Body plan

A body plan, Bauplan (pl. German: Baupläne), or ground plan is a set of morphological features common to many members of a phylum of animals.[1] The vertebrates share one body plan, while invertebrates have many.

Modern groups of animals can be grouped by the arrangement of their body structures, so are said to possess different body plans.

This term, usually applied to animals, envisages a "blueprint" encompassing aspects such as symmetry, layers, segmentation, nerve, limb, and gut disposition. Evolutionary developmental biology seeks to explain the origins of diverse body plans.

Body plans have historically been considered to have evolved in a flash in the Ediacaran biota; filling the Cambrian explosion with the results, and a more nuanced understanding of animal evolution suggests gradual development of body plans throughout the early Palaeozoic. Recent studies in animals and plants started to investigate whether evolutionary constraints on body plan structures can explain the presence of developmental constraints during embryogenesis such as the phenomenon referred to as phylotypic stage.

History

Among the pioneering zoologists, Linnaeus identified two body plans outside the vertebrates; Cuvier identified three; and Haeckel had four, as well as the Protista with eight more, for a total of twelve. For comparison, the number of phyla recognised by modern zoologists has risen to 36.[1]

Linnaeus, 1735

In his 1735 book Systema Naturæ, Swedish botanist Linnaeus grouped the animals into quadrupeds, birds, "amphibians" (including tortoises, lizards and snakes), fish, "insects" (Insecta, in which he included arachnids, crustaceans and centipedes) and "worms" (Vermes). Linnaeus's Vermes included effectively all other groups of animals, not only tapeworms, earthworms and leeches but molluscs, sea urchins and starfish, jellyfish, squid and cuttlefish.[2]

Cuvier, 1817

Haeckel's 'Monophyletischer Stambaum der Organismen' from Generelle Morphologie der Organismen (1866) with the three branches Plantae, Protista, Animalia

In his 1817 work, Le Règne Animal, French zoologist Georges Cuvier combined evidence from comparative anatomy and palaeontology[3] to divide the animal kingdom into four body plans. Taking the central nervous system as the main organ system which controlled all the others, such as the circulatory and digestive systems, Cuvier distinguished four body plans or embranchements:[4]

  1. with a brain and a spinal cord (surrounded by skeletal elements)[4]
  2. with organs linked by nerve fibres[4]
  3. with two longitudinal, ventral nerve cords linked by a band with two ganglia below the oesophagus[4]
  4. with a diffuse nervous system, not clearly discernible[4]

Grouping animals with these body plans resulted in four branches: vertebrates, molluscs, articulata (including insects and annelids) and zoophytes or radiata.

Haeckel, 1866

Ernst Haeckel, in his 1866 Generelle Morphologie der Organismen, asserted that all living things were monophyletic (had a single evolutionary origin), being divided into plants, protista, and animals. His protista were divided into moneres, protoplasts, flagellates, diatoms, myxomycetes, myxocystodes, rhizopods, and sponges. His animals were divided into groups with distinct body plans: he named these phyla. Haeckel's animal phyla were coelenterates, echinoderms, and (following Cuvier) articulates, molluscs, and vertebrates.[5]

Gould, 1979

Stephen J. Gould explored the idea that the different phyla could be perceived in terms of a Bauplan, illustrating their fixity. However, he later abandoned this idea in favor of punctuated equilibrium.[6]

Origin

20 out of the 36 body plans originated in the Cambrian period,[7] in the "Cambrian explosion",[8] However, complete body plans of many phyla emerged much later, in the Palaeozoic or beyond.[9]

The current range of body plans is far from exhaustive of the possible patterns for life: the Precambrian Ediacaran biota includes body plans that differ from any found in currently living organisms, even though the overall arrangement of unrelated modern taxa is quite similar.[10] Thus the Cambrian explosion appears to have more or less completely replaced the earlier range of body plans.[7]

Genetic basis

Genes, embryos and development together determine the form of an adult organism's body, through the complex switching processes involved in morphogenesis.

