are more adapted to survivjng under extreme conditions of heat and dryness in comparison withR. communis. In contrast, under irrigated conditions, the latter species might exhibit higher photosynthesis rates.

In conclusion, under non-limiting water supplyR. communis plants have high photosynthetic efficiency associated with an efficient use of light and CO₂ and high stomatal and mesophyll conductance. In contrast,J. curcas is resistant to hot and dry conditions due to an efficient excess energy dissipation mechanism at PSII level by NPQ. This photochemical response inJ. curcas is associated with an effective stomatal mechanism that might restrict water loss, which allows it to maintain high water use efficiency under abiotic stress conditions.

Acknowledgements

We are grateful to the Foundation for Support of Scientific and Technological Development of Ceará (FUNCAP) (Project 2155/Programa Núcleos de Excelência, PRONEX) and to the Brazilian National Council for Scientific and Technological Development for financial support (CNPQ).

References

Achten, W.M.J.; Maes, W.H.; Aerts, R.; Verchot, L.; Trabucco, A.; Mathijs, E.; Singh, V.P. 2010. Jatropha: from global hype to local opportunity. Journal of Arid Environments 74: 164-165.
Adams III, W.W.; Muller, O.; Cohu, C.M.; Demmig-Adams, B. 2013. May photoinhibition be a consequence, rather than a cause, of limited plant productivity? Photosynthesis Research 117: 31-44.
Aragão, R.M.; Silva, E.N.; Vireira, C.F.; Silveira, J.A.G. 2012. High supply of NO₃^-mitigates salinity effects through an enhancement in the efficiency of photosystem II and CO₂ assimilation in Jatropha curcas plants. Acta Physiologiae Plantarum 34: 2135-43.
Athanasiou, K.; Dyson, B.C.; Webster, R.E.; Johnson, G.N.; 2010. Dynamic acclimation of photosynthesis increases plant fitness in changing environments. Plant Physiology 152: 366–73.
Babita, M.; Maheswari, M.; Rao, L.M.; Shanker, A.K.; Rao, D.G. 2010. Osmotic adjustment, drought tolerance and yield in castor (Ricinus communis L.) hybrids. Environmental and Experimental Botany 69: 243–249.
Bagard, M.; Le Thiec, D.; Delacote, E.; Hasenfratz-Sauder, M.P.; Banvoy, J.; Gérard, J.; Dizengremel, P.; Jolivet, Y. 2008. Ozone-induced changes in photosynthesis and photorespiration of hybrid poplar in relation to the developmental stage of the leaves. Physiologia Plantarum 134: 559-574.
Barbour, M.M.; Buckley, T.H.; 2007. The stomatal response to evaporative demand persists at night in Ricinus communis plants with high nocturnal conductance. Plant Cell and Environment 30: 711-721.
Chaves, M.M.; Flexas, J.; Pinheiro, C. 2009. Photosynthesis under drought and salt stress: regulation mechanisms from whole plant to cell. Annals of Botany 103: 551-560.
Chaves, M.M.; Maroco, J.P.; Pereira, J.S. 2003. Understanding plant responses to drought: from genes to the whole plant. Functional Plant Biology 30: 239-264.
Cousins, A.B.; Johnson, M.; Leakey, A.D.B. 2014. Photosynthesis and the environment. Photosynthesis Research 119: 1-2.
Dai, Z.; Edwards, G.E.; Ku, M.S. 1992. Control of photosynthesis and stomatal conductance in Ricinus communis L. (Castor Bean) by leaf to air vapor pressure deficit. Plant Physiology 99: 1426-1434.
Driever, S.M.; Baker, N.R. 2011. The water-water cycle in leaves is not a major alternative electron sink for dissipation of excess excitation energy when CO₂ assimilation is restricted. Plant Cell and Environment 34: 837-846.
Flexas, J.; Medrano, H. 2002. Drought-inhibition of photosynthesis in C3 plants: stomatal and non-stomatal limitations revisited. Annals of Botany 89: 183-189.
Flexas, J.; Diaz-Espejo, A.; Galmés, J.; Kaldenhoff, R.; Medrano, H.; Ribas-Carbo, M.; 2007. Rapid variations of mesophyll conductance in response to changes in CO₂ concentration around leaves. Plant Cell and Environment 30: 1284-1298.
Goh, C.H.; Ko, S.M.; Koh, S.; Kim, Y.J.; Bae, H.J. 2012. Photosynthesis and environments: photoinhibition and repair mechanisms in plants. Journal of Plant Biology 55: 93–101.
Gonzalez-Cruz, J.; Pastenes, C. 2012. Water-stress induced thermotolerance of photosynthesis in bean (Phaseolus vulgaris). Enviromental and Experimental Botany 77: 127-140.
