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Article

Stomatal Behavior of Cowpea Genotypes Grown Under Varying Moisture Levels

1
Risk and Vulnerability Center, University of Limpopo, P Bag X1106, Sovenga 0727, South Africa
2
Faculty of Bioscience Engineering, Ghent University, B-9000 Gent, Belgium
*
Author to whom correspondence should be addressed.
Sustainability 2018, 10(1), 12; https://doi.org/10.3390/su10010012
Submission received: 13 October 2017 / Revised: 13 December 2017 / Accepted: 17 December 2017 / Published: 23 December 2017
(This article belongs to the Section Sustainable Agriculture)

Abstract

:
Drought is a major limitation to crop productivity worldwide. Plants lose most of their water through stomata, thus making stomata an important organ in the control of transpiration and photosynthesis. This study assessed the stomatal behavior of four cowpea genotypes grown under four moisture levels under hot semi-arid conditions. Stomatal conductance (gs) was measured at 47, 54, 70 and 77 days after planting (DAP). Biomass and carbon isotope composition (δ13C) were also determined at flowering. Genotype and moisture level significantly influenced gs. Genotypes varied in gs at vegetative stages (47 and 54 DAP) only. TVu4607 had higher gs under severe drought conditions at both 47 and 54 DAP. On the other hand, moisture level influenced gs at 54 and 70 DAP only. Stomatal conductance was severely restricted in cowpea under both moderate and severe drought conditions as gs was mostly below the threshold 0.10 mol m−2 s−1. Relationships between: biomass and gs, and δ13C and gs were positive under severe drought only. The findings revealed that cowpea genotypes vary in gs under dry conditions and that the variation is more prominent at vegetative stage, suggesting that cowpea productivity in dry areas could be improved through selection of genotypes that maintain higher gs under dry conditions.

1. Introduction

Water use efficiency (WUE) and crop productivity strongly depend on stomatal conductance (gs) of the crop. The opening and closing of the stomata, which is mainly affected by water availability [1], not only influence the amount of CO2 that diffuses into the leaf for photosynthesis but also the amount of water lost through the leaf [2]. Thus, the compromise between water loss and carbon gain determines WUE of a crop and is influenced by the stomatal response to environmental conditions [3]. Stomatal conductance thus plays a particularly important role of controlling water loss in crops grown in dry areas.
Cowpea is an important legume for smallholder farmers in arid and semi-arid regions of Africa. It is commonly grown in hot and dry areas where evaporative demand is high. Therefore, understanding the behavior of the stomata in cowpea is vital for improving its productivity and its adaptation to future drier climates.
The occurrence of droughts in semi-arid areas where cowpea is commonly grown is expected to increase [4] and this will negatively affect cowpea productivity. To maintain acceptable levels of crop productivity in such environments, there is a need to develop drought tolerant cultivars that use water efficiently [5]. The improvement of drought resistance in cowpea is only possible if there is a better understanding of its physiological responses to limited water supply. One of the primary physiological responses with a significant role in drought resistance is gs. Stomatal conductance is also believed to be a reliable integrative indicator of water stress [6] even though patchy gs could present challenges [7,8]. It is also important to develop a proxy for WUE to facilitate breeding.
WUE has been proposed to be strongly related to the adaptation of crops to drought [9] and can be measured as a ratio of biomass accumulation to the amount of water transpired/used. Alternatively, it can also be measured at leaf level as the ratio of photosynthetic rate (A) to gs [10], commonly referred to as intrinsic WUE (WUEintrinsic). The integration of WUEintrinsic over time can be estimated through carbon isotope composition [6,11]. Carbon isotope composition has also been shown to be related to WUE [12]. According to Bloch, Hoffmann [13], plants with a lower 13C-CO2 discrimination tend to be efficient water users. The advantage of measuring carbon isotope composition is that it provides an integrated measure of the plant’s growing conditions as opposed to instantaneous measurements provided by gs measurements.
Against this background, it is, therefore, important to elucidate the role of gs and carbon isotope discrimination on drought resistance and productivity of cowpea. This study therefore seeks to establish (1) how gs in cowpea is influenced by genotype and moisture level (2) how gs evolves with time under varying moisture levels. The study also seeks to establish whether there is any correlation between dry biomass accumulation and gs and whether carbon isotope composition (which provides an integration of gs and A) is related to cowpea productivity and WUE.

