Introduction
The climate change has generated an increase in the environmental temperature and this has resulted in modifications of the water regimes and the precipitation patterns worldwide (Hitz and Smith, 2004). This situation has made drought stress one of the principal limiting abiotic stresses for agricultural production (Zoebl, 2006). Water stress reduces plant growth through a reduction in photosynthesis, mainly caused by a stomatal limitation (Liu et al., 2005; Parent et al., 2014). A decrease in the plant water potential (Ψw) caused by water deficit, increases the levels of abscisic acid (ABA) in the plants, which induces a stomatal closure as an early response in the defense against stress (Lim et al., 2015). Decreases in stomatal conductance (gs) reduce water loss through transpiration, but it also decrease carbon dioxide uptake, reducing the production of photoassimilates and, therefore, plant growth (Lahlou et al., 2003; Tourneux et al., 2003a). This decrease in the photosynthetic rate under water deficit conditions has been reported in plants such as potato (Solamun tuberosum L.) (Moorby et al., 1975 Schapendonk et al., 1989; Ierna and Mauromicale, 2006; Liu et al., 2006; Ramírez et al., 2016). With severe water stress, in addition to the stomatal limitation of photosynthesis, the presence of non-stomatal limitations related to damage to the photosynthetic apparatus has been reported (Sanda et al., 2011; Noctor et al., 2014). These limitations can be measured with different variables such as the maximum photochemical efficiency of photosystem II (Fv/Fm) (Xu et al., 2010). The photosynthetic rate in many cases is also affected by the chlorophyll (Chl) content (Obidiegwu et al., 2015).
Stomatal and non-stomatal limitations cause an imbalance between the two phases of photosynthesis and an increase in the production of reactive oxygen species (ROS) (Sanchez-Rodríguez et al., 2010; Farhad et al., 2011). ROS can alter the normal functioning of plants due to the damage caused to lipids, proteins, nucleic acids, photosynthetic pigments and enzymes (Kar, 2011). The principal damage caused by ROS during water stress is lipid peroxidation, which decreases the stability of cellular membranes and increases their permeability, thereby modifying cellular metabolism (Yordanov et al., 2003). In order to overcome oxidative stress, plants have developed enzymatic and non-enzymatic antioxidants (Cruz de Carvalho, 2008). Among the non-enzymatic antioxidants, carotenoids (Car) are particularly important because they decrease ROS contents and thereby protect the photosynthetic machinery (Cazzonelli, 2011). Car may also act as a defensive response by reducing thermal effects of drought stress (Farooq et al., 2009).
The decrease in photosynthesis resulting from drought stress reduces growth, affecting parameters such as foliar area, total dry mass, and distribution of photoassimilates within the plants (Chaves et al., 2002; Lahlou et al., 2003). This negative effect on growth has been reported for plants including potato (Lahlou et al., 2003; Ierna and Mauromicale, 2006) and sorghum (Sorghum bicolor L.) (Zegada-Lizarasu and Monti, 2013). However, differences have been observed in the effects caused by drought stress related to morphological, physiological, biochemical, and molecular changes among species and cultivars (Tourneux et al., 2003a; Liu et al., 2005; Liu et al., 2006; Graca et al., 2010). Likewise, under drought stress, the tolerance of some genotypes has been associated with rapid recuperation after rehydration (Hu et al., 2010; Zegada-Lizarazu and Monti, 2013).
Solanum tuberosum L. is a species originated in the Andean region of South America, cultivated worldwide and very important for food security in Colombia (Devaux et al., 2014). Potato plants are very sensitive to drought stress compared to other species (Porter et al., 1999). It has been reported that drought stress considerably decreases yield, making water availability a limiting factor in the production of this crop (Lahlou et al., 2003; Tourneux et al., 2003a; Obidiegwu et al., 2015). In South American countries, potato is cultivated in highly mountainous areas with few or no available water, suggesting that this crop is often subjected to drought stress conditions.
