Materials and methodsPlant material

Materials and methods
Plant material and greenhouse conditions
Based on previous studies (Calatayud et al., 2011), the drought tolerant accessions ‘ECU-973’ of Capsicum chinense Jacq. (code 12) and ‘BOL-58’ of Capsicum baccatum L. var. pendulum (code 14), and the water stress susceptible accessions ‘Piquillo de Lodosa’ ( code 8) and ‘Serrano’ of Capsicum annuum L. (code 5) were chosen as rootstocks in this study. The pepper cultivar ‘Verset’ ( California type; Rijk Zwaan) was grafted onto these four pepper accessions. The pepper seeds were sown on 1 December 2011 in 100- cell polystyrene trays filled with peat-based substrate and kept under a Venlo-type glasshouse. The plants were transplanted to 54- cell trays. The graft was performed on 12 February using the tube grafting method (cutting the growing tip of the rootstock at a 45◦ angle below the cotyledons, attaching the scion, previously cut at a 45◦ angle above the cotyledons, and fixing the rootstock and scion with a clip).
One month after grafting, the plants were placed in 5 L polyethylene pots covered with aluminum sheets (the root system having been previously washed clean of substrate). Pots were filled with a nutrient solution containing (in mmol L−1): 12.3 NO −; 1.02
3
2 + 2+ 2+
H2PO4−; 2.45 SO4 −; 3.24 Cl−; 5.05 K ; 4.23 Ca , 2.55 Mg and
micronutrients(15.8MFe2+,10.3MMn2+,4.2MZn2+,43.5M

B5+, 1.4M Cu2+) that had been artificially aerated. The electrical

conductivity and pH of this nutrient solution was 2.1dSm−1 and

6.5, respectively. Nutrient solution was added daily to compensate for absorption. After 7 days of seedling acclimation to the pots, PEG 8000 (Sigma Co.) was dissolved in a nutrient solution for inducing osmotic stress at 3.5% and 7% PEG. The osmotic potential of the solutions, measured with a vapor osmometer (Digital osmometer, Wescor, Logan, USA), were −0.35 and −0.77 MPa respectively. Nutrient solution (0% PEG) was approximately −0.05 MPa due to the presence of the nutrient salt.
The treatments were defined by three PEG levels (0%, 3.5%, and 7%) and four plant combinations (the cultivar ‘Verset’ grafted onto rootstock accessions 5, 8, 12 and 14). The grafted combinations (rootstock/cultivar) were labeled as: 5/cultivar, 8/cultivar, 12/cultivar and 14/cultivar. The ungrafted cultivar ‘Verset’ was used as control. The layout was completely randomized with three replications for each combination and six plants per replication.
All physiological measurements were performed at 7 (T1) and 14 (T2) days after PEG addition on a fully expanded mature leaf (third or fourth leaf from the shoot apex).
During the culture, plants were grown in a Venlo-type greenhouse under natural light conditions (610–870molm−2 s−1) and

temperature ranges were 21–24 ◦C; and relative humidity was 52 –72%.
Water relations
The osmotic potential of leaf sap (s in MPa) was measured using an osmometer (Digital osmometer, Wescor, Logan, USA). Two

independent determinations were performed on each replicate and plant combination, obtained from 6 plants per treatment and combination.
The leaves were tightly wrapped in aluminum foil, frozen at −80 ◦C, and stored in liquid nitrogen. After thawing, sap was collected from syringes at 25 ◦C and placed in the osmometer (Rodríguez-Gamir et al., 2010). Osmolyte content (mmolkg−1) was
converted to MPa using the Van’t Hoff equation. The osmotic adjustment (OA) was determined as the difference between the osmotic potential of the leaves at full turgor for control plants and the stressed plants (Garcia-Sanchez et al., 2007). Full turgor was achieved by rehydrating the leaves with distilled water in darkness for 24 h.
Six other similar leaves from two independent plants of each plant combination, PEG treatment, and replicate were collected to determine the (RWC) as (FW − DW)/(TW − DW) × 100 where FW is fresh weight, DW is dry weight, and TW is turgid weight.
Proline determination
Proline content was determined as described by Bates et al. (1973). Leaf pepper tissue (0.05 g) was ground in 3% sulfosalicylic acid, the homogenate was filtered, and 0.75 mL glacial acetic acid, and 0.75 mL ninhydrin reagent (1.25 g ninhydrin in 30 mL glacial acetic acid and 20 mL 6 N phosphoric acid) were added to an aliquot of the filtrate. The reaction mixture was boiled for 1 h, and readings were taken at a wavelength of 520 nm in a spectrophotometer. Three independent determinations were performed in three different extracts, obtained from 18 plants per treatment and combination (one leaf per plant or 500 mg (DW) of leaves, and six plants per extract).
Photosynthetic activity and chlorophyll fluorescence CO2 fixation rate (AN, mol CO2 m− s− ), stomatal conduc-
2 1
2 1
tance to water vapor (gs, mol H2O m− s− ), transpiration rate
2 1
(E, mmol H2O m− s− ), and substomatal CO2 concentration (Ci,
molCO mol−1 air) were measured at steady-state while main-
2
taining the plants at 1000molm−2 s−1 during 10–15min and

