Response of Turf Bermudagrass Hybrids to Induced Drought Stress Under Controlled Environment

Abstract

Bermudagrass is a warm-season turfgrass commonly grown in drought-prone areas. Harnessing natural genetic variation available in germplasm is a principal strategy to enhance its resilience to drought stress. This study was carried out to assess the comparative performance of bermudagrass hybrids under drought conditions and their subsequent recovery following the drought period. A total of 48 hybrids, including 2 commercial cultivars, ‘Tifway’ and ‘TifTuf’, were established under optimum growth conditions in the greenhouse and then subjected to drought stress by withholding irrigation for four weeks. The dry-down experiment was laid out in a randomized complete block design with four replications. Turf color, visual quality, and active spectral reflectance data were collected weekly and used to assess the health and vigor of the hybrids during progression of the drought stress for four weeks and through recovery after rewatering. Analysis of variance revealed significant differences among the hybrids for color, visual quality, and spectral vegetation indices. A multivariate analysis grouped the hybrids into drought-tolerant with full recovery after rewatering, moderately tolerant, and susceptible to extended drought stress without recovery. These results showed the prevalence of genetic variation for drought tolerance and proved instrumental in the development of bermudagrass cultivars resilient to drought stress and improved water use efficiency.

1. Introduction

The turfgrass industry in the desert southwest USA is increasingly facing a water scarcity challenge in maintaining healthy and resilient landscapes. Frequent and prolonged droughts, higher temperatures, and declining freshwater resources have become significant threats to turfgrasses [1,2]. Water scarcity and the rise in temperature could worsen in the future, primarily due to changes in global weather patterns [3,4].

The objective of turfgrass and landscape irrigation is to provide sufficient soil moisture, which is essential for turfgrass growth, shoot density, and acceptable turf quality. In ideal aesthetic conditions, turfgrasses contain 75–85% water by weight [5] and will start wilting with a 10% decrease in water content [6]. This will subsequently affect the environmental, social, and economic benefits of turfgrass, indicating high water requirements for turfgrass management in desert environments where high temperatures intensify evapotranspiration (ET). Inadequate water availability in the soil profile also limits the ability of turfgrasses to uptake nutrients necessary for growth, leading to deterioration of turf color and quality, and increased susceptibility to pests and diseases [7]. Severe water shortage in the soil can desiccate and kill turfgrass and therefore truncate its ability to fulfill its intended purpose [1,7].

Breeding to develop drought-tolerant turfgrass varieties is a common strategy for sustaining the turfgrass industry in arid and semi-arid environments. The use of drought-resistant turfgrass species and cultivars is advocated to reduce turfgrass irrigation needs [8,9]. The strategy requires leveraging the genetic variation prevalent within a selected species [10]. Moreover, the effectiveness of selecting drought-tolerant genotypes greatly depends on a better understanding of drought tolerance and the recovery characteristics observed after a prolonged drought episode.

Hybrid bermudagrass (Cynodon dactylon × C. transvaalensis) is a widely used turfgrass for home lawns, golf courses, sports fields, and parks. Studies have been conducted to compare, characterize, and understand drought tolerance mechanisms and physiology among bermudagrass genotypes [11,12,13]. Bermudagrass’s ability to maintain its functional and aesthetic qualities under limited water availability is a focal point of study [14,15] and highlights the combined importance of soil depth and the genetic composition of cultivars in sustaining turfgrass functionality during periods of drought stress. Research shows significant genetic diversity in bermudagrass, which is well adapted for regions experiencing drought and elevated temperatures [2,13,15,16]. A range of drought stress response differences have been observed in bermudagrass [10,17] mainly through drought avoidance and tolerance mechanisms such as osmotic adjustment, antioxidant metabolism, and rooting characteristics [13]. Intraspecific diversity in rooting depth has been documented for bermudagrass in ideal soil conditions [18]. Gopinath et al. [2] reported significant variations among several bermudagrass genotypes for leaf firing, turf quality, canopy temperature, and Normalized Difference Vegetation Index (NDVI) values in the field. Remote sensing has become an effective, rapid, and non-destructive technique for turfgrass phenotyping under various water regimes and helps in optimizing turfgrass selection under water stress [19]. A result of a turfgrass irrigation study conducted in Central California suggested an NDVI threshold of 0.5 for hybrid bermudagrass to maintain acceptable quality [20]. In addition to canopy characteristics, root traits that allow for the absorption of water from deeper soil layers without restriction were likely linked to better performance of some of the genotypes.