It has been shown that the magnitude of drought stress in potato production depends on the plant phenology, duration, and severity of the stress (Jefferies, 1995). Potato plants are susceptible to soil matric potentials (SMP) lower than -25 kPa and SMP values near -45 kPa, causing water stress in this crop (Wang et al., 2007). Thus far, there is not information available about the physiological effects of short periods of water deficit on Colombian potato cultivars. Potato plants could respond to drought stress very early and develop strategies to cope with it (Farhad et al., 2011; Monneveux et al., 2013). Therefore, physiological behavior of the plants under this stress could provide information on their capacity to tolerate drought stress.
This study aimed to evaluate leaf Ψw gas exchange behavior, leaf temperature (LT), chlorophyll fluorescence parameters, photosynthetic pigment content, membrane permeability, growth parameters, and yield in three potato (S. tuberosum L.) cultivars that are commercially used in Colombia under a short period of water stress and recovery, aiming to expand knowledge on this topic of interest.
Materials and methods
Plant material and experimental design
This study was carried out in 2013 in the greenhouses of the Facultad de Ciencias Agrarias of the Universidad Nacional de Colombia, located at 2,600 m a.s.l. A seed tuber with a weight of 50 (±10) g of the potato tubers of Diacol Capiro (DC), Pastusa Suprema (PS), and Esmeralda (Es) cultivars were planted in black plastic bags that contained 5 kg of silty loam soil with pH 6.3. The plant materials were arranged in plots. Each plot consisted of 12 plants distributed in an area of 4.80 m2, 0.80 m, and 0.40 m apart. Considering the results of the soil analysis, each plant was fertilized with 20 g of Abocol® 10-30-10 (N-P-K) and 5 g of Agrimins®, applied at planting. Foliar applications of Omex Bio 8®, which provide macroelements and chelated microelements were applied at doses of 1 cm3 L-1 60 d after planting (DAP). Since planting time, plants were irrigated with 800 mL of water every third day; the SMP was maintained at 0.00 MPa to guarantee plant emergence and growth. During the experiment, the maximum and minimum temperatures and relative humidity were registered daily with a weather station (MCR200 μMetos®, Pessl Instruments, Weiz, Austria) (Fig. 1a). The mean vapor pressure deficit (VPD) (Fig. 1b) also was calculated.
![](/img/revistas/agc/v35n2//0120-9965-agc-35-02-00158-gf1.jpg)
FIGURE 1A Mean temperature, maximum and minimum temperatures (°C) and mean relative humidity (%); B. Average vapor pressure deficit (VPD) (kPa) in the greenhouse during the days of the period in which the potato plants were subjected to water deficit. DAT: days after treatment.
The treatments were distributed in a split-plot arrangement under a randomized complete block design with three replications; the cultivars were placed in the main plots, and the water states were in the sub-plots - drought-stressed (DS) or well-watered (WW) plants. In the DS treatment, irrigation was suspended at 74 DAP, at the beginning of tuberization stage in the three cultivars; several studies report that when the water deficit is applied in this phenological stage generates a reduction in crop yield (Liu et al., 2005; Liu et al., 2006; Ahmadi et al., 2010). Drought stress was applied for 4 to 6 d, until the SMP reached values below -45 kPa, which is considered to cause water stress in potato crops (Wang et al., 2007; AksiC et al., 2014). The stress level also was defined according to the permanent wilting point reported for potato crops, in which the leaf Ψw reaches a less negative value than -1.60 MPa (Vos and Haverkort, 2007; Rolando et al., 2015). After this period of stress, the plants were irrigated for recovery.
Leaf water potential and soil matric potential
The leaf Ψw was measured from 12:00 h to13:00 h in 3 or 4 completely expanded leaves from top to bottom of six plants per treatment. was measured with a Scholander pressure chamber (PMS Model 615, Fresno, CA, USA). SMP was measured at 6:00 h with a tensiometer (Tensiorun®, Unidrench, Bogota, Colombia).
Gas exchange, water use efficiency, and leaf temperature
For the three cultivars, the photosynthetic rate (A), gs, and transpiration rate (E) were registered using a photosynthesis measurement system (LCpro-SD, Portable BioScientific, Hoddesdon, UK). The measurements were taken on 3 or 4 completely expanded leaves of six plants per treatment from 9:00 h to 11:30 h with a CO2 concentration of400 μL L-1 and a photosynthetic photon flux density of 900 μπω! m-2 s-1. The intrinsic water use efficiency (WUEi) was calculated with A and gs data (A/gs). The leaf temperature (LT) was measured using a manual infrared thermometer (HD550, Extech®, Waltham, Ma, USA). Five measurements were taken per leaf of six plants per treatment.