2. Materials and Methods

2.1. Plant Growth Conditions and Experimental Design

A two-year field research was carried out at the University of Limpopo experimental farm, Syferkuil (23°50′ S, 029°41′ E) in the Limpopo Province, South Africa. In the first year, cowpea was planted on the 2 January 2015 while in the second experiment, planting was on the 22 December 2015. The differences in planting dates were mainly a result of logistics. The average daily temperature during the growing season at Syferkuil ranges from 12 to 35 °C.
Four genotypes; IT00K-1263, IT99K-1122, TVu14632 and TVu4607 were used in the experiments and abbreviated as IT1, IT2, TV1 and TV2, respectively. The lines were sourced from the International Institute of Tropical Agriculture (IITA) in Nigeria. The lines were selected from a pool of 91 that were pre-screened earlier for high grain and biomass yield in Limpopo over a period of two years. In the first season, all 91 lines were grown under rain fed conditions and the best eight performing lines in terms of grain and biomass yield were selected. In the subsequent season, the eight lines were further grown under rain fed conditions and four lines with high grain yield and biomass were selected for further investigation. In both pre-screening seasons cowpea was sown later in the season to induce water stress conditions through reduced rainfall.
Cowpea was planted in rows, 0.9 m apart with in row spacing of 0.20 m, without inoculation and depended on the resident Bradyrhizobia population for nodulation. The plot sizes were 10 m × 10 m and irrigation was by Rain Bird sprinklers (Rain Bird, Azusa, CA, USA), fitted with Arad M20 water meters (Arad Group, Arad, Israel) to record the amount of water applied. In addition, rain gauges were installed at the center of each plot. Soil moisture was measured three to four times a week using a capacitance sensor; Diviner 2000 (Sentek Technologies, Stepney, Australia) from access tubes installed at the center of each plot. Irrigation was applied when half of the plots under the same moisture level reached the threshold value. The soil was classified as a Chromic Luvisol (Hypereutric) [14]. The soil depth ranges from 60–70 cm, with sandy clay loams overlaying sandy clays and an available water capacity (AWC) of 80 mm.
The four genotypes were examined under four moisture levels in a split-plots and four replications. The main plot treatment was the irrigation level and the subplot, cowpea lines. The four moisture levels were as follows:
  • Well-watered (WW): 25% soil moisture depletion before recharging to field capacity (FC);
  • Moderately well-watered (MW): 50% soil moisture depletion before recharging to FC;
  • Moderate drought (MD): 75% soil moisture depletion before recharging to 50% of FC;
  • Rainfed (severe drought; SD): the crop depended solely on rainfall. However, in the 2016 season, the plots were irrigated at the beginning to establish the experiments as the rainfall was too low at the start of the season.
Due to unexpected rainfall interferences, the moisture levels could not be maintained throughout the 2016 growing season. However, in the 2015 season, the moisture levels were maintained for most parts of the growing season due to reduced seasonal rainfall and longer drought period experienced. The amounts of water received (irrigation + rainfall) by the crop at flowering and harvesting stages for the different moisture treatments is shown in Table 1. Cowpea grown under water-limited conditions flowered much earlier compared to the cowpea grown under well-watered conditions. These differences were more pronounced in 2015 compared to 2016. In addition, cowpea took longer to reach gravest maturity in 2016 compared to 2015 due to the availability of more moisture.
The AWC was estimated using the hydraulic properties calculator [15]. Before the first planting, composite top soil samples (0 to 30 cm) were analyzed for pH, organic carbon (OC), electrical conductivity (EC) and macronutrients. The soils had a pH (H2O) of 8.1, 500 mg N kg−1, 18.7 mg P kg−1, 369 mg K kg−1, 1008 mg Ca kg−1, 710 mg kg−1, 33 mg Na kg−1 and OC of 0.5%. The EC measured before the start of the experiments was 82 µS cm−1 with an exchangeable sodium percentage (ESP) of 4 making it a non-saline soil. The soils were then fertilized with single super phosphate (10.5%) at a rate of 35 kg P ha−1. The same rate of P was applied in the subsequent year.

2.2. Plant Harvesting and Sample Preparation

Biomass at 50% flowering (i.e., time when half of the plants had flowered) was harvested from a 0.9 m2 area (equivalent to four plants per plot) from all plots on the same day in each year while grain yield was determined at harvest maturity from four middle rows of 2 m length each (equivalent to 40 plants per plot). Shoot biomass at flowering was collected by cutting the main stem at 3 cm above the ground, leaving small stumps. Root biomass was then sampled by first watering the soil around the stumps to avoid root hair and nodule loss. Basins were made around the harvest area (about 0.36 m2) and then watered using canes. Water was applied to the small harvest area only. As described the plots were 100 m2 in size hence the watered area did not disturb the moisture treatments. The watered area was then left for 24 h to allow infiltration before carefully digging out the stumps using spades. The roots were then washed with water on a sieve to remove bound soil particles and collect root biomass. Shoot and root dry biomass was then determined by oven drying the samples at 65 °C to constant weight. Grain yield was harvested at full maturity on different days for the different moisture as cowpea reached maturity at different times. The time when the first harvest was done in each year is shown by the big arrows on Figure 1.

2.3. Leaf Gas Exchange Measurements

Leaf gas exchange (stomatal conductance (gs), photosynthetic rate (A) and transpiration rate (E)) measurements were carried out using LCi-SD Ultra Compact Photosynthesis System (ADC Bio Scientific, Hoddesdon, UK). The photosynthesis machine does not provide control of CO2, temperature or relative humidity but rather uses ambient conditions. The measured ambient CO2 ranged from 380 to 395 ppm, chamber temperature from 30 to 36 °C while ambient relative humidity averaged from a minimum of 35% and a maximum of 93% over the growing period. The measurements were taken four times in the first season on clear sunny days between 11h00 and 13h00. The measurements were taken at 47, 54, 70, and 77 days after planting (DAP) in 2015. In 2016, the measurements were taken only once at 70 DAP due to malfunctioning of the machine. The measurements were done on a single youngest fully matured leaf per plot.

