Systematics and the Exploration of Life. Группа авторов

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Systematics and the Exploration of Life - Группа авторов


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      Introduction written by Philippe GRANDCOLAS and Marie-Christine MAUREL.

      Symmetry of Shapes in Biology: from D’Arcy Thompson to Morphometrics

      1.1. Introduction

Photo depicts the diversity of symmetric patterns in the living world.

      COMMENTARY ON FIGURE 1.1. – a) Centipede (C. Brena); b) corals (D. Caron); c) orchid (flowerweb); d) spiral aloe (J. Cripps); e) nautilus (CC BY 3.0); f) plumeria (D. Finney); g) Ulysses butterfly (K. Wothe/Minden Pictures); h) capri (P. Robles/Minden Pictures); i) Angraecum distichum (E. hunt); j) desmidiale (W. Van Egmond); k) diatom (S. Gschmeissner); l) sea turtle (T. Shultz); m) radiolarian (CC BY 3.0); n) starfish (P. Shaffner).

      Thompson’s main thesis is that “physical forces”, such as gravity or surface tension phenomena, play a preponderant role in the determinism of organic forms and their diversity within the living world. His structuralist conception of the diversity of forms is accompanied by a critique of the Darwinian theory of evolution, but this critique is in fact based on an erroneous interpretation of the causal context (efficient cause vs. formal cause) presiding over the emergence of forms (Medawar 1962; Gould 1971, 2002, p. 1207).

      The notion of symmetry is present in the backdrop throughout the book. The successive chapters go through the different orders of magnitude of the organization of life and the physical forces that prevail at each of these scales. The skeletons of radiolarians, the spiral growth of mollusk shells and the diversity of phyllotactic modes are some of the examples illustrating the pivotal role of symmetry in the architecture of biological forms. This interest in symmetry is in line with the work of Ernst Haeckel, whose book Kunstformen der Natur (Haeckel 1899) offers bold anatomical representations emphasizing (and sometimes idealizing) the exuberance and sophistication of symmetry patterns found in nature. Thompson sees the harmony and regularity of symmetric forms as the geometric manifestation of the mathematical principles that establish a fundamental basis for his theory of forms.

      Beyond the questions of symmetry, Thompson’s idea of combining geometry and biology to study shapes remains at the heart of the principles and methods of modern morphometrics (Bookstein 1991, 1996).

      In this section, we propose an overview of the mathematical characterization of the notion of symmetry, as it can be applied to organic forms. The physical environment in which living organisms evolve is


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