Chlorophyll fluorescence parameters
In order to determine the photoinhibition of photosynthesis, Fv/Fm was measured in dark-adapted leaves for 45 min using a MINI-PAM modulated fluorometer (Walz®, Effeltrich, Germany). The measurements were carried out on the same leaves that were used to measure A. The Chl molecules were excited for 0.80 s with 1,500 μmol 1 m-2 s-1 of actinic light. The parameters photosynthetic electron transport rate (ETR), effective quantum efficiency of PSII (Y[II]), photochemical quenching (qP), and non-photochemical quenching (NPQ) were registered.
Photosynthetic pigments
Leaf pigments were extracted in accordance with Lichtenthaler (1987). The upper-third portion (equal to three or four expanded leaves) of six plants per treatment was homogenized in 80% acetone. The absorbance was determined at an optical density of 663 nm and 647 nm for Chl and 470 nm for Car. The Chl and Car contents were determined, and a carotenoid/chlorophyll ratio (Car/Chl) was calculated using these values.
Membrane permeability
Permeability of cellular membranes was measured by the amount of electrolyte leakage (EL) (Valentovic et al., 2006). Ten 2.5-mm-diameter leaf discs were placed in Falcon tubes with 2 mL of deionized water at 25°C. The electrical conductivity (EC) was determined with a conductometer (HI 9835 Hanna® - ICT, SL, Bogota, Colombia) at 24 h. The EC values were expressed as a percentage with respect to the highest value using the equation PE = (EC1 * EC2) * 100; where PE = percentage of lost electrolytes, EC1 = EC at 24 h, and EC2 = EC after heating up 80°C.
Growth and yield parameters
At 123 DAP, the stem length was measured from the base to the apical meristem; the leaf area (LA) was measured with a LI-3000C portable leaf area meter (LI-COR Inc., Lincoln, NE, USA). The plants were individually separated into above-ground mass (ABG), roots (R) and tubers, which were subsequently dried in a 70 °C oven at constant weight. The root/shoot ratio (R/S) was determined using dry weight data. At 164 DAP, the tuber yield (Y) was determined as tuber fresh weight per plant using 10 plants per treatment at the time of harvest for the three varieties.
Data analysis
The data of each parameter were analyzed with analysis of variance (ANOVA) and presented as the mean value for each treatment and cultivar. A Tukey test (P≤0.01) was performed to evaluate the treatment effects. Each treatment value is the average of six replicates. Statistical analyses were performed using the R software program (R Development Core Team, 2010).
Temperature, relative humidity, and vapor pressure deficit
During the experiment period, the minimum air temperature was between 9.7°C and 12.8°C, and the maximum temperature was between 31.3°C and 38.5°C; the mean temperature was between 18.6°C and 20.6°C. The mean relative air humidity oscillated between 69.4% and 89.3%; the mean minimum and maximum relative humidity values were 44.2±10.20% and 98.8±1.6%, respectively (Fig. 1A). During the evaluation period, the VPD varied between 0.30 kPa and 0.50 kPa (Fig. 1B).