Developmental biologists seek to understand how genes control the development of structural features through a cascade of processes in which key genes produce morphogens, chemicals that diffuse through the body to produce a gradient that acts as a position indicator for cells, turning on other genes, some of which in turn produce other morphogens. A key discovery was the existence of groups of homeobox genes, which function as switches responsible for laying down the basic body plan in animals. The homeobox genes are remarkably conserved between species as diverse as the fruit fly and humans, the basic segmented pattern of the worm or fruit fly being the origin of the segmented spine in humans. The field of animal evolutionary developmental biology ('Evo Devo'), which studies the genetics of morphology in detail, is rapidly expanding[11] with many of the developmental genetic cascades, particularly in the fruit fly Drosophila, catalogued in considerable detail.[12]

See also

  • Anatomical terms of location  Standard terms for unambiguous description of relative placement of body parts
  • Arthropod head problem  Dispute concerning the evolution of arthropods
  • Deep homology  Control of growth and differentiation by deeply conserved genetic mechanisms
  • Evolutionary developmental biology  Comparison of organism developmental processes
  • Definition of Phylum based on body plan  High level taxonomic rank for organisms sharing a similar body plan
  • Ediacaran biota  All organisms of the Ediacaran Period (c. 635–538.8 million years ago)
  • Macroevolution  Evolution on a scale at or above the level of species
  • Precambrian body plans  Structure and development of early multicellular organisms
  • Sean B. Carroll  American evolutionary developmental biologist
  • Segmentation (biology)  Division of some animal and plant body plans into a series of segments
  • Supernumerary body part  Growth of an additional part of the body and a deviation from the body plan
  • Symmetry in biology  Geometric symmetry in living beings

References

  1. Valentine, James W. (2004). On the Origin of Phyla. p. 33. ISBN 978-0226845487.
  2. Linnaeus, Carolus (1735). Systema naturae, sive regna tria naturae systematice proposita per classes, ordines, genera, & species. Leiden: Haak. pp. 1–12.
  3. Reiss, John (2009). Not by Design: Retiring Darwin's Watchmaker. University of California Press. p. 108. ISBN 978-0-520-94440-4.
  4. De Wit, Hendrik Cornelius Dirk De Wit. Histoire du Développement de la Biologie, Volume III, Presses Polytechniques et Universitaires Romandes, Lausanne, 1994, p. 94-96. ISBN 2-88074-264-1
  5. Haeckel, Ernst. Generelle Morphologie der Organismen : allgemeine Grundzüge der organischen Formen-Wissenschaft, mechanisch begründet durch die von Charles Darwin reformirte Descendenz-Theorie. (1866) Berlin
  6. Bowler, Peter J. (2009). Evolution: the History of an Idea. California, p. 364.
  7. Erwin, Douglas; Valentine, James; Jablonski, David (1997). "Recent fossil finds and new insights into animal development are providing fresh perspectives on the riddle of the explosion of animals during the Early Cambrian". American Scientist (March–April).
  8. Erwin, D. H. (1999). "The Origin of Bodyplans". Integrative and Comparative Biology. 39 (3): 617–629. doi:10.1093/icb/39.3.617.
  9. Budd, G. E.; Jensen, S. (2000). "A critical reappraisal of the fossil record of the bilaterian phyla". Biological Reviews of the Cambridge Philosophical Society. 75 (2): 253–95. doi:10.1111/j.1469-185X.1999.tb00046.x. PMID 10881389. S2CID 39772232.
  10. Antcliffe, J. B.; Brasier, M. D. (2007). "Charnia and sea pens are poles apart". Journal of the Geological Society. 164 (1): 49–51. Bibcode:2007JGSoc.164...49A. doi:10.1144/0016-76492006-080. S2CID 130602154.
  11. Hall, Brian K. (28 March 2005). "Evo Devo is the New Buzzword..." Scientific American. 292 (4): 102–104. Bibcode:2005SciAm.292d.102H. doi:10.1038/scientificamerican0405-102. Retrieved 13 September 2014.
  12. Arthur, Wallace. (1997). Animal Body Plans. Cambridge England: Cambridge University Press. ISBN 0-521-77928-6.
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