2.4. Isotope Analyses

For isotope analyses, five to ten young fully grown leaves (depending on the size) were randomly sampled from different plants per plot at 50% flowering. The leaves were dried at 65 °C to constant weight and ground to a fine powder using a ZM200 mill (Retsch, Haan, Germany). The 13C/12C isotope compositions of the leaves were analyzed using an Automated Nitrogen Carbon Analyser—Solid and Liquids (ANCA-SL) (SerCon, Crewe, UK) interfaced with an Isotope Ratio Mass Spectrometer (IRMS) (20-20, SerCon, Crewe, UK). The isotope composition was reported as δ13C in ‰ using Vienna Pee Dee Belemnite (V-PDB) as international standard (Rstandard) and calculated using the formula below:
δ 13 C sample = ( R sample R standard 1 ) × 1000

2.5. WUE Determination

WUE of biomass (WUEbiomass) was calculated as the ratio of shoot biomass to total amount of water used. The total amount of water added was obtained from the summation of the rain gauge recordings from planting to flowering. At leaf level, intrinsic WUE (WUEintrinsic) was calculated as follows: WUEintrinsic = A/gs where A is the photosynthetic rate, and gs is the stomatal conductance. A and gs were obtained from the measurements of the Photosynthesis System described under 2.3.

2.6. Statistical Analyses

The analysis was conducted in accordance with the standard procedure for analysis of variance (ANOVA) of a split plot design with irrigation as the main plot and genotypes as sub-plots [16]. The ANOVA was performed to calculate the effects of moisture level, genotype and time (i.e., DAP) on the studied parameters. Where the interaction effect was not significant, data was split according to moisture level and analyzed for the effect of genotype at each moisture level (for some parameters). Post hoc multiple comparisons for observed means was done using Tukey and different means were denoted by *, ** or *** for significance levels p ≤ 0.05, p ≤ 0.01 and p ≤ 0.001, respectively. Bivariate Pearson Correlation was carried out to assess the relationship between gs and δ13C and between gs and biomass. All data were analyzed using the SPSS 20 statistical package (SPSS, Armonk, NY, USA).

3. Results

3.1. Rainfall Distribution and Amount

The distribution of daily rainfall received during the two growing seasons as well as the cumulative amount of water applied is shown on Figure 1. Time to physiological maturity varied with moisture levels in both years. The total amount of water received from planting to last harvesting was 121 mm in 2015 and 299 mm in 2016 (Table 1). No significant rains were received in the immediate period before and after planting in 2016, hence the crop was irrigated to establish the experiment. At the time of biomass collection (short arrows), a total of 73 mm was received in 2015 while at the same stage 218 mm (rainfall + irrigation) had been received in 2016. Furthermore, the rainfall distribution differed between the two seasons. A longer mid-season dry period was experienced in 2015 compared to 2016. Soon after the dry period in 2016, 126 mm of rain was received in ten days when the cowpea was still flowering while much of the late rain received in 2015 came when most of the cowpea had reached physiological maturity. The cumulative amount of rainfall and irrigation differed with moisture levels in 2015 as shown by the bottom left panel. However, in 2016, differences were only observed between well-watered (WW and MW) and water-limited conditions (MD and SD). It must be noted that there were some significant rains received after harvesting of cowpea under MD and SD in 2015.

3.2. Genotypic Variation in Stomatal Conductance with Time and Moisture Level

Stomatal conductance measured in 2015 varied with genotype, moisture level, DAP and the combined effect of moisture and DAP. Due to the interaction between moisture level and DAP, Figure 2 shows gs data separated according to moisture level and showing the effects of genotype and DAP. Genotypes varied in gs before flowering i.e., at 47 and 54 DAP but neither at flowering (70 DAP) nor just after flowering (77 DAP) (Figure 2). Similarly, no genotypic variations in gs were observed in 2016, where gs measurements were only carried out at 70 DAP (results not shown). At both 47 and 54 DAP, significant variations in gs were mainly observed under limited water supply (MD and SD). Under SD conditions, genotype TV2, had significantly higher gs compared to the other genotypes at 47 DAP while it only differed with IT2 under the same moisture level at 54 DAP. However, under MW, genotype IT1 performed much better than the other genotypes at 47, 54 and 70 DAP. Moisture levels on the other hand, significantly influenced gs at 54 and 70 DAP but had no influence at 47 and 77 DAP (Figure 2). Generally, gs was higher under well-watered conditions (WW and MW) compared to water-limited conditions (MD and SD). At 54 DAP, gs was higher under WW compared to both MD and SD but did not differ with MW. A similar trend was also observed at 70 DAP. Figure 2 also shows how gs of the genotypes evolved with DAP at each moisture levels with a control line at 0.10 mol m−2 s−1 showing the threshold value below which photosynthesis is believed to be affected as described by Flexas et al. [17]. The figure shows that under WW, gs was above the threshold at 47, 54 and 70 DAP and was only below the threshold at 77 DAP. Under MW, only IT1 maintained gs at above the threshold until 70 DAP. However, under SD, all genotypes had gs below the threshold except for TV2 at 47 DAP. Genotype TV2, even though below 0.10 mol m−2 s−1, it maintained a relatively higher gs compared to the genotypes. However, under SD, gs was mostly below 0.05 mol m−2 s−1.