Hoagland, D.R.; Arnon, D.L. 1950. The water culture method for growing plants without soil. UCLA, Berkeley, CA, USA. (California Agricultural Experimental Extension Circular, 347).
Kramer, D.M.; Evans, J.R. 2011. The importance of energy balance in improving photosynthetic productivity. Plant Physiology 155: 70-78.
Lieth, J.H.; Reynolds, J.F. 1987. The Nonrectangular hyperbola as a photosynthetic light response model: geometrical interpretation and estimation of the parameter θ. Photosynthetica 101: 363-366.
Lima Neto, M.C.; Lobo, A.K.M.; Martins, M.O.; Fontenele, A.V.; Silveira, J.A.G. 2014. Dissipation of excess photosynthetic energy contributes to salinity tolerance: a comparative study of salt-tolerantRicinus communis and salt-sensitiveJatropha curcas Journal of Plant Physiology 171: 23–30.
Liu, X.; Huang, B. 2008. Photosynthetic acclimation to high temperatures associated with heat tolerance in creeping bentgrass. Journal of Plant Physiology 165: 1947-1953.
Maes, W.H.; Achten, W.M.; Reubens, B.; Raes, D.; Samson, R.; Muys, B. 2009a. Plant-water relationships and growth strategies ofJatropha curcas L. seedlings under different levels of drought stress. Journal of Arid Environments 73: 877-884.
Maes, W.H.; Trabucco, A.; Achten, W.M.J; Muys, B. 2009b. Climatic growing conditions ofJatropha curcas L. Biomass & Bioenergy 33: 1481-1485.
Maxwell, K.; Johnson, G.N. 2000. Chlorophyll fluorescence: a practical guide. Journal of Experimental Botany 51: 659–668.
Meng, G.; Li, G.; He, L.; Chai, Y.; Kong, J.; Lei, Y. 2013. Combined effects of CO₂ enrichment and drought stress on growth and energetic properties in the seedlings of a potential bioenergy cropJatropha curcas Journal of Plant Growth Regulation 32: 542–550.
Murchie, E.H.; Niyogi, K.K. 2011. Manipulation of photoprotection to improve plant photosynthesis. Plant Physiology 155: 86–92.
Niyogi, K.K. 1999. Photoprotection revisited: genetic and molecular approaches. Annual Review of Plant Physiology and Plant Molecular Biology 50: 333-359.
Osmond, B.; Förster, B. 2006. Photoinhibition: then and now. p. 11-22. In: Demmig-Adams, B.; Adams III, W.W.; Mattoo, A.K., eds. Photoprotection, photoinhibition, gene regulation, and environment. Springer, Dordrecht, The Netherlands.
Sharkey, T.D.; Bernacchi, C.J.; Farquhar, G.D.; Singsaas, E.L. 2007. Fitting photosynthetic carbon dioxide response curves for C₃ plants. Plant, Cell & Environment 30: 1035-1040.
Schreiber, U.; Bilger, W.; Neubauer, C. 1994. Chlorophyll fluorescence as a nonintrusive indicator for rapid assessment of in vivo photosynthesis. p. 49-70. In: Schulze, E.D.; Caldwell, M.M., eds. Ecophysiology of photosynthesis. Springer, Berlin, Germany.
Silva, E.N.; Ribeiro, R.V.; Ferreira-Silva, S.L.; Viégas, R.A.; Silveira, J.AG.; 2010a. Comparative effects of salinity and water stress on photosynthesis, water relations and growth of Jatropha curcas plants. Journal of Arid Environments 74: 1130-1137.
Silva, E.N.; Ferreira-Silva, S.L.; Fontenele, A.V.; Ribeiro, R.V.; Viégas, R.A.; Silveira, J.A.G. 2010b. Photosynthetic changes and protective mechanisms against oxidative damage subjected to isolated and combined drought and heat stresses in Jatropha curcas plants. Journal of Plant Physiology 167: 1157-1164.
Silva, E.N.; Vieira, S.A.; Ribeiro, R.V.; Ponte, L.F.A.; Ferreira-Silva, S.L.; Silveira, J. A.G. 2012. Contrasting physiological responses of Jatropha curcas plants to single and combined stresses of salinity and heat. Journal of Plant Growth Regulation 32: 159–169.
Takahashi, S.; Badger, M.R. 2011. Photoprotection in plants: a new light on photosystem II damage. Trends in Plant Science 16: 53-60.
Yamori, W.; Hisosaka, K.; Way, D.A. 2014. Temperature response of photosynthesis in C₃, C₄ and CAM plants: temperature acclimation and temperature adaptation. Photosynthesis Research 119: 101-117.

Publication Dates

Publication in this collection
June 2015

History

Received
17 Sept 2014
Accepted
19 Nov 2014

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Achten, W.M.J.; Maes, W.H.; Aerts, R.; Verchot, L.; Trabucco, A.; Mathijs, E.; Singh, V.P. 2010. Jatropha: from global hype to local opportunity. Journal of Arid Environments 74: 164-165.