Results
Leaf water potential and soil matric potential
Leaf Ψw was significantly different (P≤0.01) between the WW and the DS cultivars from 1 to 6 d after treatment (DAT) and between the DS cultivars from 3 to 6 DAT (Fig. 2A). From 2 DAT, a significant decrease in the leaf Ψw was recorded in the DS cultivars. A leaf Ψw close to -2.00 MPa was observed at 4 DAT for DC (-1.99 MPa), at 5 DAT for PS (-2.15 MPa), and at 6 DAT for Es (-2.00 MPa). One day after recovery, the DC and PS cultivars showed a significantly lower leaf Ψw (-0.46 MPa and -0.51 MPa, respectively) compared to the WW cultivars (-0.28 MPa and -0.23 MPa, respectively), while Es had leaf Ψw values equal to those of the WW cultivars (-0.26 MPa) (Fig. 2a). The leaf was significantly different (P ≤ 0.01) between the WW and DS cultivars, from 1 to 4 DAT; however, there weres no significant differences between WW cultivars at any day. The SMP was reduced from 1 DAT and reached the most negative values in the DC (-54 kPa), PS (-56 kPa), and Es (-61 kPa) cultivars at 4, 5, and 6 d, respectively (Fig. 2B). However, after 1 d of recovery, the SMP of DS treatments reached the value of WW treatments (-0.00 kPa). Analyzed together, these results indicate the plants of the three cultivars experimented water deficit at different times, which decreased the leaf Ψw to values associated with water stress in plants.
![](/img/revistas/agc/v35n2//0120-9965-agc-35-02-00158-gf2.jpg)
FIGURE 2 Effects of drought stress and subsequent recovery in three potato cultivars (DC: Diacol Capiro, PS: Pastusa Suprema, Es: Esmeralda). WW: well-watered, DS: drought-stressed, DAT: days after treatment. A. Leaf water potential (Ψw); B. Soil matric potential (SMP). The data shown are the averages of six replicates, with the standard deviations indicated by the vertical bars. Means denoted by the same letter do not significantly differ at P≤0.01 according to the Tukey test.
Gas exchange, water use efficiency, and leaf temperature
The photosynthetic rate was statistically significant (P≤0.01) between the WW and DS cultivars from 1 to 6 DAT. The physiological parameters gs and E were statistically significant (P≤0.01) between the WW and DS cultivars from 2 to 6 DAT. Among the DS cultivars, there was a statistically significant difference in A from 1 to 6 DAT; in gs between 2 and 6 DAT; and in E at 2 DAT, 5 DAT, and 6 DAT (Fig. 3A-C). A, gs, and E were significantly different (P≤0.01) between the WW and DS cultivars from 1 DAT (A) and from 2 DAT (gs and E) until the leaf of the plants reached their lowest values (Fig. 3A, C). The highest A values in the DS cultivars were recorded in the Es cultivar from 1 to 4 DAT (4.49-22.56 μmol 1 CO2 m-2 s-1) (Fig. 3A). The gs only presented significant differences between the DS cultivars at 2 DAT, and the Es cultivar showed the highest value (0.09 mmol H2O m-2 s-1). The lowest values for A (0.56-1.17 μmol CO2 m-2 s-1), gs (0.01 mmol H2O m-2 s-1), and E (0.40-0.53 mmol H2O m-2 s-1) were recorded in all cultivars when they reached the lowest Ψw. One day after recovery, only the PS cultivar showed significant differences in A with the WW treatment (24.21 μmol CO2 m-2 s-1), while for gs and E all cultivars reached the values of the WW treatments.
![](/img/revistas/agc/v35n2//0120-9965-agc-35-02-00158-gf3.gif)
FIGURE 3 Effects of water deficit and subsequent recovery in three cultivars of potato (DC: Diacol Capiro, PS: Pastusa Suprema, Es: Esmeralda). WW: well-watered, DS: drought-stressed, DAT: days after treatment. A. Photosynthesis (A); B. Stomatal conductance (gs); C. Transpiration (E); D. Leaf temperature (LT). The data shown are the means of six replicates, with the standard deviations indicated by the vertical bars. Means denoted by the same letter do not significantly differ at P≤0.01 according to the Tukey test.
LT showed the significantly higher values in the DS cultivars at 2 DAT for plats of Es (18.01°C) and at 3 DAT for all cultivars (Fig. 3D). The maximum values for the DC (21.48°C) and PS (23.19°C) cultivars were recorded when the lowest leaf Ψw values were reached, while in the Es cultivar the maximum value was observed at 5 DAT (22.29°C). One day after recovery, the LT for the three cultivars reached the values of the WW cultivars (9.53-14.02°C). These results indicate that in the three cultivars under DS, there was a gradual stomatal closure which was higher when the plants reached a leaf Ψw close to -2.00 MPa, and this decrease in stomatal conductance reduced the CO2 input for photosynthesis as well.