3.3. Evolution of Leaf Gas Exchanges with Time under the Four Moisture Levels

The progression of cowpea mean stomatal conductance (gs), photosynthetic rate (A), transpiration rate (E) and the ratio of inter-cellular CO2 concentration to ambient CO2 (ci/ca) (averaged across genotypes) with DAP is shown on Figure 3. Moisture level significantly influenced the progression of measured gas exchange parameters. Cowpea grown under well-watered conditions had high values of the gs, A and E compared to those grown under water-limited conditions. At higher moisture levels (WW and MW), an initial increase in gs, A, and E was observed from 47 to 54 DAP followed by a gradual decrease from 54 through 70 to 77 DAP. At lower moisture levels (particularly under SD), no initial increase in gs, A, and E was observed but rather a steady decrease with time from the first measurement (47 DAP) to the last (77 DAP). Differences in gs, A, and E resulting from the effect of moisture levels were more distinct at 54 DAP. Differences in gs, A, and E were mainly significant between WW and SD. Remarkably, even though high moisture levels were maintained under WW, gs, A, and E still decreased with DAP from 54 DAP onwards. The variation of A and gs with time and moisture levels was very similar and strongly related (Table 2).

3.4. Relationship between gs Measured at 47 DAP, Biomass and Δ13c

Figure 4 shows the relationship between gs and biomass, and between gs and δ13C during the early growth stages of cowpea (47 DAP) as affected by the four moisture levels. Figure 5 on the other hand shows the relationships of genotypic averages demonstrating how gs of the four genotypes was related to biomass, δ13C, root biomass and grain yield. The results showed no significant relationships between dry biomass accumulated prior to flowering (i.e., 47 DAP) and gs measured under WW, MW and MD conditions. A similar relationship was also observed with leaf δ13C. However, under rain fed (SD), positive relationships were observed between gs and dry biomass (r2 = 0.58, p < 0.05) as well as between gs and δ13C of leaves sampled at flowering stage (r2 = 0.60, p < 0.05). Cowpea grain yield, was also positively related to gs at 47 DAP under SD (r2 = 0.50, p < 0.05) and under WW (r2 = 0.64, p < 0.01). The overall relationships: gs and biomass; gs and root biomass; gs and grain yield were mostly positive when data for all moisture levels were combined while that of δ13C and gs was mostly negative (Figure 5). Similar relationships were also observed with gs measurements taken at 70 DAP (Figure A1). Where relationships were significantly positive, genotype TV2 performed much better compared to the others. Figure 5A,D shows that TV2 had significantly higher aboveground biomass, root biomass and gs under SD conditions. In Table 2 the relationship between gs measured at 70 DAP and δ13C was strongly negative in both years (2015 = −0.49 ** and 2016 = −0.78 **).

3.5. Genotypic Variation in Δ13c with Moisture Level

The variation in δ13C measured in leaves at the flowering stage is shown on Figure 6. The results show that moisture level significantly influenced leaf δ13C in both seasons (2015 and 2016), but genotypic effects were not observed. No differences in leaf δ13C values were observed for cowpea grown under MD and SD in both seasons. In both seasons, there were clear differences between leaf δ13C grown under well-watered conditions (WW and MW) and those under water-limited conditions (MD and SD). Thus, cowpea discriminated more against 13C-CO2 when soil moisture was more readily available compared to when the soil moisture was limited, resulting in more negative δ13C values being observed under well-watered conditions. In the first season, differences in leaf δ13C values were also observed between WW and MW. In 2015, average δ13C values were −25.6‰ under WW and −24.3‰ under SD while in 2016 the averages were −26.9‰ under WW and −24.7‰ under SD. Due to the higher rainfall received in 2016, cowpea discriminated more against 13C in 2016 compared to 2015.