Understanding inherent genetic variation regarding drought tolerance and recovery after prolonged drought stress among germplasm sources can bring new insights supporting bermudagrass breeding programs. It is crucial to develop drought- and heat-resistant varieties that support quality landscapes while maximizing water conservation. Utilization of the natural diversity present in bermudagrass germplasm is essential for the development of improved cultivars that can thrive in harsh environmental conditions and meet recreational and ecosystem services needs in the southwest desert. Therefore, we investigated 48 hybrid turf bermudagrass genotypes with induced drought stress using a dry-down experiment in a controlled greenhouse environment by withholding irrigation for four weeks before rewatering. The objectives of this study were to examine the relative drought tolerance of the genotypes and their recovery potential after prolonged drought stress.

2. Materials and Methods

2.1. Study Materials and Greenhouse Conditions

A total of 48 turf-type bermudagrass hybrids, including 2 commercial cultivars, ‘Tifway’ and ‘TifTuf’, were evaluated. The hybrids were developed from different parents by Oklahoma State University Turf Breeding Program and selected based on their performance in small-plot progeny testing at Stillwater, Oklahoma. The commercial cultivars (‘TifTuf’ and ‘Tifway’) were selected due to their industry prevalence and adaptability [21,22]. The entries were established under optimum growth conditions in a greenhouse. The experiment was arranged in the middle of the greenhouse chamber on a bench between an evaporative cooler and exhaust fans. Plants were subjected to acute water stress by withholding irrigation for four weeks and then were rewatered. The greenhouse conditions throughout the experimental period consisted of full sunlight (an average photosynthetic photon flux density (PPFD) of 2000 µmole m⁻² s⁻¹) for an average of 13 h. The average daily temperatures in the greenhouse were 32.2 °C (90 °F) and 26.7 °C (85 °F) during the day and night, respectively. The average relative humidity was 30 percent.

2.2. Seedling Establishment, Turfgrass Maintenance and Drought Treatment

The plants for this experiment were grown from plugs taken from a field experiment at Maricopa Agricultural Center (MAC), Maricopa, Arizona (33°3′24″N 112°2′48″W). The plugs were planted in a 20 cm wide × 40 cm deep polyethylene pot (Stuewe and Sons Inc., Corvallis, OR, USA) filled with a mixture of Pro-Mix general-purpose growing medium (Premier Horticulture Ltd., Rivière-du-Loup, Quebec, Canada) and fine sand (USGA specific 90:10 sand/peat moss mix (v:v)) in a 1:1 ratio (v:v). All the pots were subjected to a pre-trial conditioning treatment by watering once a week for a month. Irrigation was provided to the plants manually from an overhead shower. Once a full canopy was formed by all the genotypes and uniform visual turf quality obtained, the plants were trimmed to 10 cm above the pot top and consistently maintained by weekly trimming conducted one day prior to data collection. Then, irrigation was withheld, and the following day, the soil volumetric water content (VWC%) was measured by fully inserting a 12 cm probe on the top surface of each pot using a FieldScout TDR 350 digital soil moisture meter (Spectrum Technologies, Inc., Aurora, IL, USA). This dry-down drought stress lasted for four weeks. After this period, each pot was watered well to allow the soil moisture to return to field capacity to initiate the recovery process.

2.3. Experimental Design, Response Variables, and Statistical Analysis

The 48 hybrid bermudagrass genotypes, including ‘Tifway’ and ‘TifTuf’, were laid out in a randomized complete block design (RCBD) with four replications. The experiment was arranged in the middle of the greenhouse chamber on a bench between an evaporative cooler and exhaust fans. Response variables such as visual turf color and quality assessment along with active spectral reflectance, color imagery, and soil moisture data were collected on a weekly basis. Turfgrass color and quality ratings were visually assessed using the 1–9 scale of the NTEP evaluation guideline [23,24], where 1 = worst, 6 = minimum acceptable level, and 9 = best.