WUEi in the DS cultivars was significantly higher at 3 DAT for PS (181.37 μmol CO2 mol-1 H2O) and Es (218.09 μmol CO2 mol-1 H2O) and at 4 DAT for Es (261.52 μmol CO2 mol-1 H2O) compared with the plants of WW cultivars (Fig. 4). These results showed that the PS and Es cultivars subjected to water deficit have a higher WUEi, which could be related to drought tolerance.
![](/img/revistas/agc/v35n2//0120-9965-agc-35-02-00158-gf4.gif)
FIGURE 4 Effects of water deficit and subsequent recovery on the intrinsic water use efficiency (WUEi) in three cultivars of potato (DC: Diacol Capiro, PS: Pastusa Suprema, Es: Esmeralda). WW: well-watered, DS: drought-stressed, DAT: days after treatment. The data shown are the means of six replicates, with the standard deviations indicated by the vertical bars. Means denoted by the same letter do not significantly differ at P≤0.01 according to the Tukey test.
Chlorophyll fluorescence parameters
Fv/Fm has been widely used to detect stress-induced alterations in the photosynthetic apparatus (Zegada-Lizarasu and Monti, 2013). In this study, we found that Fv/Fm recorded values greater than 0.80 for the DS and WW cultivars (Fig. 5A). Y(II) and ETR presented significant differences between the WW and DS cultivars at 4 DAT and 5 DAT (Fig. 5B, C). The DC and PS cultivars presented the lowest values for Y(II) and ETR when they reached the lowest leaf Ψw, while the Es cultivar presented the lowest value for both parameters 1 d before reaching the lowest of leaf Ψw One day after recovery, the three DS cultivars did not show significant differences in Y(II) and ETR compared to the WW cultivars. qP exhibited a significant decrease in Es (0.37) and PS (0.37) cultivars at 5 DAT; during the other days (from day 1 to 4), qP did not show differences between the WW and DS cultivars (Fig. 5D). NPQ was significantly higher in DS cultivars at 4 DAT and 5 DAT, with the highest value in PS (0.44) at 5 DAT (Fig. 5E).
![](/img/revistas/agc/v35n2//0120-9965-agc-35-02-00158-gf5.jpg)
FIGURE 5 Effects of water deficit and subsequent recovery on the variables derived from chlorophyll fluorescence in three cultivars of potato (DC: Diacol Capiro, PS: Pastusa Suprema, Es: Esmeralda). WW: well-watered, DS: drought-stressed, DAT: days after treatment. A. Maximum quantum yield of photosystem II (Fv/Fm); B. Effective quantum efficiency of PSII (Y[II]); C. Photosynthetic electron transport rate (ETR); D. Photochemical quenching (qP); E. Non-photochemical (NPQ). The data shown are the averages of six replicates, with the standard deviations indicated by the vertical bars. Means denoted by the same letter do not significantly differ at P≤0.01 according to the Tukey test.
One day after recovery, the variables Fv/Fm, Y(II), and ETR reached the values of those of WW plants in the three cultivars, while for NPQ the cultivars did not reach the values of the WW plants. These results indicate the absence of any major impairment of the photosynthetic apparatus during leaf water deficit.
Photosynthetic pigments
Chl for Es cultivar under DS was significantly higher from 5 to 7 DAT compared to WW plants (Fig. 6A). For the other cultivars, there were no significant differences in Chl between the plants under DS and WW. The Car presented a significantly higher value in DS cultivars from 2 DAT for DC and Es and from 4 to 6 DAT for PS compared to WW plants. From 4 DAT, Es presented the highest values for Car content (0.36-0.40 mg g-1 fresh weight [FW]), while DC presented the lowest values at 5 DAT (0.27 mg g-1 FW) (Fig. 6B). The Car/Chl ratio was higher for DS plants (Fig. 6C); the ratios increased from 2 DAT for DC and Es and from 4 DAT for PS. These results suggest that the three varieties exhibit a strong photoprotective system against water stress.