[2] Adams III, W.W.; Muller, O.; Cohu, C.M.; Demmig-Adams, B. 2013. May photoinhibition be a consequence, rather than a cause, of limited plant productivity? Photosynthesis Research 117: 31-44.

[3] Aragão, R.M.; Silva, E.N.; Vireira, C.F.; Silveira, J.A.G. 2012. High supply of NO₃^-mitigates salinity effects through an enhancement in the efficiency of photosystem II and CO₂ assimilation in Jatropha curcas plants. Acta Physiologiae Plantarum 34: 2135-43.

[4] Athanasiou, K.; Dyson, B.C.; Webster, R.E.; Johnson, G.N.; 2010. Dynamic acclimation of photosynthesis increases plant fitness in changing environments. Plant Physiology 152: 366–73.

[5] Babita, M.; Maheswari, M.; Rao, L.M.; Shanker, A.K.; Rao, D.G. 2010. Osmotic adjustment, drought tolerance and yield in castor (Ricinus communis L.) hybrids. Environmental and Experimental Botany 69: 243–249.

[6] Bagard, M.; Le Thiec, D.; Delacote, E.; Hasenfratz-Sauder, M.P.; Banvoy, J.; Gérard, J.; Dizengremel, P.; Jolivet, Y. 2008. Ozone-induced changes in photosynthesis and photorespiration of hybrid poplar in relation to the developmental stage of the leaves. Physiologia Plantarum 134: 559-574.

[7] Barbour, M.M.; Buckley, T.H.; 2007. The stomatal response to evaporative demand persists at night in Ricinus communis plants with high nocturnal conductance. Plant Cell and Environment 30: 711-721.

[8] Chaves, M.M.; Flexas, J.; Pinheiro, C. 2009. Photosynthesis under drought and salt stress: regulation mechanisms from whole plant to cell. Annals of Botany 103: 551-560.

[9] Chaves, M.M.; Maroco, J.P.; Pereira, J.S. 2003. Understanding plant responses to drought: from genes to the whole plant. Functional Plant Biology 30: 239-264.

[10] Cousins, A.B.; Johnson, M.; Leakey, A.D.B. 2014. Photosynthesis and the environment. Photosynthesis Research 119: 1-2.

[11] Dai, Z.; Edwards, G.E.; Ku, M.S. 1992. Control of photosynthesis and stomatal conductance in Ricinus communis L. (Castor Bean) by leaf to air vapor pressure deficit. Plant Physiology 99: 1426-1434.

[12] Driever, S.M.; Baker, N.R. 2011. The water-water cycle in leaves is not a major alternative electron sink for dissipation of excess excitation energy when CO₂ assimilation is restricted. Plant Cell and Environment 34: 837-846.

[13] Flexas, J.; Medrano, H. 2002. Drought-inhibition of photosynthesis in C3 plants: stomatal and non-stomatal limitations revisited. Annals of Botany 89: 183-189.

[14] Flexas, J.; Diaz-Espejo, A.; Galmés, J.; Kaldenhoff, R.; Medrano, H.; Ribas-Carbo, M.; 2007. Rapid variations of mesophyll conductance in response to changes in CO₂ concentration around leaves. Plant Cell and Environment 30: 1284-1298.

[15] Goh, C.H.; Ko, S.M.; Koh, S.; Kim, Y.J.; Bae, H.J. 2012. Photosynthesis and environments: photoinhibition and repair mechanisms in plants. Journal of Plant Biology 55: 93–101.

[16] Gonzalez-Cruz, J.; Pastenes, C. 2012. Water-stress induced thermotolerance of photosynthesis in bean (Phaseolus vulgaris). Enviromental and Experimental Botany 77: 127-140.

[17] Hoagland, D.R.; Arnon, D.L. 1950. The water culture method for growing plants without soil. UCLA, Berkeley, CA, USA. (California Agricultural Experimental Extension Circular, 347).

[18] Kramer, D.M.; Evans, J.R. 2011. The importance of energy balance in improving photosynthetic productivity. Plant Physiology 155: 70-78.

[19] Lieth, J.H.; Reynolds, J.F. 1987. The Nonrectangular hyperbola as a photosynthetic light response model: geometrical interpretation and estimation of the parameter θ. Photosynthetica 101: 363-366.

[20] Lima Neto, M.C.; Lobo, A.K.M.; Martins, M.O.; Fontenele, A.V.; Silveira, J.A.G. 2014. Dissipation of excess photosynthetic energy contributes to salinity tolerance: a comparative study of salt-tolerantRicinus communis and salt-sensitiveJatropha curcas Journal of Plant Physiology 171: 23–30.

