An Essay on “The Chemical Basis of Morphogenesis” written by A. Turing Yongjin Park (99328-162), Dept. of Biological Sciences.

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Presentation transcript:

An Essay on “The Chemical Basis of Morphogenesis” written by A. Turing Yongjin Park ( ), Dept. of Biological Sciences

Agenda Morphogenetic model A critique on the article Conclusion regarding complexity

Morphogenetic Model Morphogenesis := morphology (shape) + genesis (development) Chemical reagent (I.e., hormones) matters Enzyme kinetics: velocity ∝ concentration Osmotic pressure as driving force Cell as a single system Morphogen as a single unit Units ∈ System

Morphogenetic Model cont. Model organism (hydra)

Morphogenetic Model cont.

A critique on Turing Mathematically rigorous model but not biologically relevant. Physical basis simultaneously contributes to the morphogenesis in more fundamental aspects. Skeletal structures (both extra and intra) Almost not permeable (or highly selective) cell membrane Tightly controlled cell division cycle Membrane tension Cell migration (neural navigation) A single cell is far more complex.

Sui Huang & Donald E. Ingber, Nature Cell Biology 1, E131 - E138 (1999)

Sui Huang & Donald E. Ingber, Nature Cell Biology 1, E131 - E138 (1999)

Marc Neumann & Markus Affolter, EMBO reports 7, 1, 36 – 40 (2006)

Olga C. Rodriguez et al., Nature Cell Biology 5, (2003)

Luca Tamagnone & Paolo M. Comoglio, EMBO reports 5, 4, 356 – 361 (2004)

Cellular network model

Conclusion Simplicity within complexity Oscillating chemical gradient is at the heart of biological homeostasis. Morphogenesis or chemical computing Chicken or egg problem Physical complexity leads to computing structure Network model of state machines But even central dogma is not devised in 1950’s. Biological state machine  DNA computing.