Abstract
Water deficit stress is one of the major limiting factors that adversely affect plant growth and yield production. Some rhizosphere bacteria are known to promote plant growth in such stressful conditions. To study the response of quantifying canola growth, yield and yield components, to root colonization by two species of mycorrhizal fungi, a two-year field experiment was conducted at the research farm of Zanjan University. The main plot conditions were irrigation at 85% (S1), 70% (S2) and 55% (S3) of field capacity which were defined as no stress, mild and severe stress. The subplot treatments included three levels of mycorrhizal inoculation: non inoculation (control), G. Mosseae and G. Intraradices. The results showed that regardless of water deficit stress, colonized plants produced more biomass, seed and oil yield than non inoculated plants. Water deficit stress reduced the RWC and oil percentage of the seeds, although mycorrhizal improved these traits. Water deficit strikingly decreased the linoleic acid content in the seeds in contrast with increased stearic, oleic, arachidic and linolenic acids in the canola seeds. The presence of bacteria increased the seed oil percentage, oleic and linoleic contents. However, it decreased arachidic, particularly when the plants were subjected to water deficit stress.
Highlights
Drought is one of the main restrictions on the quantity and quality of crop productivity throughout the world
High air temperature was observed during the seed filling period in the first growing season (April-June) and the difference in rainfall during the growing season could be the reason for the significant interaction between year and treatment and for yield and yield components
The results showed that SPAD and relative water content (RWC) content were lower in the plants under drought stress (Table 4)
Summary
Drought is one of the main restrictions on the quantity and quality of crop productivity throughout the world. It is assumed that drought will have caused yield loss and crop damage in more than 50% of arable land by 2050 (Martínez-Ballesta et al, 2013). Drought interferes with the normal function of plants due to changing in turgor and plant water potential (Rahdari and Hoseini, 2012). Variation in chlorophyll and relative water content (RWC) are often measured because they are affected by stress and expected to be a symptom of the photooxidation of drought injury (Keshavarz et al, 2018). Among the various impacts of drought stress, its effects on plant growth and crop damage in arid and semi arid ecosystem are generally discussed (Anjum et al, 2011)
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