The active spectral reflectance data were captured with a height-independent active crop canopy sensor, the ‘RapidScan CS-45’ (Holland Scientific, Lincoln, NE, USA), which measures canopy reflectance at the wavelengths of 670 nm, 730 nm, and 780 nm. The sensor was held in nadir view 40 cm above the surface of the pots without any background. Images were taken by hand using an Olympus Tough TG4 (Olympus Corporation, Tokyo, Japan) with locked exposure settings. All the data were collected between 1:00 and 2:00 pm in the afternoon. Spectral vegetation indices such as Normalized Difference Red Edge Index (NDRE) [25], Normalized Difference Vegetation Index (NDVI) [26], Dark Green Color Index (DGCI) [27], Normalized Green-Blue Difference Vegetation Index (NGBVI) [28,29], and Normalized Red–Blue Difference Vegetation Index (NRBVI) [30] were calculated using the formulae provided in the respective references. The data were collected weekly for four weeks without watering and one week after rewatering. A workflow utilizing Python 3.6.9 [31] provided custom image-based OpenCV [32] and scikit-image [33] processes. Then, the HSV (Hue, Saturation, Value) color space [34,35,36] was used to segment the living green plant material and enabled subsequent calculation of the color and cover of features [37,38]. These observations were used to assess the responses of the genotypes to the progression of drought stress and for recovery after prolonged simulated drought.

Weekly soil moisture status was monitored using a FieldScout TDR 350 digital soil moisture meter, and volumetric water content (VWC %) was recorded. The measurement was made by first placing the moisture sensor in the first pot and waiting a few minutes to allow for some thermal equilibration before beginning. The pot was then left in place for one to three seconds prior to the measurement, and it was measured in a time of roughly three to six seconds. Only one measurement was taken per pot after multiple measurements were confirmed to yield a stable reading.

Data were subjected to statistical analyses of variance, and multivariate analyses such as cluster and correlation analyses using R v4.4.0 [39] and SAS statistical software v9.4 (SAS Institute Inc., Cary, NC, USA). R packages including ‘FactoMineR’ [40] and ‘cluster’ [41] were used in the multivariate analyses and visualization of results. Replications were designated as random, while the genotypes were fixed effects in the analysis.

3. Results

3.1. Effect of Drought on Bermudagrass Aesthetics and Vegetation Indices

Induced drought impacted the average overall color and quality scores of bermudagrass hybrids tested for drought tolerance in a controlled environment (Figure 1). Though there were variations among the hybrids tested, the average color and quality scores decreased as the drought progressed. The initial effect of drought was minimal in the first two weeks; however, by week four after drought initiation (T_4), the average color and quality scores were dramatically reduced to below the acceptable level of a visual score of 6. As induced drought stress continued from T_0 through T_4, mean color scores were significantly decreased from 7.3 to 3.5 (Figure 1a and Figure S2 in Supplementary Materials). The mean color differences were significant between different time points except T_0 and T_1. After the drought was halted, the average color scores of the hybrids after recovery (T_5), increased to the T_3 stage average. Similarly, turf quality linearly decreased as drought stress continued from T_0 through T_4.

Some of the active spectral vegetation indices and imaging data depicted an overall decline in the average performance of the genotypes through week four (T_4) (Figure 1b). NDVI and NDRE showed continual reduction as the drought stress was sustained, with significant differences among the time points. NDVI scores significantly decreased from 0.87 at T_0 to 0.51 at T_4. The overall NDVI scores of the hybrids were statistically recovered to the T_3 level one week after the induced drought was halted via rewatering. Likewise, average NDRE differences were observed among the time points. On the other hand, DGCI, NGBVI, and NRBVI did not show substantial differences between different stages of drought stress and in the recovery phase.

The mean separation for visual assessment and spectral reflectance (LSD_0.05) for all the genotypes showed that there were significant differences between the weeks (Figure 2). Average color and quality scores were significantly affected starting at week three (T_2) (Figure S1a). After rewatering, color recovered faster than quality. The spectral vegetation indices showed the same trend (Figure S1b), and the total fraction of green (NDVI) decreased faster than the DGCI.

