Abstract
Plant architecture is optimized for the local light environment. In response to foliar shade or neighbor proximity (low red to far-red light), some plant species exhibit shade-avoiding phenotypes, including increased stem and hypocotyl growth, which increases the likelihood of outgrowing competitor plants. If shade persists, early flowering and the reallocation of growth resources to stem elongation ultimately affect the yield of harvestable tissues in crop species. Previous studies have shown that hypocotyl growth in low red to far-red shade is largely dependent on the photoreceptor phytochrome B and the phytohormone auxin. However, where shade is perceived in the plant and how auxin regulates growth spatially are less well understood. Using the oilseed and vegetable crop species Brassica rapa, we show that the perception of low red to far-red shade by the cotyledons triggers hypocotyl cell elongation and auxin target gene expression. Furthermore, we find that following shade perception, elevated auxin levels occur in a basipetal gradient away from the cotyledons and that this is coincident with a gradient of auxin target gene induction. These results show that cotyledon-generated auxin regulates hypocotyl elongation. In addition, we find in mature B. rapa plants that simulated shade does not affect seed oil composition but may affect seed yield. This suggests that in field settings where mutual shading between plants may occur, a balance between plant density and seed yield per plant needs to be achieved for maximum oil yield, while oil composition might remain constant.
Highlights
Plant architecture is optimized for the local light environment
The median speed of auxin movement along the eudicot hypocotyl is 7 mm h21 (Kramer et al, 2011). If we assume this speed to be true for the Brassica genus, it would take greater than 2 h for newly synthesized apical auxin to move to the base of a typical 7-d-old B. rapa hypocotyl
Studies using Arabidopsis have indicated that the cotyledons are the most likely source of increased auxin synthesis in low R:FR shade (Tanaka et al, 2002; Tao et al, 2008) and that phytochrome B (phyB) functions in cotyledons to modulate hypocotyl growth (Endo et al, 2005)
Summary
In response to foliar shade or neighbor proximity (low red to far-red light), some plant species exhibit shade-avoiding phenotypes, including increased stem and hypocotyl growth, which increases the likelihood of outgrowing competitor plants. Using the oilseed and vegetable crop species Brassica rapa, we show that the perception of low red to far-red shade by the cotyledons triggers hypocotyl cell elongation and auxin target gene expression. We find that following shade perception, elevated auxin levels occur in a basipetal gradient away from the cotyledons and that this is coincident with a gradient of auxin target gene induction These results show that cotyledon-generated auxin regulates hypocotyl elongation. The SAS includes hypocotyl and stem elongation, reduced root and leaf growth, and reduced defenses against herbivores and pathogens This adaptive response can be viewed as a competitive strategy to allocate resources toward growth that alters plant architecture to enable better light harvesting. PIF targets include genes encoding the YUCCA family of flavin monooxygenases that catalyze the rate-limiting step in auxin biosynthesis and other growth-promoting genes (Mashiguchi et al, 2011; Won et al, 2011; Hornitschek et al, 2012; Li et al, 2012)
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