Molecular mechanisms of shade tolerance in plants

Summary Shade tolerance is an ecological concept used in a wide range of disciplines, from plant physiology to landscaping or gardening. It refers to the strategy of some plants to persist and even thrive in environments with low light levels because of the shade produced by the vegetation proximity...

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Bibliographic Details
Published in:The New phytologist 2023-08, Vol.239 (4), p.1190-1202
Main Authors: Martinez‐Garcia, Jaime F., Rodriguez‐Concepcion, Manuel
Format: Article
Language:English
Subjects:
Arabidopsis - genetics
Arabidopsis Proteins - metabolism
Comparative analysis
Comparative studies
Components
Crops, Agricultural - metabolism
Elongation
Gardening
Gene Expression Regulation, Plant
HFR1
Hypocotyl - metabolism
Landscaping
Light
light intensity
Light levels
low R : FR
Molecular modelling
Molecular properties
phytochromes
PIFs
Plant communities
Plant physiology
Plant populations
Plants
Plants (botany)
Proximity
Shade
shade avoidance
shade tolerance
Species
Understory
Vegetation
vegetation proximity
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Summary:Summary Shade tolerance is an ecological concept used in a wide range of disciplines, from plant physiology to landscaping or gardening. It refers to the strategy of some plants to persist and even thrive in environments with low light levels because of the shade produced by the vegetation proximity (e.g. in the understory). Shade tolerance influences the organization, structure, functioning, and dynamics of plant communities. However, little is known about its molecular and genetic basis. By contrast, there is a good understanding on how plants deal with the proximity of other plants, a divergent strategy used by most crops to respond to vegetation proximity. While generally shade‐avoiding species strongly elongate in response to the proximity of other plants, shade‐tolerant species do not. Here we review the molecular mechanisms that control the regulation of hypocotyl elongation in shade‐avoiding species as a reference framework to understand shade tolerance. Comparative studies indicate that shade tolerance is implemented by components also known to regulate hypocotyl elongation in shade‐avoiding species. These components, however, show differential molecular properties that explain how, in response to the same stimulus, shade‐avoiding species elongate while shade‐tolerant ones do not.
ISSN:0028-646X
1469-8137
DOI:10.1111/nph.19047