3.2. Variation in Drought Response and Recovery Among Bermudagrass Hybrids

Combined analysis of variance indicated that visual ratings and optical indices of bermudagrass hybrids were significantly affected by genotype, time (length of drought stress), and their interaction effects (

Table 1. Combined analysis of variance for visual ratings and spectral vegetation indices of 48 hybrid bermudagrass types studied for drought tolerance in a controlled environment at Maricopa, AZ, in 2023.

Source	DF	Mean Square
		Color	Quality	NDRE	NDVI	DGCI	NGBVI	NRBVI
Replication	3	7.8 ***	9.0 ***	0.059 ***	0.106 ***	0.014 ***	0.008 ***	0.005 ***
Genotype	47	3.9 ***	4.7 ***	0.020 ***	0.039 ***	0.008 ***	0.005 ***	0.006 ***
Time	5	400.4 ***	352.8 ***	1.817 ***	3.912 ***	0.348 ***	0.431 ***	0.387 ***
Genotype × Time	235	1.5 ***	1.2 ***	0.005 *	0.009 *	0.002 **	0.001 ***	0.001 ***
R2		0.80	0.78	0.78	0.80	0.73	0.87	0.84
CV		14.6	15.2	17.3	11.7	6.6	8.5	11.3
Mean		5.9	5.6	0.35	0.71	0.50	0.25	0.21

NDVI = Normalized Difference Vegetation Index; NRDE = Normalized Difference Red Edge Index; DGCI = Dark Green Color Index; NGBVI = Normalized Green-Blue Vegetation Index; and NRBVI = Normalized Red–Blue Vegetation Index; *, **, *** significant at 0.05, 0.01, 0.001 probability levels.

). There were highly significant differences among the hybrids for color and quality, as well as four spectral vegetation indices, namely NDRE, NDVI, DGCI, NGBVI, and NRBVI. There were highly significant differences among the six time points when the performance data were collected during the drought stress study. The genotype by time interaction was also significant for color (p ≤ 0.001), quality (p ≤ 0.001), NGBVI (p ≤ 0.001), NRBVI (p ≤ 0.001), DGCI (p ≤ 0.01), NDRE (p ≤ 0.05), and NDVI (p ≤ 0.05).

Individual weekly time point data analysis of variance of visual and optical indices showed differences among turf bermudagrass hybrids (Table S1). Genotypic differences for visual color and quality during the dry-down (T_0 to T_4) and recovery (T_5) phases were significant. Differences in visual color and quality at T_0 and T_1 were mainly due to genetic differences. Pre-drought stress (T_0), hybrids such as OSU 1156 and OSU 2118 gave the highest and lowest color scores of 8.8 and 6.3, respectively. Similarly, the mean highest and lowest turf quality scores recorded were 8.5 and 5.5 for OSU 2101 and OSU 2119, respectively.

Mean color and quality scores of the genotypes showed palpable variation among the genotypes four weeks after withholding irrigation and after recovery (Figure 2 and Figure S3). Genotypes such as OSU 2119, OSU 1617, OSU 2118, OSU 2107, and OSU 2018 maintained acceptable levels of greenness and turf quality. OKC 1876 showed acceptable color but lower visual quality. On the other hand, OSU 2021 showed acceptable quality but a lower color score.