3.6. WUEbiomass and WUEintrinsic as Influenced by Moisture Level

WUEbiomass varied with moisture level in 2015 but not in 2016 (Figure 7). Likewise, genotypes had a significant effect on WUEbiomass only in the 2015 growing season and not in 2016. The interaction effect between moisture level and genotype was not significant in both years. In 2015, a general increase in mean WUEbiomass with decreasing moisture level was observed where WUEbiomass was higher under SD followed by MD and then MW and WW. Average WUEbiomass of 26.8 kg ha−1 mm−1 was observed in cowpea grown under SD compared to 18.0 kg ha−1 mm−1 observed under WW. Genotypic variations in WUEbiomass were observed in 2015 and where only significant under WW and SD. Under SD, TV2 had the highest WUEbiomass of 38.6 kg ha−1 mm−1 while the other three genotypes did not vary with WUEbiomass values ranging from 21.4 to 24.8 kg ha−1 mm−1. Under WW, TV2 maintained a higher WUEbiomass (in magnitude) followed by IT2, while TV1 had the lowest WUEbiomass. Even though no genotypic differences were observed in the 2016, however in magnitude, TV1 consistently had the lowest WUEbiomass under all moisture level. On average, WUEbiomass was significantly lower in 2016 compared to that of 2015. When data for all moisture levels were averaged, TV2 had significantly higher WUEbiomass compared to the other three genotypes in 2015. When correlated to the measured gas exchanges, WUEbiomass did not show any significant relationship with the measured gas exchange parameters in both seasons (Table 2). No significant relationship was also observed between WUEintrinsic and WUEbiomass.
WUEintrinsic was also influenced by moisture levels in both seasons. No genotypic differences were observed and the interaction between moisture and genotype was also not significant. WUEintrinsic was higher under water-limited conditions (MD and SD) compared to well-watered conditions (MW and WW). In 2015, further differences were also observed between MD and SD. WUEintrinsic ranged from 120 to 200 µmol mol−1 in 2015 while in 2016 it ranged from 133 to 189 µmol mol−1. Genotypes did not vary in WUEintrinsic at each moisture level and this was observed in both seasons. Even when data for all moisture levels were combined the genotypes still did not show any differences in WUEintrinsic as was observed with WUEbiomass. WUEintrinsic was also negatively related to gs, A, E and ci/ca in both seasons (Table 2). In addition, WUEintrinsic was positively related to δ13C.

4. Discussion

4.1. Variation in Leaf Gas Exchange with Genotype, Moisture Level and DAP

The study has shown that soil moisture significantly influences leaf gas exchanges in cowpea. Stomatal conductance, A and E were found to be high under higher moisture level compared to lower moisture levels (Figure 2 and Figure 3). Such results were expected and agree with the findings of similar studies [6]. It was also interesting to note that genotypes only varied in gs during the early growth stages but not in the later stages. A plausible explanation for such a variation could be differences in root establishment, where genotypes that establish their roots faster would have much more access to water, resulting in high leaf water content and hence higher gs. Agbicodo, Fatokun [18] reported that plants that maintain higher tissue water potential under low water availability can do so by developing efficient root system that maximizes on water uptake.
Accordingly, it can be postulated that the high gs of TV2 at 47 and 54 DAP under SD (Figure 2) may have resulted from a stronger and a more efficient rooting system (Figure 5D) that enabled it to tap water efficiently early in its growth. Even though TV2 was superior in biomass and root biomass under SD, the grain yield observed at the same moisture level was not congruent with the high biomass observed. Interestingly, at both 47 and 54 DAP genotypes did not vary in gs under WW conditions but showed much variation under lower moisture levels (MW, MD and SD). This could probably be due to the easily available moisture that allowed the genotypes to absorb enough moisture to keep stomata open. This probably suggests that, gs variation in cowpea genotypes may be more determined by root characteristics rather than by leaf characteristics. Under MW and MD, IT1 and TV2 consistently revealed higher gs compared to the other two genotypes (IT2 and TV1). However, under SD, TV2 maintained relatively higher values of gs, which were significant at 47 DAP. The results suggest that TV2 probably has the capacity to establish an efficient rooting system very early in the season. In a separate study, TV2 was found to have significantly higher root biomass compared to the other genotypes [19].
Genotypic differences observed in gs under low water availability could be due to differences in the response mechanisms to water deficit. Genotypes with higher capacity to establish efficient rooting system, may show drought tolerance by maintaining relatively higher gs, E an A while those weakly established rooting system, may show drought avoidance by closing their stomata, hence low gs, E and A. IT1 and TV2 displayed strong drought tolerance tendencies under moderate drought (MD) at 47 and 54 DAP. Stomatal conductance of TV2 under MD was similar to its gs under MW while other genotypes had significantly lower gs at MD compared to MW. Stomata of cowpea are also known to be sensitive to soil drying [9], and thus the cowpea plant normally exhibits drought avoidance mechanism [20,21]. The drought avoidance mechanism could explain lower gs across all moisture levels exhibited by IT1, IT2 and TV1 at 54 DAP.
While genotypic differences in gs were observed at 47 and 54 DAP, the soil moisture effect was observed at 54 and 70 DAP (Figure 2). The lack of moisture level effect at 47 DAP is difficult to explain but the differences might have been masked by the higher gs displayed by TV2 and IT1 under MD and SD. The lack of moisture level effect on gs at 77 DAP was probably due to crop aging. Stomata conductance values observed at 77 DAP were significantly low, mostly below 0.05 mol m−2 s−1 (Figure 2 and Figure 3). Figure 3 shows a gradual decrease in gs with DAP even under WW, which supports the idea of plant aging. In addition, stomata are generally known to be more open early in the season than at its end [22] hence the decrease of gs with DAP. Another interesting observation was the gs observed under WW in this study were relatively lower than those observed in intercropped sorghum and cowpea [23] and in sugar beet [13]. However, they were in the same range as those reported by [24] in cowpea and by [25] in wheat.
The strong relationship observed between gs and A (r2 = 0.90, p < 0.01) suggests that CO2 assimilation in cowpea is controlled by stomatal effects. However, the water stress may not have been severe enough to induce non-stomatal effects on photosynthetic processes. The control of gs on A is also confirmed by the identical evolution of A and gs with time (Figure 3). Similar results have also been reported in other legume studies [26]. Transpiration rate related strongly with gs (r2 = 0.97, p < 0.01, 2015 season). Flexas et al. [17], reported that photosynthesis is affected when gs goes below 0.10–0.15 mol m−2 s−1. In this study, cowpea grown under rain fed conditions (SD) and under MD had gs values lower than 0.10 mol m−2 s−1 for most of their growing period (Figure 2 and Figure 3). This, therefore, suggests that cowpea grown in semi-arid regions are likely photosynthesizing at sub-optimal levels throughout their life cycle. In addition, Table 1 shows that time to flowering and maturity were shortened by water availability. As a result, biomass and grain yield observed in 2015 were significantly lower under SD, an indication of the suppressed photosynthetic rate as well limited time for biomass accumulation and grain filling. Thus, improvement in cowpea stomatal conductance could increase productivity of cowpea under dry conditions. TV2 and IT1 where the only genotypes that maintained gs values above 0.10 mol m−2 s−1 under moderate drought (MD) until 54 DAP.
δ13C, which provides an integration of the environmental conditions during the period of CO2 assimilation [6], differed with moisture level. δ13C values were more negative under well-watered conditions compared to water-limited conditions, which corroborates the findings of many other studies on C3 plants [13,27,28]. Less negative δ13C values under SD were attributed to lower 13C discrimination due to the partial closure of the stomata occurring under soil drying. The influence of gs and A on δ13C is confirmed by the strong negative relationship between δ13C and, A and gs (Table 2). The relationship between gs at 47 DAP and δ13C showed a positive relationship under SD only (Figure 4). The positive relationship seems to suggest the existence genotypic variation in leaf δ13C of cowpea grown under SD conditions, whereby genotypes that show higher gs would have less negative δ13C values. However, the observed results did not show significant genotypic variation in δ13C under SD (Figure 6). Figure 2 shows that TV2 had significantly higher gs under SD at 47 DAP but this did not translate to significantly higher δ13C (Figure 6).

