Drought and Elevated Carbon Dioxide Impact the Morphophysiological Profile of Basil (Ocimum basilicum L.)

Abstract

Treating plants with elevated carbon dioxide (eCO2) can increase their drought tolerance. Increased atmospheric CO2, a fundamental factor in climate change, may compensate for the drought-induced reduction in crop growth and yield. Basil, being moderately sensitive to drought stress, experiences several morphological changes under drought conditions. Thus, we designed an experiment that addresses how drought stress and different levels of CO2 affect the overall morphological growth patterns during basil’s early and late-season growth. The experiment was conducted under four different growth conditions: two water treatments, (1) a full-strength Hoagland’s solution was added to the basil plants at 120% of the evapotranspiration each day, and (2) 50% of the full-strength Hoagland’s solution was added to basil plants for the drought treatment, alongside two levels of CO2 application [ambient 420 ppm (aCO2) and elevated 720 ppm (eCO2)]. The drought had a severe impact on the morphological traits of the shoot and root systems. Compared to control, the drought stress reduced the marketable fresh mass (FM) by 31.6% and 55.2% in the early and late stages of growth. FM was highest under control + eCO2 (94.4–613.7 g) and lowest under drought + aCO2 (67.9–275.5 g). Plant height under drought + aCO2 and drought + eCO2 reduced by 16.8 % and 10.6 % during the late season. On the other hand, dry mass (DM%) increased by 31.6% and 55.2% under DS + eCO2 compared to control in the early and late stages of growth, respectively. This study suggested that eCO2 during drought stress significantly impacts basil morphological traits compared to aCO2. Besides, anthocyanin (Antho) decreased by 10% in DS + aCO2 and increased by 12.6% in DS + aCO2 compared to control. Similarly, NBI, a ratio of chlorophyll (Lchl) and flavonoids (Flav), was recorded to be the highest in DS + aCO2 (40.8) compared to any other treatments. Overall, this study indicates that the suppression of basil’s morphophysiological traits by drought is more prominent in its later growth stage than in the earlier stages and eCO2 played an important role in alleviating the negative effect of drought by increasing the DM% by 55%.