3.3. Correlation of Visual Ratings and Spectral Reflectance

Pearson correlation analysis was performed to quantify the magnitude and determine the direction of associations among the visual assessment scores and optical indices at the T_0, T_4, and T_5 time points (Figure 3). The correlation coefficients were computed for each pair of the two visual assessments and five spectral parameters considered in this study. Correlation coefficients revealed that various degrees of associations are prevalent among visual assessments and active spectral reflectance-based vegetation indices during the progression of drought stress and the recovery phase after rewatering. In general, visual color and quality were positively correlated with NDRE, NDVI, and DGCI in the pre-stress, maximum stress, and recovery phases. Color had a strong positive correlation with quality (r = 0.64, p ≤ 0.001), NDVI (r = 0.50, p ≤ 0.001), NDRE (r = 0.67, p ≤ 0.001), and DGCI (r = 0.74, p ≤ 0.001). Likewise, quality showed strong positive associations with NDVI (r = 0.61, p ≤ 0.001), NDRE (r = 0.69, p ≤ 0.001), and DGCI (r = 0.67, p ≤ 0.001). Among the spectral vegetation indices, NDRE had a strong positive correlation with NDVI (r = 0.90, p ≤ 0.001) and DGCI (r = 0.74, p ≤ 0.001). NRBVI was negatively correlated with color, quality, and other vegetation indices (except NGBVI) at pre-stress and after recovery. The associations of NGBVI with color (r = −0.14), quality (r = 0.10), and NDRE (r = 0.09) were non-significant.

Four weeks after drought induction, most pairwise correlation coefficients of visual assessment scores and optical indices were strongly positive. Color was positively correlated with quality (r = 0.86, p ≤ 0.001), NDVI (r = 0.55, p ≤ 0.001), DGCI (r = 0.52, p ≤ 0.001), and NGBVI (r = 0.68, p ≤ 0.001). Turf quality also had a positive and strong correlation with NDVI (r = 0.61, p ≤ 0.001), NDRE (r = 0.52, p ≤ 0.001), and NGBVI (r = 0.68, p <0.001). Furthermore, NDVI had a strong positive correlation with NDRE (r = 0.80, p ≤ 0.001) and DGCI (r = 0.54, p ≤ 0.001). The associations of NDRE with DGCI (r = 0.5, p ≤ 0.001) and NGBVI with NRBVI (r = 0.9, p ≤ 0.001) were found to be strong and positive as well.

In the recovery phase, strong positive associations were observed for color with quality (r = 0.63, p ≤ 0.001), NDRE (r = 0.60, p ≤ 0.001), and DGCI (r = 0.65, p ≤ 0.001). Similarly, quality had a strong positive association with NDVI (r = 0.67, p ≤ 0.001), NDRE (r = 0.78, p ≤ 0.001), and DGCI (r = 0.50, p ≤ 0.001). Furthermore, NDRE showed strong positive correlations with NDVI (r = 0.87, p ≤ 0.001) and DGCI (r = 0.62, p ≤ 0.001). Other pairwise comparisons including NGBVI with NRBVI (r = 0.79, p ≤ 0.001) showed strong positive relationships. NDVI showed a moderate positive correlation with color (r = 0.45, p < 0.001) and DGCI (r = 0.46, p ≤ 0.001). In contrast, NRBVI had significant negative associations with DGCI (r = 0.88, p ≤ 0.001) and color (r = −0.57, p ≤ 0.001). Negative associations of NRBVI with quality (r = 0.38, p ≤ 0.001), NDRE (r = 0.47, p ≤ 0.001), and NDVI (r = 0.3, p ≤ 0.001) were also observed. A statistically significant negative association was also observed between NGBVI and DGCI (r = 0.45, p ≤ 0.001). Despite the significant positive or negative correlations presented above, no associations were detected (p ≤ 0.05) for NGBVI with quality (r = 0.07), NDVI (r = 0.13), and NDRE (r = 0.01).

3.4. Clustering of Bermudagrass Hybrids Pre- and Post-Stress and After Recovery

Hierarchical agglomerative cluster analysis was conducted utilizing visual assessment, spectral reflectance, and imaging data collected pre-drought stress (T_0), at maximum drought stress (T_4), and during recovery (T_5), revealing distinct grouping patterns (Figure 4). These differences typically reflect the physiological and genetic responses of the genotypes to water stress and their ability to recover after prolonged dry spells. The pre-stress genotype cluster originates from baseline physiological traits like growth rate, leaf area, color, and similarities in genetic makeup and metabolic profiles. The cluster of genotypes four weeks post-drought stress initiation (maximum drought stress) shifted the groupings of the genotypes dramatically. Genotypes that exhibited high color and quality scores such as OSU 1617, OSU 2119, and OSU 2018 were characteristically grouped together, while susceptible genotypes OSU 1156, OSU 2102, and OSU 2113 were grouped together.

