LED Lighting Strategies Affect Physiology and Resilience to Pathogens and Pests in Eggplant ( Solanum melongena L.)

LED Lighting Strategies Affect Physiology and Resilience to Pathogens and Pests in Eggplant ( Solanum melongena L.)

Over the last decade, LED lighting has gained considerable interest as an energy-efficient supplemental light source in greenhouse horticulture that can change rapidly in intensity and spectral composition. Spectral composition not only affects crop physiology but may also affect the biology of path...

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Published in:Frontiers in plant science Vol. 11; p. 610046
Main Authors: Anja Dieleman, J, Marjolein Kruidhof, H, Weerheim, Kees, Leiss, Kirsten
Format: Journal Article
Language:English
Published: Switzerland Frontiers Media S.A 13-01-2021
Subjects:
blue light
Botrytis cinera
defense response
far-red light
Plant Science
shade avoidance
Solanum melongena (L.)
blue light
defense response
far-red light
shade avoidance
Botrytis cinera
Solanum melongena (L.)
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Summary:Over the last decade, LED lighting has gained considerable interest as an energy-efficient supplemental light source in greenhouse horticulture that can change rapidly in intensity and spectral composition. Spectral composition not only affects crop physiology but may also affect the biology of pathogens, pests, and their natural enemies, both directly and indirectly through an impact on induced plant resistance. In this study, we investigated the effects of light spectrum against a background of sunlight on growth and development of . These effects were related to the spectral effects on the establishment of populations of the predatory mite and plant resilience against the biotrophic fungus powdery mildew, the necrotrophic fungus botrytis, and the herbivorous arthropod Western flower thrips. The effects of a reduced red/far-red (R:FR) ratio were studied under two ratios of red to blue light. Far-red light either was supplied additionally to the photosynthetic photon flux density (PPFD) or partially replaced PPFD, while maintaining total photon flux density (PFD). Effects of white light or additional UV-B light on plant resilience was tested, compared to the reference (5% blue, 5% green, and 90% red light). Plant biomass in the vegetative phase increased when additional far-red light was supplied. Stem length increased with far-red, irrespective of PPFD and the percentage of blue light. In the generative phase, total shoot biomass and fruit fresh weights were higher under additional far-red light, followed by the treatments where far-red partly replaced PPFD. Far-red light increased biomass partitioning into the fruits, at the expense of the leaves. There were no differences in population growth of mites between light treatments, nor did light treatment have an effect on the vertical distribution of these predatory mites in the plants. The treatments with additional far-red light reduced the infection rate of powdery mildew, but increased botrytis infection. These differences might be due to the plant defenses acting against these pathogens evolving from two different regulatory pathways. These results show that positive effects of altered spectral compositions on physiological responses were only moderately compensated by increased susceptibility to fungal pathogens, which offers perspective for a sustainable greenhouse horticulture.
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This article was submitted to Crop and Product Physiology, a section of the journal Frontiers in Plant Science
Edited by: Sissel Torre, Norwegian University of Life Sciences, Norway
Reviewed by: Francesco Orsini, University of Bologna, Italy; Niels Holst, Aarhus University, Denmark
ISSN:1664-462X
1664-462X
DOI:10.3389/fpls.2020.610046