[21] Liu, X.; Huang, B. 2008. Photosynthetic acclimation to high temperatures associated with heat tolerance in creeping bentgrass. Journal of Plant Physiology 165: 1947-1953.

[22] Maes, W.H.; Achten, W.M.; Reubens, B.; Raes, D.; Samson, R.; Muys, B. 2009a. Plant-water relationships and growth strategies ofJatropha curcas L. seedlings under different levels of drought stress. Journal of Arid Environments 73: 877-884.

[23] Maes, W.H.; Trabucco, A.; Achten, W.M.J; Muys, B. 2009b. Climatic growing conditions ofJatropha curcas L. Biomass & Bioenergy 33: 1481-1485.

[24] Maxwell, K.; Johnson, G.N. 2000. Chlorophyll fluorescence: a practical guide. Journal of Experimental Botany 51: 659–668.

[25] Meng, G.; Li, G.; He, L.; Chai, Y.; Kong, J.; Lei, Y. 2013. Combined effects of CO₂ enrichment and drought stress on growth and energetic properties in the seedlings of a potential bioenergy cropJatropha curcas Journal of Plant Growth Regulation 32: 542–550.

[26] Murchie, E.H.; Niyogi, K.K. 2011. Manipulation of photoprotection to improve plant photosynthesis. Plant Physiology 155: 86–92.

[27] Niyogi, K.K. 1999. Photoprotection revisited: genetic and molecular approaches. Annual Review of Plant Physiology and Plant Molecular Biology 50: 333-359.

[28] Osmond, B.; Förster, B. 2006. Photoinhibition: then and now. p. 11-22. In: Demmig-Adams, B.; Adams III, W.W.; Mattoo, A.K., eds. Photoprotection, photoinhibition, gene regulation, and environment. Springer, Dordrecht, The Netherlands.

[29] Sharkey, T.D.; Bernacchi, C.J.; Farquhar, G.D.; Singsaas, E.L. 2007. Fitting photosynthetic carbon dioxide response curves for C₃ plants. Plant, Cell & Environment 30: 1035-1040.

[30] Schreiber, U.; Bilger, W.; Neubauer, C. 1994. Chlorophyll fluorescence as a nonintrusive indicator for rapid assessment of in vivo photosynthesis. p. 49-70. In: Schulze, E.D.; Caldwell, M.M., eds. Ecophysiology of photosynthesis. Springer, Berlin, Germany.

[31] Silva, E.N.; Ribeiro, R.V.; Ferreira-Silva, S.L.; Viégas, R.A.; Silveira, J.AG.; 2010a. Comparative effects of salinity and water stress on photosynthesis, water relations and growth of Jatropha curcas plants. Journal of Arid Environments 74: 1130-1137.

[32] Silva, E.N.; Ferreira-Silva, S.L.; Fontenele, A.V.; Ribeiro, R.V.; Viégas, R.A.; Silveira, J.A.G. 2010b. Photosynthetic changes and protective mechanisms against oxidative damage subjected to isolated and combined drought and heat stresses in Jatropha curcas plants. Journal of Plant Physiology 167: 1157-1164.

[33] Silva, E.N.; Vieira, S.A.; Ribeiro, R.V.; Ponte, L.F.A.; Ferreira-Silva, S.L.; Silveira, J. A.G. 2012. Contrasting physiological responses of Jatropha curcas plants to single and combined stresses of salinity and heat. Journal of Plant Growth Regulation 32: 159–169.

[34] Takahashi, S.; Badger, M.R. 2011. Photoprotection in plants: a new light on photosystem II damage. Trends in Plant Science 16: 53-60.

[35] Yamori, W.; Hisosaka, K.; Way, D.A. 2014. Temperature response of photosynthesis in C₃, C₄ and CAM plants: temperature acclimation and temperature adaptation. Photosynthesis Research 119: 101-117.

	J. curcas	R. communis
Light Γ* (µmol m⁻² s⁻¹)	20.71 b	26.82 a
Light P_Nmax(µmol m⁻² s⁻¹)	19.06 b	24.12
CO₂ Γ^* (µmol m⁻² s⁻¹)	12.06 a	8.34 b
CO₂ P_Nmax(µmol m⁻² s⁻¹)	38.26 b	49.17 a
V_cmax(µmol m⁻² s⁻¹)	225.10 a	142.26 b
J_max(µmol m⁻² s⁻¹)	246.04 a	185.10 b
g_m(mol m⁻² s⁻¹)	0.23 b	0.59 a
P_R(µmol m⁻² s⁻¹)	7.52 a	3.46 b

	R. communis	J. curcas
Leaf DM (g per plant)	5.41*	4.91
RWC (%)	81.43*	63.24
Water potential (MPa)	-0.31*	-0.19
Electrolyte leakage (%)	21.18	21.69

Brasil