In the recovery phase, the pattern of groupings of the genotypes was strikingly changed. This regrouping based on visual assessment and spectral vegetation index data highlights the differential ability of the bermudagrass genotypes to resume normal growth and photosynthesis after prolonged drought stress. Genotypes that demonstrated rapid recovery and regrowth such as OSU 2119, OSU 2021, and OSU 1617 were grouped together. Some of the genotypes did not return to their original clusters, indicating perpetual physiological or structural changes due to drought stress. Those with delayed responses and those lacking recovery ability were grouped separately.

3.5. Principal Component Analysis

Using weekly visual and spectral reflectance data, principal component analysis (PCA) was used to analyze the 48 bermudagrass genotypes. The first three principal components explained about 91% of the total variance of the visual and spectral reflectance scores of 48 bermudagrass genotypes before the initiation of drought stress (Figure 5a). NGBVI and NRBVI mostly contributed through PC 2. Except for NRBVI and NGBVI, the remaining spectral indices and visual assessment scores showed higher degrees of positive association. The variance contribution of each spectral index was higher than that of the visual scores.

At four weeks post-drought induction, the first three principal components explained about 92.9% of the variance. The first and second principal components explained about 60.7 and 23.9%, respectively. The third component explained only 8.1% of the total variance. Color, quality, NDRE, and SAVI contributed through the first principal component. Similarly, DGCI, NRBVI, and NGBVI contributed through the second principal component. Spectral indices that contributed through the first and second principal components further contributed through the third principal component (8.3%).

After 4 weeks of acute water stress, the plants were rewatered. Then, one week after rewatering (T_5), entries were evaluated for their recovery using the same set of visual assessments and spectral and optical indices. One week into recovery, 89.9% of the variance was explained by the first three components (Figure 5a). The first and second principal components explained 61 and 22.5% of the variance. Color, quality, SAVI, DGCI, NDRE, and NRBVI contributed through the first component. Contributions to the second principal component came from NDVI, NGBVI, and NRBVI. Furthermore, color and NDVI contributed to the third principal component (6.4).

The number of principal components (PCs) maintained for further analysis was determined by plotting eigenvalues or percentages of explained variances of each dimension (Figure 5b). PCA identified the components that explained a significant portion of the variance, the contribution of each parameter to the total variance, and the relationships among the visual and spectral scores.

3.6. Soil Moisture Depletion

Weekly soil moisture content monitoring of the pots of bermudagrass hybrids in the dry-down and recovery experiments in a controlled setting revealed a continual reduction in VWC% as the drought period progressed (Figure 6A). The moisture sensor data also revealed substantial differences among the pots (Figure 6B). It appears that the density of the turfgrass and the level of compaction may account for some of the variations.

4. Discussion

We conducted a dry-down study on 46 turf-type bermudagrass hybrids along with 2 commercial hybrids, ‘Tifway’ and ‘TifTuf’. Our investigation was based on variations in visual ratings for color and quality and active spectral reflectance-based vegetation indices, mainly NDVI, NRDE, and image DGCI, as metrics to estimate the overall performance of the hybrids in response to extended induced drought stress. The induced drought in a controlled environment impacted the average color and quality scores of most of the bermudagrass genotypes starting at week three (T_3).

Despite differences among the hybrids evaluated, average color and quality scores declined during the drought progression. The proportion of bermudagrass hybrids that retained acceptable color scores was 100% one week (T_1) and two weeks (T_2) after drought induction. However, the proportion was reduced to 27% three weeks (T_3) after drought induction. Four weeks after drought induction, the average color and quality scores for almost all accessions had dropped substantially below acceptable levels.

Four weeks after inducing drought conditions, there were noticeable differences in color and quality scores among the genotypes. Genotypes such as OSU2119, OSU1617, OSU 2118, OSU 2107, and OSU 2018 maintained acceptable levels of greenness and turf quality after four weeks without irrigation. In contrast, OKC 1876 exhibited acceptable color but had a low quality score, while OSU 2021 showed acceptable quality with a low color score. A study of 460 common bermudagrass genotypes under field and induced drought conditions identified three main clusters based on turf quality and green cover as response variables [42]. The average turf quality scores for the drought-tolerant bermudagrass hybrids in the current study were consistent with this report.