4.2. Relationships of WUEbiomass and WUEintrinsic as Influenced by Moisture Level

Higher WUE is regarded as an important factor in improving crop performance under water-limited conditions [29]. WUE can be measured or estimated in several ways as described by Tambussi, Bort [11]. In this study, WUE was measured in terms of: biomass accumulation (WUEbiomass); as gas exchange (WUEintrinsic) and estimated δ13C data. The results showed strong influence of moisture level on all three (WUEintrinsic, WUEbiomass and δ13C). It was observed that WUEintrinsic, WUEbiomass and δ13C were all higher under water-limited conditions (Figure 6 and Figure 7) agreeing with the findings of Bloch, Hoffmann [13] who also found higher WUE under water-limited conditions. However, other studies are contrary to such findings [30]. The lack of differences in WUEbiomass in 2016 may be attributed to the relatively higher rainfall received in that year. It is believed that under well-watered conditions plants continue to assimilate carbon even when evaporative demand is very high resulting in higher losses of water per carbon gained, leading to lower WUEbiomass [13]. Under water-limited conditions crops only assimilate carbon when evaporative demand is low, hence loses less water per carbon gained [13].
Similarly, WUEintrinsic was higher under water stressed conditions due to differences in the rate of decrease between A and gs. When stomata are partially closed, the photosynthetic rate does not immediately decrease, resulting in higher WUEintrinsic [6]. Also, WUEintrinsic increases when A increases at a constant gs [21]. There was no significant relationship between WUEbiomass and WUEintrinsic, probably because WUEintrinsic is an instantaneous measurement that reflects conditions prevailing at the instant of measurement while WUEbiomass is an integration of the conditions from sowing to the time of biomass sampling. δ13C, which provides an integration of WUEintrinsic overtime was positively related to WUEbiomass in 2015. The strong relationship shows that δ13C can be used as a surrogate of WUEintrinsic in cowpea. Similar conclusions have also been drawn in other studies [31].

5. Conclusions

In conclusion, the findings of this study showed that gs responded to genotypic variation, moisture levels and to the time of measurement. Variation in genotypes varied at early vegetative stages and mostly under water-limited conditions, with genotype TVu4607 (TV2) showing much higher gs under SD. As expected, gs was higher under well-watered conditions compared to water-limited conditions but it was interesting to note that, gs still decreased with DAP even under WW conditions. This study also showed that gs is severely restricted in cowpea grown in semi-arid areas as gs under MD and SD were mostly below 0.10 mol m−2 s−1. Thus, improving gs of cowpea grown in such areas could improve its productivity. The use of δ13C in screening for high WUE in cowpea maybe limited as it only responded to moisture level and not to genotype. However, the highly significant and positive relationship observed between δ13C and gs under SD suggest that δ13C could be useful as a screening trait for higher gs in cowpea under drought conditions.
The findings of this study were however constrained by the high rainfall received later in 2016 that reduced the moisture levels to two, thus failing to completely replicate the four levels observed in 2015. Another limitation of the study is in the reduced number of gas exchange measurements (gs, A, E and ci/ca) taken per plot. These are instantaneous measurements that would require several measurements per plot. However, due to the large number of the experimental plots and the limitation in the time and conditions to which measurements can be carried out, a reduced number of measurements per plot were taken to accommodate all plots within the recommended period.

