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Diffusion in Embryogenesis

Nature volume 225pages 420–422 (1970)Cite this article

Abstract

A simple order-of-magnitude calculation suggests that diffusion may be the underlying mechanism in establishing morphogenetic gradients in embryonic development.

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References

  1. Wolpert, L., J. Theoret. Biol., 25, 1 (1969). This article, entitled “Positional Information and the Spatial Pattern of Cellular Differentiation”, should be consulted both for a modern statement of the problem and also for references to earlier work.

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  2. The basic idea of this article was presented at a lecture given to students at the Fourth NATO Advanced Study Institute of Molecular Biology in July 1969 at Spetsai.

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  4. For a review see Lawrence, P. A., Adv. Insect Physiol. (in the press). See especially Stumpf, H., Roux Arch. Ent. Mech. Org., 158, 315 (1967).

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  7. The mechanism for forming a source and a sink for ions also presents special problems, whereas for organic molecules rather simple enzymatic processes could do the trick.

  8. The effect of temperature on the viscosity of water does not seriously affect the calculations. Taking the viscosity of water (in arbitrary units) as 1.0 at 20° C, its value at 5° C is about l½ and at 39° C is close to 2/3.

  9. See, for example, a very ingenious fluorescent method used by Victor W. Burns (Biochem. Biophys. Res. Commun., 37, 1008; 1969) using a small organic molecule. He obtained a factor of about × 6 for Euglena. The figure for yeast was about twice this.

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  11. This assumes that the permeability is fairly evenly distributed over the cell membrane. If it were concentrated in a small patch the effective diffusion would be slower.

  12. For example, P for glucose in ascites cells at 37° C in about 4.5 × 10−4 cm/s ( Kolber, A. R., and LeFevre, P. G., J. Gen. Physiol., 50, 1907; 1967), or in human red cells at 37° C about 1 × 10−4 cm/s ( Millar, D. M., Biophys. J., 5, 407; 1965). Admittedly these are among the higher values of P known so far. See Stein, W. D., The Movement of Molecules Across Cell Membranes, chap. 4 (Academic Press, New York, 1967). It should be remembered that in going from one cell to the next the morphogen may have to cross two cell membranes.

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  13. An upper limit can be calculated assuming that the morphogen is an ion, that it diffuses (at 37° C) in the cytoplasm as freely as in water, that the permeability between cells is so high that it does not slow down the process at all, and that the most efficient method is used to set up the gradient. The distance then comes to 1.5 cm, but I feel that this combination of assumptions is quite unrealistic.

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  16. The present model could be elaborated by assuming two different morphogens, one having a gradient sloping from left to right, and the other with a gradient from right to left: on this model the position of a cell would be characterized by the ratio of its concentration of the two morphogens. This particular elaboration, however, would not significantly alter any of the arguments given in this article.

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  1. Medical Research Council Laboratory of Molecular Biology, Hills Road, Cambridge

    FRANCIS CRICK

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  1. FRANCIS CRICK
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CRICK, F. Diffusion in Embryogenesis. Nature 225, 420–422 (1970). https://doi.org/10.1038/225420a0

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