Several studies have been conducted to characterize, compare, and understand drought tolerance characteristics among different sets of bermudagrass genotypes and physiological mechanisms underlying the differences [11,12,13]. A study on the physiological responses of drought tolerance in bermudagrass grouped genotypes into drought-tolerant, moderately tolerant, and susceptible types [17]. This grouping was probably based on relative water loss, cell membrane damage (electrolyte leakage), osmolytes, accumulation of hydrogen peroxide (H₂O₂), and antioxidant enzyme activities.

The standard controls, ‘Tifway’ and ‘TifTuf’, did not retain acceptable visual ratings beyond three weeks after drought induction. In contrast to our findings, in a study conducted to investigate differences in drought response among bermudagrass and seashore paspalum genotypes, ‘TifTuf’ consistently maintained higher quality ratings. Furthermore, ‘TifTuf’ was able to maintain lower canopy temperatures and higher relative water content and had the greatest accumulation of osmolytes during drought [43]. The discrepancy between our findings and this report might be attributed to the differences in intensity, length of time, and environmental conditions.

Both visual assessments and active spectral reflectance measurements were utilized to evaluate the health and vigor of the genotypes throughout the drought stress period and during recovery. Analysis of variance indicated significant differences among the hybrids in terms of color and quality, as well as in the five optical indices NDRE, NDVI, DGCI, NGBVI, and NRBVI. These results are in accordance with spectral vegetation indices in a previous report of genetic variation among the hybrids under optimal growing conditions [44]. Furthermore, ANOVA revealed significant differences among the six time points and the interaction of genotype and time point effects. The statistical significance for all the visual assessment and spectral reflectance data indicates genetic variation among the bermudagrass hybrids for both drought tolerance and recovery potential. This result is aligned with previous reports where wilting and leaf firing variations of turfgrasses during dry-down periods reflect the relative drought resistance of these genotypes [14].

As visual turf quality and color assessments are subjective, objective high-throughput multispectral assessment is valuable. Spectral reflectance can indirectly detect water content and depict variability in grass water status in water deficit conditions [45]. In the current study, the reflectance spectra of the genotypes underwent a gradual reduction with increased drought stress. Vegetation indices are acclaimed as effective indicators of water stress in bermudagrass [46], effective in capturing the genetic variation among the hybrids for drought stress tolerance.

The NDVI exhibited significant variations across different time points. Average NDVI scores decreased significantly from 0.87 to 0.35 as induced drought stress proceeded during the dry-down phase. However, the overall NDVI scores of the potentially drought-tolerant hybrids statistically returned to the acceptable level in just one week after the drought was alleviated through rewatering. This indicates that the hybrids have a noticeable recovery potential, maintenance of photosynthetic activity, and overall plant health after periods of acute water stress [47]. Katuwal et al. [13] reported that drought-tolerant bermudagrass genotypes maintained higher NDVI values compared to drought-susceptible ones. A strong association between NDVI and visual rating values [48] also indicates the importance of NDVI as a non-invasive tool to monitor photosynthetic activity and overall plant health under various environmental conditions. Changes in other spectral indices, including NDRE, DGCI, NGBVI, and NRBVI, followed the same trend, indicating that drought progression had a significant impact on active spectral reflectance. These variations observed among the hybrids suggest that spectral reflectance can be used in bermudagrass breeding to select genotypes for leaf water potential and recovery from extended drought conditions. Investigating the variations in vegetation indices among the hybrids under water stress conditions is also crucial to understanding drought-adaptive mechanisms and optimum management of turfgrass irrigation.

Our findings revealed the existence of substantial drought response variations among the 48 bermudagrass hybrids evaluated under a controlled environment. Similar results were observed in controlled and field-condition investigations [10]. Four weeks of a dry-down period uncovered substantial drought response variations among the hybrids. Dry-down periods vary significantly depending upon the genotype (natural or experimental genotypes) and study conditions (field vs. controlled). A study that evaluated 10 bermudagrass genotypes under greenhouse and field conditions indicated that genotypes under field conditions tend to perform better for longer dry-down phases (up to 60 days) vs. 9 days in controlled environments [2]. The reduced rooting zone in a pot and inability to access deep water storage induced quicker and more extreme stress than the field environment.

