Abstract
This study evaluates the potential for adaptability and tolerance of wheat genotypes (G) to an arid environment. We examined the influence of drought stress (DS) (100, 75, and 50% field capacity), planting times (PT) (16-November, 01-December, 16-December and 01-January), and G (Yocoro Rojo, FKAU-10, Faisalabad-08, and Galaxy L-7096) on phenological development, growth indices, grain yield, and water use efficiency of drip-irrigated wheat. Development measured at five phenological growth stages (GS) (tillering, jointing, booting, heading, and maturity) and growth indices 30, 45, 60, and 75 days after sowing (DAS) were also correlated with final grain yield. Tillering occurred earlier in DS plots, to a maximum of 31 days. Days to complete 50% heading and physiological crop maturity were the most susceptible GS that denoted 31–72% reduction in number of days to complete these GS at severe DS. Wheat G grown with severe DS had the shortest grain filling duration. Genotype Fsd-08 presented greater adaptability to studied arid climate and recorded 31, 35, and 38% longer grain filling period as compared with rest of the G at 100–50% field capacity respectively. December sowing mitigated the drought and delayed planting effects by producing superior growth and yield (2162 kg ha−1) at severe DS. Genotypes Fsd-08 and L-7096 attained the minimum plant height (36 cm) and the shortest growth cycle (76 days) for January planting with 50% field capacity. At severe DS leaf area index, dry matter accumulation, crop growth rate and net assimilation rate were decreased by 67, 57, 34, and 38% as compared to non-stressed plots. Genotypes Fsd-08 and F-10 were the superior ones and secured 14–17% higher grain yield than genotype YR for severely stressed plots. The correlation between crop growth indices and grain yield depicted the highest value (0.58–0.71) at 60–75 DAS. So the major contribution of these growth indices toward grain yield was at the start of reproductive phase. It's clear that booting and grain filling are the most sensitive GS that are severely affected by both drought and delay in planting.
Highlights
Drought and temperature extremes are the major abiotic constraints to cereal production worldwide, in rainfed dry agriculture systems (Venkateswarlu and Shanker, 2012)
Differences among G were significant (p ≤ 0.05) under the influence of drought stress (DS), and planting dates (PD) and the negative effect of DS was more severe on L-7096 and Yocoro Rojo (YR) as compared with those recorded on Faisalabad 2008 (Fsd-08) and F-10
Regardless of different DS and PD, the maximum plant height was recorded for L-7096 while prolonged growth cycle was observed in Fsd-08 (Figure 2)
Summary
Drought and temperature extremes are the major abiotic constraints to cereal production worldwide, in rainfed dry agriculture systems (Venkateswarlu and Shanker, 2012). The western region of Saudi Arabia is classified into rain fed dry area by Koppen’s classification scheme, due to its arid land features. Under changing environmental features globally and increasing world population, crop production and water resources are declining day by day, along with the increased frequency of extreme temperature fluctuations. It is imperative to develop heat and drought tolerant wheat genotypes (G) to match the ever increasing demand for food supply (Buck et al, 2007; Hossain et al, 2013). It is hypothesized that selected exotic G may outcompete the local G and can replace them based on their performance under local arid land conditions
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