![](/img/revistas/agc/v35n2//0120-9965-agc-35-02-00158-gf6.jpg)
FIGURE 6 Effects of water deficit and subsequent recovery in three cultivars of potato (DC: Diacol Capiro, PS: Pastusa Suprema, Es: Esmeralda). WW: well-watered, DS: drought-stressed, FW: fresh weight, DAT: days after treatment. A. Chlorophyll (Chl); B. Carotenoids (Car); C. Carotenoids/chlorophyll ratio (Car/Chl). The data shown are the means of six replicates, with the standard deviations indicated by the vertical bars. Means denoted by the same letter do not significantly differ at P≤0.01 according to the Tukey test.
Membrane permeability
The DS cultivar plants presented a significant increase in EL from 2 DAT (Fig. 7). The Es cultivar presented the highest values at 5 DAT and 6 DAT (62.36 % and 55.29%, respectively). One day after recovery, none of the DS cultivars reached the EL values of WW plants (Fig. 7). These data suggest that the three DS cultivars exhibit an increase in membrane permeability, although this increase was higher in the Es cultivar.
![](/img/revistas/agc/v35n2//0120-9965-agc-35-02-00158-gf7.jpg)
FIGURE 7 Effects of water deficit and subsequent recovery on electrolyte leakage (EL) in three cultivars of potato (DC: Diacol Capiro, PS: Pastusa Suprema, Es: Esmeralda). WW: well-watered, DS: drought-stressed, DAT: days after treatment. The data shown are the means of six replicates, with the standard deviations indicated by the vertical bars. Means denoted by the same letter do not significantly differ at P≤0.01 according to the Tukey test.
Growth and yield parameters
ABG was significantly greater in WW plants across all cultivars (Fig. 8A), while for the RDM there were no significant differences between the DS and the WW cultivars (Fig. 8B). Regarding the R/S, the DS Es cultivar presented a significant increase (1.5) due to a lower ABG compared to the analogous WW cultivar (1.3) (Fig. 8C). The LA did not show differences between the DS and WW cultivars (Fig. 8D). There were no differences in Y between the DS and WW cultivars (Fig. 8E). Taken together, these data suggest that the three cultivars were tolerant to the drought stress.
![](/img/revistas/agc/v35n2//0120-9965-agc-35-02-00158-gf8.jpg)
FIGURE 8 Effects of water deficit and subsequent recovery in three cultivars of potato (DC: Diacol Capiro, PS: Pastusa Suprema, Es: Esmeralda). WW: well-watered, DS: drought-stressed. A. Above-ground mass (ABG); B. Root dry mass (RDM); C. Root/shoot ratio (R/S); D. Leaf area (LA); E. Tuber yield (Y). The data shown are the averages of six replicates, with the standard deviations indicated by the vertical bars. Means denoted by the same letter do not significantly differ at P≤0.01 according to the Tukey test.
Discussion
Drought stress is one of the most common stresses limiting crop productivity (Chaves et al., 2003). Cultivars can differ in their sensitivity to water deficit, being classified as tolerant or sensitive (Cabello et al., 2013; Obidiegwu et al., 2015). A few studies have been conducted on the physiological characterization of potato cultivars that are currently cultivated in the Andean region, under either irrigated or water deficit conditions (Tourneux et al., 2003a, b; Ramírez et al., 2014; Rolando et al., 2015; Ramírez et al., 2016). Neither is information available about the physiological effects of short periods of water deficit on potato. In his study we evaluated physiological parameters, and yield in three potato (S. tuberosum L.) cultivars commercially used in Colombia under a short period of water stress and recovery. One measurement related con the tolerance of the plants to water stress is leaf Ψw, because it indicates the water state and, therefore, the ability of the plant to take up water or conserve the amount it has (Hsiao, 1973). In this study, it was recorded that the three cultivars, DC, PS, and Es, presented a leaf Ψw close to -2.00 MPa in a short period of time. The Es cultivar took more time to reach this (6 d), followed by PS (5 d) and DC (4 d). The Es cultivar was the only one to equal the of the WW plants after 1 day of recovery (Fig. 2a). The values Ψw of leaf for the three cultivars were below those reported for potato crops at the permanent wilting point (-1.60 MPa) (Vos and Haverkort, 2007; Rolando et al., 2015). In many plants, the degree of decrease in leaf under drought stress conditions is related to the regulation of water loss through a reduction in gs (Liu et al., 2006; Osakabe et al., 2014). There was a decrease in