Drought response variations among turf bermudagrass hybrids could prove instrumental in the development of bermudagrass cultivars with resilience to drought stress and improved water use. Genotypic variation in responses to reduced soil water supply among bermudagrass is attributed to shoot and root traits affecting water access, retention, and use [16,21,49]. Among shoot and root traits, canopy configuration or leaf orientation, shoot density, growth habit, rooting depth, and root density are the most important characteristics [6,50]. Bermudagrass leaf characteristics that contribute to drought tolerance are thought to be thick leaf cuticles, smaller stomatal openings, and low evapotranspiration rates [14,42,51]. This variation facilitates the likelihood of selecting more desirable superior genotypes for appropriate landscapes in the southwest desert. In addition to assessing variation in drought responses, a breeding program is recommended to develop genotypes with a more extensive root system and higher root-to-shoot ratio as an effective strategy to improve the drought performance of bermudagrass [10]. The findings of the current study are instrumental in the breeding process for the development of superior bermudagrass cultivars suitable for drought-prone and water-scarce areas.

A correlation analysis was performed to assess the relationships between visual and optical indices at 0 (T_0) and 4 weeks (T_4) after drought induction and the recovery phase (T_5). The correlation analysis revealed associations among visual assessment traits and optical vegetation indices for bermudagrass hybrids evaluated for drought response during the extended drought stress and recovery phase after rewatering. The results agree with previous reports, where visual and vegetation indices were highly and positively correlated [10].

Clustering and principal component analyses of bermudagrass hybrids during the dry-down and recovery phases elucidated the pattern and association of indices and genotypes. The degree of contribution of each index varies, to some extent, during the drought initiation, maximum drought event, and recovery phases. Among the indices, NDVI had the lowest contribution to the total variation at four weeks after drought induction. Yet color and quality had a remarkable effect on the total variance among the 48 bermudagrass hybrids at the maximum drought stress (i.e., four weeks after drought induction). This indicates that the various spectral and vegetative indices respond differentially to the induced stress. This shift of genotype grouping under maximum drought stress is primarily due to variations in drought tolerance, largely attributed to variations in osmotic adjustment (proline accumulation, soluble sugars), stomatal regulation, water retention capacity, and antioxidant enzyme activity [15]. Based on the response characteristics, the 48 bermudagrass genotypes can be grouped into three groups: highly drought-tolerant with full recovery after rewatering, moderately tolerant, and susceptible to extended drought stress without recovery. Although determining drought tolerance mechanisms is beyond the scope of this study, bermudagrass has various drought response mechanisms including physiological adaptations (osmotic adjustment, stomatal regulation, photosynthetic efficiency, hormonal response, root architectural adjustments) [17]. Morphological adaptations include changes in leaf morphology, accumulation of cuticular wax, tillering responses, internode elongation, biomass allocation, and enhancements in seed production and viability [52].

5. Conclusions

In general, distinct genotypes demonstrated varying capacities for drought tolerance and drought recovery. The results indicate that hybrids exhibit trait diversity to cope with various recurring water deficits or to recover from extended drought stress. These abilities reflect the extent of genetic variation and the significant potential of the germplasm under study for developing new cultivars suitable for arid and semi-arid environments. Under drought stress conditions, both color and quality were affected, as measured by spectral vegetation indices and visual assessments. The persistence and recovery rate of a few genotypes were high, implying better water use efficiency.

Better understanding the drought tolerance mechanisms in those identified hybrids is a crucial next step in the development of drought-resilient bermudagrass cultivars. Transcriptome profiling and metabolome profiling would lend insight into the mechanistic basis of drought tolerance in those identified hybrids.

Controlled environments are valuable tools for scientific research, enabling the manipulation of variables and the observation of specific factors of interest. However, it is important to recognize that these environments may not fully replicate field conditions. Field conditions are incredibly complex, comprising several biotic and abiotic interactions. Therefore, additional field evaluations are needed to assess the relative long-term performance of different genotypes.