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Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
The Vertebrate Archetype (Richard Owen)
Reading Benton Chapter 5
Evolution of the Skeleton
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Next week
Tuesday (17 Sept): Paper Discussion
Purnell, M. A. 2001. Scenarios, selection and the ecology of early vertebrates. Pp. 187-208 in P. E. Ahlberg (ed.), Major Events in Vertebrate Evolution: Palaeontology, Phylogeny, Genetics, and Development. Palaeontological Association Special Volume Series, 61. Taylor and Francis: London.
Wednesday (18 Sept): No formal lab
You may visit the Zooarchaeology Collection during lab hours. Let Ryan Kennedy know as a courtesy if you plan on going ([email protected]).
Thursday (19 Sept): No lecture
Tuesday (24 Sept): Midterm I, Project proposal due
• be able to fully label diagrams of dermatocranium and amniote skeleton• be familiar with terms listed in Lab 1 handout• be familiar with modern tetrapod groups and their phylogenetic relationships• be familiar with the Carboniferous Crisis and its relevance to vertebrate evolution (first lecture, see
reference by Sahney et al if you want to read more)• be familiar with the homology and evolution material from today’s lecture• be familiar with chordate characters and early fossil chordates
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Schematic view of two aspects of evolution
Morphology(e.g., big tabular versus small tabular)
Tim
e
Descendant A Descendant B
Ancestor
Speciation event
Aspect 1: evolutionary change. involves change in a species’ (populations’) average morphology and variation around that mean over time. Results in morphological change.
Aspect 2: speciation. involves splitting of a species from one population into more than one. Results in increased diversity (where diversity means number of species).
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Two definitions of speciesBiological species definition: “Species is a population of interbreeding individuals reproductively isolated from other such populations” (after Mayr, 1942)
• emphasizes the fact that there is variation within species• emphasizes that the only way for species to become different is when they
are reproductively isolated• emphasizes that speciation requires the breakdown of gene flow for two
isolated populations to emerge
Evolutionary species definition: “Species is a lineage (ancestor-descendant sequence of populations) evolving separately from others with its own tendencies” (after Simpson, 1961)
• emphasizes role of reproductive isolation in speciation• emphasizes evolutionary change within a species, separate from speciation
itself• A biological species is essentially one population in the set of ancestor-
descendant populations in the evolutionary species
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Two definitions of evolution“Descent with modification”. (after Darwin, 1859)
• recognizes that descendant is a modified form of ancestor• homologies are modified features inherited from ancestor
“Control of development by ecology”. (after Van Valen, 1974)
• recognizes that the phenotype of an organism is produced by developmental processes that are only partly genetic
• by “ecology” refers to the ability of an organism to function in its environment and in relation to other species with the phenotype it possesses
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Two kinds of evolutionary change
Modification of ancestral features
involves the inheritance of homologous structures with modification in their size, shape, position, or function.
Examples: enlargement of openings between existing bones, reduction in the size of bones, incorporation of bones of mandible into bones of middle ear, modification of branchial arches into mandibular and hyoid arches, fusion of metatarsal bones into a single tarsometatarsus
Origin of novel features
involves origin of a new feature that wasn’t present in ancestor.
Examples: origin of new bones in fins or limbs. increase in the number of vertebrae or digits.
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Romanes, 1892 (reproduced in Bolker and Raff, 1996)
Homology and “analogy”The bones of the forelimbs of pterosaurs, bats, and birds are homologous, shared from their common amniote ancestor (humerus, radius and ulna, carpals, phalanges)
The wing structure is not homologous because it evolved independently in the three groups (wings are termed “analogous”, or non-homologous)
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Zoology Research Collections, Naturhistoriska riksmuseet, Stockholm (photo by P. David Polly, 2009)
Formal definitions of homologyCorresponding structures in different organisms
[homology is] “the same organ in different animals under every variety of form and function” - Richard Owen, 1843
“a feature in two or more organisms is homologous when it is derived from the same (or corresponding) feature in their common ancestor” - Ernst Mayr, 1982
Homology is a key concept for the interpretation of fossil organisms, for phylogeny recontstruction, and for understanding of mechanisms of evolution
Criteria for homology include similarity of structure and position, the documentation of transitional forms in the fossil record, the study of development (or ontogeny).
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Owen, R. 1847. On the archetype and homologies of the vertebrate skeleton. London.
Richard Owen and the vertebrate archetypeOwen (1804-1892) was the pre-eminent paleontologist and anatomist in London
Contemporary of Queen Victoria, Charles Darwin, and Thomas Huxley
Described many fossils, including the first Archaeopteryx and the fossils Darwin collected in South America
Interested in reconciling the apparent contradictions between functional adaptation and the structural continuity represented by homology
Developed the idea of the vertebrate archetype, a common structural plan from which all vertebrates are derived
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Homology - the same structure in different organisms under every variety of form and function inherited from the common ancestor of those organisms.
Serial homology - repetition of the same structure within an organism, such as vertebrae, ribs, legs in arthropods, gills in fish, etc.
Deep homology - similar structures derived from the same underlying patterns of gene expression, even if the structures have different evolutionary origins and losses.
Primary homology - a homology recognized based on structural similarity, but whose inheritance from a common ancestor has not been tested by phylogenetic analysis.
Secondary homology - a homology whose evolution from a common ancestor has been confirmed by phylogenetic analysis.
Types of homology
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Coates, M. I., M. Ruta, and M. Friedman. 2008. Ever since Owen: changing perspectives on the early evolutio of tetrapods. