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Cryptochrome-Timeless structure reveals circadian clock timing mechanisms.

Changfan LinShi FengCristina C DeOliveiraBrian R Crane
Published in: Nature (2023)
Circadian rhythms influence many behaviours and diseases 1,2 . They arise from oscillations in gene expression caused by repressor proteins that directly inhibit transcription of their own genes. The fly circadian clock offers a valuable model for studying these processes, wherein Timeless (Tim) plays a critical role in mediating nuclear entry of the transcriptional repressor Period (Per) and the photoreceptor Cryptochrome (Cry) entrains the clock by triggering Tim degradation in light 2,3 . Here, through cryogenic electron microscopy of the Cry-Tim complex, we show how a light-sensing cryptochrome recognizes its target. Cry engages a continuous core of amino-terminal Tim armadillo repeats, resembling how photolyases recognize damaged DNA, and binds a C-terminal Tim helix, reminiscent of the interactions between light-insensitive cryptochromes and their partners in mammals. The structure highlights how the Cry flavin cofactor undergoes conformational changes that couple to large-scale rearrangements at the molecular interface, and how a phosphorylated segment in Tim may impact clock period by regulating the binding of Importin-α and the nuclear import of Tim-Per 4,5 . Moreover, the structure reveals that the N terminus of Tim inserts into the restructured Cry pocket to replace the autoinhibitory C-terminal tail released by light, thereby providing a possible explanation for how the long-short Tim polymorphism adapts flies to different climates 6,7 .
Keyphrases
  • gene expression
  • single molecule
  • cell free
  • oxidative stress
  • genome wide
  • hepatitis c virus
  • hiv infected
  • circulating tumor
  • molecular dynamics simulations
  • heat stress
  • bioinformatics analysis
  • binding protein