gs in the three DS cultivars from 2 DAT below 0.05 mol H2O m-2 s-1 (Fig. 3B), wich suggests a regulation of water loss through a decrease in stomatal conductance, as has been observed in other plants, such as wheat (Triticum aestivum L.) (Siddique et al., 2000), cotton (Gossypium hirsutum L.) (Pallas et al., 1967), and sugarcane (Saccharum spp.) (Graca et al., 2010). The gs values we recorded are below the values that have been associated with metabolic impairment affecting photochemical and biochemical components of photosynthesis (Flexas et al., 2004, 2006). LT is usually negatively correlated with gs and E (Pallas et al., 1967; Graca et al., 2010). An increase in LT in the three DS cultivars was recorded when the values of gs and E were lowest (Fig. 3D). Differences in water stress tolerance between cultivars may be due in part to differential sensitivities of the photosynthetic process to water deficit (Chaves et al., 2002; Tourneux et al., 2003b; Ierna and Mauromicale, 2006). A and E were greatly influenced by stomatal behavior, decreasing in the DS cultivars (Fig. 3A, C), as has been described previously (Tourneux et al., 2003b; Liu et al., 2005; Ierna and Mauromicale, 2006). The fast recovery of the photosynthetic rate to values of WW plants (DC and Es cultivars) or very close to those values (PS cultivar) suggests that stomatal closure is the earliest response to water deficit and the dominant limitation of photosynthesis. The Es cultivar showed the lowest decrease in A under drought stress, wich suggests a lower sensitivity of its photosynthetic process to water deficit (Fig. 3A). A fast, full recovery of photosynthesis after re-watering has been reported in potato after irrigation deficit (Van Loon, 1981; Vos and Groenwold, 1989; Ramírez et al., 2016). It also was found that some drought stress-tolerant cultivars showed an increase in WUEi (Gago et al., 2014). The higher values of WUEi in DS Es (Fig. 4) are due to the lower reduction in photosynthesis that was recorded in this cultivar and could be related to tolerance (Liu et al., 2006; Ahmadi et al., 2010). The Fv/Fm values (0.81-0.91) observed in all cultivars (Fig. 5A) suggest the absence of any major impairment of the photosynthetic apparatus in the plants under DS and indicate resistance of the photosynthetic apparatus, as has been reported in previous studies (Moorby et al., 1975; Schapendonk et al., 1989; Tourneux et al., 2003b). However, the decrease in ETR, Y(II), and qP and the increase in NPQ in all DS cultivars (Fig. 5B-E) suggest a possible mild alteration in the phase of light-dependent reactions, which did not have a significant effect on the photosynthetic rate. Consequently, the main limitation was due to stomatal closure and not to an impairment of the photosynthetic apparatus (Ierna and Mauricale, 2006; Ahmadi et al., 2010).
It was observed that the DS Es cultivar showed an increase of Chl (Fig. 6A). Drought stress can reduce the final size of leaves of potato, and this effect varies among cultivars (Jefferies, 1993). The increase in Chl content found in Es could be associated with the decrease in leaf growth and water turgor loss, as has been described in potato (Teixeira and Pereira, 2007; Ramírez et al., 2014; Rolando et al., 2015). The DC and PS cultivars under drought stress did not exhibit differences in Chl compared to WW plants. These data could suggest that in these cultivars leaf growth and leaf turgor were less affected by water deficit, likely as result of the osmotic adjustment (Sánchez-Rodríguez et al., 2010; Farhad et al., 2011).
Carotenoids pigments are essential in photosynthesis. At the same time, they have a protective role in their ability to reduce the thermal effects of drought stress, and these pigments are also non-enzymatic antioxidants (Cruz de Carvalho, 2008; Farooq et al., 2009). An increase in Car content has been reported in many plants under stress conditions (Efeoglu et al., 2009; Ghobadi et al., 2013). Here, we found that all cultivars showed an increase in the Car content, which was highest in the Es cultivar under DS (Fig. 6B). The Car/Chl ratio in all cultivars under drought stress was also higher than that in WW plants. The Car content and Car/Chl ratio are correlated with the capacity of light protecting mechanisms (Boardman, 1977). These results suggest that the three cultivars have a strong photoprotective system against water stress, as has been described in other plants (Efeoglu et al., 2009; Ghobadi et al., 2013).
