AbstractThe Evening Complex (EC), composed of the DNA-binding protein LUX ARRHYTHMO (LUX) and two additional proteins, EARLY FLOWERING 3 (ELF3) and ELF4, is a transcriptional repressor complex and a core component of the plant circadian clock. In addition to maintaining oscillations in clock gene expression, the EC also participates in temperature and light entrainment and regulates important clock output genes such asPHYTOCHROME INTERACTING FACTOR 4(PIF4), a key transcription factor involved in temperature dependent plant growth. These properties make the EC an attractive target for altering plant development through targeted mutations to the complex. However, the molecular basis for EC function was not known. Here we show that binding of the EC requires all three proteins and that ELF3 decreases the ability of LUX to bind DNA whereas the presence of ELF4 restores interaction with DNA. To be able to manipulate this complex, we solved the structure of the DNA-binding domain of LUX bound to DNA. Using structure-based design, a LUX variant was constructed that showed decreasedin vitrobinding affinity but retained specificity for its cognate sequences. This designed LUX allele modulates hypocotyl elongation and flowering. These results demonstrate that modifying the DNA-binding affinity of LUX can be used to titrate the repressive activity of the entire EC, tuning growth and development in a predictable manner.Significance StatementCircadian gene expression oscillates over a 24 hr. period and regulates many genes critical for growth and development. In plants, the Evening Complex (EC), a three-protein repressive complex made up of LUX ARRYTHMO, EARLY FLOWERING 3 and EARLY FLOWERING 4, acts as a key component of the circadian clock and is a regulator of thermomorphogenic growth. However, the molecular mechanisms of complex formation and DNA-binding have not been identified. Here we determine the roles of each protein in the complex and present the structure of the LUX DNA-binding domain in complex with DNA. Based on these data, we used structure-based protein engineering to produce a version of the EC with alteredin vitroandin vivoactivity. These results demonstrate that the EC can be modified to alter plant growth and development at different temperatures in a predictable manner.
Photosynthetic Entrainment of the Circadian Clock Facilitates Plant Growth under Environmental Fluctuations: Perspectives from an Integrated Model of Phase Oscillator and Phloem Transportation