Acknowledgments

This work was financially supported by VLIR-IUC, an Inter University Cooperation with University of Limpopo (UL), South Africa under Project 6 on Food Security. The authors would also like to acknowledge support from the Risk and Vulnerability Science Centre at UL. The following people are also acknowledged for their contribution to the work: Katja Van Nieuland, LouisEloff, and Jimmy Motloutsi.

Author Contributions

Lawrence Munjonji, Kingsley K. Ayisi, Pascal Boeckx and Geert Haesaert conceived and designed the experiments; Lawrence Munjonji performed the experiments; Lawrence Munjonji analyzed the data; Lawrence Munjonji, Kingsley K. Ayisi, Pascal Boeckx and Geert Haesaert contributed towards the writing and editing of the paper.

Conflicts of Interest

The authors declare no conflict of interest.

Appendix A

Figure A1. The relationship between genotypic means of stomatal conductance (gs) measured at 70 DAP and mean biomass (A), root biomass (at flowering) (B), δ13C (C) and grain yield (D). Means were calculated per moisture level i.e., blue for well-watered; green for moderate well-watered; yellow for moderate drought and red for severe drought. Symbols: circle for genotype IT1, triangle for IT2, rectangle for TV1, and diamond for TV2.
Figure A1. The relationship between genotypic means of stomatal conductance (gs) measured at 70 DAP and mean biomass (A), root biomass (at flowering) (B), δ13C (C) and grain yield (D). Means were calculated per moisture level i.e., blue for well-watered; green for moderate well-watered; yellow for moderate drought and red for severe drought. Symbols: circle for genotype IT1, triangle for IT2, rectangle for TV1, and diamond for TV2.
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Figure 1. Top panel: Daily rainfall received during the two growing seasons, starting in December of previous year until harvest (2015-black bars and 2016-grey bars). Set of arrows: (a) sowing day (b) biomass collection at 50% flowering and (c) long arrows first harvesting dates (2015-black arrows; 2016-gray arrows). Bottom panels show cumulative rainfall plus irrigation for the two years (2015 on the left and 2016 on the right).
Figure 1. Top panel: Daily rainfall received during the two growing seasons, starting in December of previous year until harvest (2015-black bars and 2016-grey bars). Set of arrows: (a) sowing day (b) biomass collection at 50% flowering and (c) long arrows first harvesting dates (2015-black arrows; 2016-gray arrows). Bottom panels show cumulative rainfall plus irrigation for the two years (2015 on the left and 2016 on the right).
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Figure 2. Variation in genotypic stomatal conductance with DAP at different moisture levels (well-watered (WW), moderately well-watered (MW), moderate drought (MD) and severe drought (SD) for data measured in 2015. IT1, IT2, TV1 and TV2 are the genotypes. The ANOVA table shows the effects of genotypes (G), Moisture level (M), Time of measurement as DAP as well as their interaction effects. Error bars are stander error of mean. The line at 0.10 mol m−2 s−1 is a control line showing the threshold value below which photosynthesis is affected as described by Flexas et al. [17].
Figure 2. Variation in genotypic stomatal conductance with DAP at different moisture levels (well-watered (WW), moderately well-watered (MW), moderate drought (MD) and severe drought (SD) for data measured in 2015. IT1, IT2, TV1 and TV2 are the genotypes. The ANOVA table shows the effects of genotypes (G), Moisture level (M), Time of measurement as DAP as well as their interaction effects. Error bars are stander error of mean. The line at 0.10 mol m−2 s−1 is a control line showing the threshold value below which photosynthesis is affected as described by Flexas et al. [17].
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Figure 3. Mean stomatal conductance (gs), photosynthetic rate (A), transpiration (E), and ratio of intercellular CO2 concentration (ci) to ambient CO2 concentration (ca) of four cowpea genotypes under four moisture levels (well-watered (WW), moderately well-watered (MW), moderate drought (MD) and severe drought (SD)) measured at 47, 54, 70 and 77 days after planting (DAP). Errors bars indicate standard error of means.
Figure 3. Mean stomatal conductance (gs), photosynthetic rate (A), transpiration (E), and ratio of intercellular CO2 concentration (ci) to ambient CO2 concentration (ca) of four cowpea genotypes under four moisture levels (well-watered (WW), moderately well-watered (MW), moderate drought (MD) and severe drought (SD)) measured at 47, 54, 70 and 77 days after planting (DAP). Errors bars indicate standard error of means.
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Figure 4. The relationship between stomatal conductance (gs) measured at 47 DAP and biomass accumulated at flowering and as well leaf δ13C measured at flowering.
