Physiological properties related to drought biology essay of sugarcane
This review article integrates literature on our current understanding of the biological effects of drought stress on sugarcane growth in a manner that bridges signaling networks with physiological and genetic defense mechanisms. In the present study, we examined eight morphophysiological traits of categorized sugarcane genotypes into four groups based on significant. The LPO content that has built up during drought and salt stress indicates the stress responses of the plant. Proline levels increased in response to drought, and drought severely limits sugarcane productivity in many parts of the world. This study characterized the physiological responses to different periods of drought in a. Using the key physiological markers, the drought tolerance potential of elite sugarcane clones is evaluated every year at the ICAR-Sugarcane Breeding Institute. The aim of this study was to investigate the effects of early drought stress. on physiological parameters and agronomic traits of six sugarcane genotypes, Sugarcane. Article PDF Available. Physiological and agronomic properties of certain sugarcane genotypes grown under field conditions, influenced by early exposure of sugarcane to drought conditions, causes various changes in physiological and biochemical properties. Some changes in traits cause growth. In the present study, we examined eight morphophysiological traits of sugarcane genotypes, divided into four groups based on significant abundances. A pot experiment was conducted in a net house to evaluate the effects of drought stress. treatment - after planting on the growth and physiology of. The MFVD based on the DC of each yield trait and SR indicated that ten of the hybrids had high drought resistance, while the genotypes were highly sensitive to the drought. The T of the SoACLA sugarcane lines was used to analyze the physiological and biochemical changes and the expression of drought-related genes under water stress. Drought stress is one of the most important abiotic stressors for wheat worldwide, with negative effects on wheat growth and yield. . Assessing genetic variation and drought stress tolerance of key agronomic and physiological traits of spring wheat and screening germplasm sources for higher drought tolerance and yield stability are a must. Drought is a major abiotic stress affecting sugarcane productivity worldwide. Water deficiency during sugarcane growth will lead to a reduction in leaf pigment content, such as chlorophyll, known as chlorosis. Although changes in the spectral reflectance signature were identified as a prominent sign of changes in chlorophyll content, breeding of drought-tolerant sugarcane today includes several important physiological traits as selection criteria, including leaf area, chlorophyll content, stomatal conductance, transpiration and. Background Sugarcane, an economically important crop grown for its unique nature of accumulating sucrose in the stem and the world's most important crop depending on the quantity produced. Sugarcane production is negatively affected by abiotic stress as it faces all kinds of environments due to its long life cycle period. Among the: The higher physiological plasticity in WDE (water deficit) affected plant homeostasis, to which sugarcane genotypes responded with strong inhibition of the physiological properties, while the lower physiological..