Abstract
Several researchers have hypothesized that shade avoidance behaviour is favoured by natural selection because it increases the fitness of individuals. Shade avoidance can be disadvantageous for crops, however, because it reduces allocation of resources to reproductive yield, increases the risk of lodging and reduces weed suppression. One approach to develop varieties with reduced shade avoidance and enhanced agronomic performance is by inducing mutations followed by phenotypic screening. We treated spring wheat seeds with ethyl methanesulfonate and screened the seedlings repeatedly under green filters for plants showing reduced elongation of the first leaf sheath and second leaf lamina. The shade avoidance responses of five promising mutant lines were further compared to non-mutated plants in a climate chamber experiment with added far-red light. Two of the selected lines displayed significantly reduced elongation under all light treatments while two lines showed reduced elongation only in added far-red light. The most promising mutant line did not differ in height from the non-mutated cultivar in neutral light, but elongated 20.6% less in strong far-red light. This traditional forward approach of screening mutagenized spring wheat produced plants with reduced shade avoidance responses. These mutants may generate new molecular handles to modify the reaction of plants to changes in light spectral distribution in traditional and novel cultivation systems.
Highlights
Plants possess sensory mechanisms to detect changes in ambient light caused by adjacent vegetation
Several studies have suggested that reduced shade avoidance responses could increase cereal crop yields (Smith 1992; Holt 1995; Sawers et al 2005; Carriedo et al 2016). In addition to these direct effects, we have argued that the shade avoidance response is detrimental to a crop’s ability to suppress weeds at high density
7200 individuals produced seeds which were sown in rows under a green filter to obtain mutant offspring with short stature phenotypes deviating from the parent cultivars
Summary
Plants possess sensory mechanisms to detect changes in ambient light caused by adjacent vegetation. Leaf chlorophylls and carotenoids absorb mostly red (R) and blue light. Light that is transmitted through vegetation is depleted in red and strongly enriched in far-red (FR; Smith 2000; Franklin and Whitelam 2005). Even before direct shading takes place, FR light reflected from neighbouring plants lowers the R:FR light ratio, acting as an early signal of neighbour proximity (Casal et al 1986; Ballaré et al 1990). The depletion of red and blue light signals a transition from neighbour detection to real competition (de Wit et al 2016). Changes in the R:FR light ratio are detected by signal-transducing photoreceptors, phytochromes, AoB PLANTS https://academic.oup.com/aobpla
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