Mild deficit irrigation delays flag leaf senescence and increases yield in drip-irrigated spring wheat by regulating endogenous hormones
Ziqiang Che, S. de Bie, Rongrong Wang, Yilin Ma, Y. L. Zhang, Fangfang He, Guiying Jiang
Abstract
Drought is one of the important stress factors affecting the growth and development processes of wheat in China’s arid zones, which severely limits the yield. This study examined the impact of deficit irrigation on the flag leaf protection system and yield of drip-irrigated spring wheat during the growth stages in arid zones. In addition, this study aimed to determine the optimal water supply mode for efficient production under drip irrigation conditions and to provide technical support for water-saving and high-yield cultivation of drip-irrigated wheat. The experiment was conducted with a split plot design using the water-sensitive variety Xinchun 22 (XC22) and the drought-tolerant variety Xinchun 6 (XC6) as the main plots, while a fully irrigated control (CK, 75–80% FC, where FC is field water holding capacity), mild deficit (T1, 60–65% FC) and moderate deficit (T2, 45–50% FC) at the tillering stage, and mild deficit (J1, 60–65% FC) and moderate deficit (J2, 45–50% FC) at the jointing stage were used as the subplots. Systematic studies were conducted on the regulatory effects of deficit irrigation during the tillering and jointing stages on protective substances, membrane lipid metabolism, endogenous hormones in the flag leaf, and yield of spring wheat. Compared with treatments T2 and J2, treatments T1 and J1 were beneficial for increasing the activities of superoxide dismutase (SOD), peroxidase (POD), and catalase (CAT), the levels of proline (Pro), indole-3-acetic acid (IAA), and zeatin riboside (ZR), and the ratios IAA/abscisic acid (ABA), ZR/ABA, IAA/ZR, and (IAA+ZR)/ABA, while reducing the levels of hydrogen peroxide (H 2 O 2 ), superoxide anion radicals (O 2 – ·), malondialdehyde (MDA), phosphatidic acid (PA), free fatty acids (FFA), ABA, phospholipase D (PLD), and lipoxygenase (LOX), alleviating flag leaf senescence, and increasing yield. Under treatment T1, the SOD, POD, CAT, and Pro levels of flag leaves in XC6 were 11.14, 8.08, 12.98, and 3.66% higher than those of treatment CK, and under treatment J1, they were 6.43, 4.49, 7.36, and 2.50% higher than those of treatment CK. Under treatment T1 in XC6, the IAA, ZR level of the flag leaf, spike number, grains per spike, 1,000-grain weight and yield were 10.50, 5.79, 3.10, 8.84, 3.78, and 10.52% higher than those of treatment CK, and under treatment J1, they were 5.36, 3.94, 2.40, 3.72, 1.37, and 4.46% higher than those of treatment CK. Compared with XC22, XC6 was more conducive to the improvement of flag leaf protective substances, IAA, ZR, dry matter weight, yield components and yield. The correlation analysis showed significant positive correlations between IAA and ZR with SOD, POD, CAT, proline, and yield. IAA and ZR promoted the enhancement of protective enzyme activities, thereby clearing reactive oxygen species to cope with the oxidative stress caused by drought and achieve the effect of delaying senescence. Principal component analysis showed that yield components and dry matter weight, had direct effects on yield. Mild deficiency during the tillering stage without water stress in other stages could effectively optimize yield components, not only achieving high yield while increasing protective substances, but also reducing the reactive oxygen species content. This strategy can be recommended as a water-saving and high-yield production mode for drip irrigation of spring wheat in Xinjiang, China.