Figure 4. The relationship between stomatal conductance (gs) measured at 47 DAP and biomass accumulated at flowering and as well leaf δ13C measured at flowering.
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Figure 5. The relationship between genotypic means of stomatal conductance (gs) measured at 47 DAP and mean biomass (A), δ13C (B), root biomass (at flowering) (C) and grain yield (D). Means were calculated per moisture level i.e., blue for well-watered; green for moderate well-watered; yellow for moderate drought and red for severe drought. Symbols: circle for genotype IT1, triangle for IT2, rectangle for TV1, and diamond for TV2.
Figure 5. The relationship between genotypic means of stomatal conductance (gs) measured at 47 DAP and mean biomass (A), δ13C (B), root biomass (at flowering) (C) and grain yield (D). Means were calculated per moisture level i.e., blue for well-watered; green for moderate well-watered; yellow for moderate drought and red for severe drought. Symbols: circle for genotype IT1, triangle for IT2, rectangle for TV1, and diamond for TV2.
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Figure 6. Influence of moisture levels on genotypic δ13C measured in leaves sampled, at flowering stage in 2015 and 2016. Average is mean of all genotypes at a particular moisture level. Asterisks show significance: *** for p ≤ 0.001.
Figure 6. Influence of moisture levels on genotypic δ13C measured in leaves sampled, at flowering stage in 2015 and 2016. Average is mean of all genotypes at a particular moisture level. Asterisks show significance: *** for p ≤ 0.001.
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Figure 7. The effect of moisture levels on biomass WUE and Intrinsic WUE of the four studied genotypes measured in 2015 and 2016. Letters show differences among the genotypes at each moisture level (different letters represent significant differences). Asterisks show significance: * for p < 0.05, ** for p < 0.01 and *** for p ≤ 0.001.
Figure 7. The effect of moisture levels on biomass WUE and Intrinsic WUE of the four studied genotypes measured in 2015 and 2016. Letters show differences among the genotypes at each moisture level (different letters represent significant differences). Asterisks show significance: * for p < 0.05, ** for p < 0.01 and *** for p ≤ 0.001.
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Table 1. Total amount of water received by cowpea genotypes and the days taken (DAP) to reach flowering and harvesting maturity in 2015 and 2016.
Table 1. Total amount of water received by cowpea genotypes and the days taken (DAP) to reach flowering and harvesting maturity in 2015 and 2016.
20152016
FloweringHarvestingFloweringHarvesting
MoistureDAP to FloweringIrrigation + Rainfall (mm)DAP to MaturityIrrigation + Rainfall (mm)DAP to FloweringIrrigation + Rainfall (mm)DAP to MaturityIrrigation + Rainfall (mm)
WW6018112534876314140419
MW6015411326776314140418
MD561129717369237126312
SD54739712167216126299
WW: well-watered; MW: moderately well-watered; MD: medium drought and SD: severe drought. DAP for flowering and maturity are averages of the four genotypes.
Table 2. Correlation among gas exchange parameters and WUEintrinsic, WUEbiomass, and δ13C in 2015 and 2016 measured at 70 DAP.
Table 2. Correlation among gas exchange parameters and WUEintrinsic, WUEbiomass, and δ13C in 2015 and 2016 measured at 70 DAP.
2015gsAEci/caWUEintrinsicWUEbiomass
A0.89 **
E0.97 **0.89 **
ci/ca0.30 *−0.060.30 **
WUEintrinsic−0.46 **−0.22−0.42 **−0.67 **
WUEbiomass−0.19−0.18−0.080.100.09
δ13C−0.49 **−0.38 **−0.41 **−0.23 *0.34 **0.31 *
2016gsAEci/caWUEintrinsicWUEbiomass
A0.90 **
E0.94 **0.91 **
ci/ca−0.01−0.35 **−0.11
WUEintrinsic−0.60 **−0.31 **−0.54 **−0.54 **
WUEbiomass0.110.150.09−0.02−0.05
δ13C−0.78 **−0.72 **−0.74 **−0.040.48 **−0.26 *
Bold values show significant correlations. Asterisks show significance: * for p < 0.05 and ** for p < 0.01. Data averaged for all moisture levels.

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Munjonji, L.; Ayisi, K.K.; Boeckx, P.; Haesaert, G. Stomatal Behavior of Cowpea Genotypes Grown Under Varying Moisture Levels. Sustainability 2018, 10, 12. https://doi.org/10.3390/su10010012

AMA Style

Munjonji L, Ayisi KK, Boeckx P, Haesaert G. Stomatal Behavior of Cowpea Genotypes Grown Under Varying Moisture Levels. Sustainability. 2018; 10(1):12. https://doi.org/10.3390/su10010012

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Munjonji, Lawrence, Kingsley K. Ayisi, Pascal Boeckx, and Geert Haesaert. 2018. "Stomatal Behavior of Cowpea Genotypes Grown Under Varying Moisture Levels" Sustainability 10, no. 1: 12. https://doi.org/10.3390/su10010012

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