Another important parameter that is negatively affected during drought stress is the permeability of membranes, which is widely used to evaluate drought tolerance (Blum and Ebercon, 1981; Premachandra et al., 1991). For plants such as maize (Zea mays L.) (Quan et al., 2004) and wheat (Bajji et al., 2002), an increase in membrane permeability under drought stress has been reported, measured as EL. Here, an increase in EL from the second day of drought stress was recorded, which was greater when plants exhibited a more negative leaf Ψw (Fig. 7). This increase could be due to the peroxidation of lipids caused by an increase in ROS, as has been reported for plants such as tomato (Lycopersicon esculentum Mill.) (Sanchez-Rodríguez et al., 2010), cotton (Deeba et al., 2012), and potato (Farhad et al., 2011). It has been found that EL under stress conditions is mainly due to K+ and anion efflux (Bajji et al., 2002; Demidchik et al., 2014). Also, it has been hypothesized that the decrease in cytosolic K+ may be involved in metabolic adjustment, which is essential for adaptation to any stress factor (Demidchik et al., 2014).
Finally, drought stress can alter carbon allocation to different tissues (Chaves et al., 2002; Shao et al., 2008). This alteration in carbon partitioning could be related to mechanisms developed by the plant to cope with the stress, such as the increase in root size or the increase in the synthesis of different compounds involved in osmotic adjustment or in protection (Schafleitner et al., 2007; Obidiegwu et al., 2015). Some potato genotypes have the capacity to increase root size under drought stress, which might lead to a reduction in the canopy size and also to an increase in R/S (Steckel and Gray, 1979). We recorded that there was a decrease in the ABG in PS and Es cultivars under drought stress but not in the LA (Fig. 8A). We also found an increase in R/S in the Es cultivar under water deficit but not in RDM (Fig. 8c). These results show that the patterns of biomass partitioning among plants under DS and WW were not very different. In potato, severe water deficit can negatively affect Y if the stress occurs just before or during tuber initiation (Mackerran and Jefferies, 1986; Monneveux et al., 2013). Although the SMP reached values near -45 kPa for the three cultivars evaluated, which has been reported to cause water stress in this crop (Wang et al., 2007), Y was not reduced. The capacity to maintain Y under drought stress showed by the three cultivars suggests that these cultivars were tolerant to the drought stress (Obidiegwu et al., 2015).
Conclusion
It has been shown that the magnitude of drought stress on potato production depends on the phenological timing, duration, and severity of the stress (Jefferies, 1995; Monneveux et al., 2013). In this study the three cultivars showed physiological responses similar to those reported for potato plants subjected to longer periods of drought stress. The plants presented values of gs that have been associated with impairment of the photosynthetic apparatus (Flexas et al., 2004, 2006; Ramírez et al., 2016). However, we have not find a major impairment of the photosynthetic apparatus, and the plants showed a fast recovery of photosynthetic rate after 1 day of rehydration. We also observed in the plants of the three cultivars that under drought stress conditions there was not a reduction of Y. These results suggest that the three cultivars developed very early mechanisms to overcome the stress. One of these mechanisms could be the early synthesis of Car that we recorded in these cultivars. This could be an indicator of the high capacity of potato plants to maintain a functional photosystem II under drought stress with a photoprotective system. Although the exposure time to water stress was short, the plants showed indicators of stress and developed very early mechanisms associated with protection. Other experiments are needed to identify whether other mechanisms are present that might explain the response showed by these cultivars under water deficit, such as proline or antioxidant synthesis, both of which have already been described in potato (Schafleitner et al., 2007; Farhad et al., 2011). It is also necessary to explore the response of these cultivars to a longer period of water deficit to evaluate if they maintain the tolerance traits that they showed in this study.