A changing morphogen gradient is interpreted by continuous transduction flow

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Development 129, 2167-2180 (2002)
© 2002 The Company of Biologists Limited

A changing morphogen gradient is interpreted by continuous transduction flow

P.-Y. Bourillot, N. Garrett and J. B. Gurdon^*

Wellcome/CRC Institute, Tennis Court Road, Cambridge, CB2 1QR, and Department of Zoology, University of Cambridge, UK

*Author for correspondence (e-mail: j.b.gurdon{at}welc.cam.ac.uk)

Accepted 21 February 2002

In vertebrate development, most signalling factors behave asmorphogens, eliciting divergent cell fates according to theirconcentration. We ask how cells interpret morphogen concentrationas it changes during the establishment of a gradient. Usingdissociated blastula cells of Xenopus exposed to activin foronly 10 minutes, we have followed the phosphorylation of taggedSmad2, the principal activin transducer, from a cytoplasmicpool to the nucleus in real time. We show that a changing concentrationof extracellular activin is rapidly and continuously transducedto provide a corresponding nuclear concentration of Smad2, eventhough gene response may be delayed for several hours. NuclearSmad2 concentration changes up as the extracellular concentrationof activin increases. We conclude that cells interpret a changingextracellular concentration by maintaining a continuous flowof activated transducer from a large cytoplasmic pool to thenucleus where it is degraded. The volume of this flow determinesthe steady state concentration of Smad2 in the nucleus and thisis used by cells to interpret extracellular morphogen concentration.

Key words: Morphogen, TGFß, Smad2, Xenopus

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