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Major Steps in Early Animal Evolution (Review Nielsen, 2008)

This review explores the major steps in early animal evolution, including multicellularity, sealed epithelium, an organized nervous system, third germ line, bilateral symmetry, and a tubular gut. It discusses the importance of these steps and the groups where these characters were first evident.

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Major Steps in Early Animal Evolution (Review Nielsen, 2008)

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  1. Major Steps in Early Animal Evolution (Review Nielsen, 2008)

  2. numbers in green represent Neilsen’s (2008) 6 major steps Tubular Gut 6 4,5,6 Triploblastica: 3 germ lines 5 Bilateria(Cnidaria included or excluded?) 4 3 Eumetazoa: organs (include organized nervous system) 3 2 3. Basal lamina, true sealed 2 epithelium (include Homoscleromorpha) 2. Desmosomes (sealed epithelia) 1. Metazoa (multicellularity) 1 1

  3. Rudolph Zallinger’s March of Progress There is support, from both 18S rDNA and the Hox gene sequences that most flatworms are derived coelomates. What is the (mis)perception depicted in Zallinger’s “March of Progress” ? How is the evolution of flatworms relevant to the “March of Progress”?

  4. Major Steps in Early Animal Evolution (Review Nielsen, 2008)

  5. Outline • 1. Multicellularity • Self non-self recognition, immunity • 2. True Sealed Epithelium • 3. An Organized Nervous System • 4. Third Germ Line • Bilateral Symmetry • Tubular (Through) gut • Why were these steps important? • In what groups were these characters first evident?

  6. Multicellularity • The ancestral metazoa or • Urmetazoa was a highly specialized pelagic choanoflagellate • B. nutrients were shared between cells, and integrity is maintained by cadherins etc. • Differentiation of roles charac-terizes the more advanced choanoblastea. • Differentiation followed by transition to bottom dwelling adult phase (pelago-benthic) and life cycle with drifting larvae

  7. Multicellularity (cntd) • E. Evolution of multicellularity • perhaps accompanied/or closely followed by individuation, including self recognition, histoincompatibility • Immune system, and apoptosis • (Mueller 2003) • The Urmetazoa possessed these characters, which were passed on to PORIFERA • (but dedicated sensory cells and nerve cells are not present)

  8. 2.Origin of sealed epithelia and extracellular digestion • scattered cadherin molecules become organized near apical pole of cells, where they form occluding and adherensjuctions and seal the epithelia B. Sealed epithelia allow for extracellular digestion; digestive processes can only function in an enclosed space; invagination of the epithelium could lead to origin of archenteron. C. Digestive epithelium becomes endoderm

  9. 2.Origin of sealed epithelia and extracellular digestion D. Homoscleromorphs larvae and not adults show some features of metazoa...i.e. Ciliated epithelia with metachronal waves E. Eumetazoa more likely to have evolved from Homoscleromorph larva that became sexually mature (dissogony: reproductive structures. This phenomenon is generally known as neoteny and the end result is a juvenalization of the organism…. E.g. humans

  10. 2. Origin of sealed epithelia and extracellular digestion D. Homoscleromorphs larvae and not adults show some features of metazoa...i.e. Ciliated epithelia with metachronal waves E. Eumetazoa more likely to have evolved from Homoscleromorph larva that became sexually mature (dissogony: reproductive structures. This phenomenon is generally known as neoteny and the end result is a juvenalization of the organism…. E.g. humans

  11. Origin of a Nervous System • Absent in Sponges and Placozoa • Electrical and Chemical Synapses present in Cnidaria • Animals with a nervous system except Ctenophora form a monophyletic unit • Apical organs found in all Eumetazoa may be first nervous system • Precursors of many of the genes involved in nervous system function are present in sponges (e.g. post-synaptic scaffold) • Neurogastrea develops ciliated band to resemble trochaea, which is a larva found in most Eumetazoa.

  12. Origin of Mesoderm (Triploblastica) • A. Exact phylogenetic origin uncertain • (Ctenophore mesoderm has independent origin) • B. Mesoderm certainly derived from Endoderm; • cells involved in specification and differentiation of mesodermal cell types are found in the the starlet anemone Nematostella

  13. 5. Evolution of Bilateral Symmetry Symmetry along A-P axis and an anterior brain Body Plan Radial Bilateral Asymmetry Symmetry Symmetry Porifera Cnidaria all other animals Placozoa Ctenophora (~ 32 phyla) Echinodermata oral • 32 Phyla of Bilateria share: • Triploblasty • Coeloms • Through-guts • Central nervous system dorsal anterior ventral Radial • Why the great success? posterior aboral bilateral

  14. 5. Evolution of Bilateral Symmetry Question hinges on whether bilateral symmetry in sea anemones is homologous to that of bilateria Position of the syphonoglyph and retractor muscles impose bilateral symmetry. But these characters are unique to anemones and are not the characters that determine bilateral symmetry in bilateria – it is likely that they evolved independently.

  15. At what point did Bilateral Symmetry Evolve? Ancestor of Cnidaria Bilateria? (homologous; lost in most Cnidaria) Independently in Anthozoa and Bilateria

  16. 5. Establishment of a Tubular Gut (Eubilateria) • More efficient digestion, food absorption • Enabled evolution of larger organisms with more • complicated behaviors; exact point of origin unknown • Acoels are most primitive bilateria ; lack a thru gut • while Platyhelminthes lost a thru gut and Ctenophores evolved thru gut independently • Origin of tubular gut not resolved phylogenetically

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