摘要Plants exploit phenotypic plasticity to adapt their growth and development to prevailing environmental conditions.Interpretation of light and temperature signals is aided by the circadian system,which provides a temporal context.Phenotypic plasticity provides a selective and competitive advantage in nature but is obstructive during large-scale,intensive agricultural practices since economically important traits(including vegetative growth and flowering time)can vary widely depending on local environmental condi-tions.This prevents accurate prediction of harvesting times and produces a variable crop.In this study,we sought to restrict phenotypic plasticity and circadian regulation by manipulating signaling systems that govern plants'responses to environmental signals.Mathematical modeling of plant growth and develop-ment predicted reduced plant responses to changing environments when circadian and light signaling pathways were manipulated.We tested this prediction by utilizing a constitutively active allele of the plant photoreceptor phytochrome B,along with disruption of the circadian system via mutation of EARLY FLOW-ERING3.We found that these manipulations produced plants that are less responsive to light and temper-ature cues and thus fail to anticipate dawn.These engineered plants have uniform vegetative growth and flowering time,demonstrating how phenotypic plasticity can be limited while maintaining plant productiv-ity.This has significant implications for future agriculture in both open fields and controlled environments.