400 ppm CO2 with a LI-6400 (LI-COR, Nebraska, USA). Light curves were previously performed (data not shown) and AN was saturated at 900 mol m−2 s−1. Current fluorescence yield (F ) and
s
the maximum light adapted fluorescence were determined with the LI-6400 in the presence of an actinic illumination of 1000molphotonsm−2 s−1, and photochemical PSII efficiency

(PSII) was computed as the quotient (Genty et al., 1989).
To evaluate the presence of chronic photoinhibitory processes, the variable fluorescence ratio Fv/Fo = Fm − Fo/Fo (Babani and Lichtenthaler, 1996) was measured on leaves after 15 min in darkness using a portable pulse amplitude modulation fluorometer (PAM-2100, Walz, Effeltrich, Germany). The background fluorescence signal for dark adapted leaves (Fo) was determined with a 0.5molphotonm−2 s−1 measuring light at a frequency of 600Hz.

The application of a saturating flash of 10,000molphotonm−2 s−1
enabled estimations of the maximum fluorescence (Fm).
Gas exchange and fluorescence determinations were performed from 9:00 a.m. to 11:00 a.m. (GMT). One measurement per plant was performed, and ten different plants were used (n = 10) for each PEG treatment and plant combination.
Nitrate reductase activity
Nitrate reductase activity (EC 1.6.6.1) was determined in vivo following the methods described by Hageman and Hucklesby (1971) and Jaworki (1971). Discs of 1 cm diameter in mature fresh leaves, or pieces of 1 cm in roots, were punched out. Samples (200 mg) were suspended in a glass vial containing 10 mL of 100 mM potassium phosphate buffer (pH 7.5), 1% (v/v) npropanol and 100 mM KNO3. The glass vial was subjected to vacuum infiltration three times in order to induce anaerobic conditions in the incubation medium. Plant samples were incubated in a water bath at 30 ◦C for 60 min in the dark and placed in a boiling water bath for 5 min to stop enzymatic reaction. Nitrite released from plant material was determined colorimetrically at 540 nm (spectrophotometer PerkinElmer, Lambda 25) by adding 0.02% (w/v) N-naphthylethylenediamine and 1% sulphanilamide. A standard curve with KNO2 was prepared to calculate the amount of NO2 contained in the samples (Calatayud et al., 2008). Sampling and replicates were used as described for proline determination.

ungrafted pepper plants (cultivar ‘Verset’) and cultivar grafted onto accessions 5 , 8, 12 and 14. Dates are mean values ± SE for n = 6. Within each plant combination different letters indicate significant differences at P < 0.05 (LSD test).
Lipid peroxidation
Lipid peroxidation was estimated through malondialdehyde (MDA) determinations using thiobarbituric acid reaction, according to the protocol reported by Heath and Packer (1968), and modified in Dhindsa et al. (1981). The non-specific background absorbance reading at 600 nm was subtracted from specific absorbance reading at 532 nm. Sampling and replicates used as described for proline determination.
Statistical analyses
The results were subjected to multifactor variance analysis (Statgraphics Centurion for Windows, Statistical Graphics Corp.). The effect of the genotype and stress level was estimated and significant interactions (genotype × stress level) were observed for all the analyzed parameters. The mean comparisons were performed using Fisher’s least significance difference (LSD) test at P < 0.05.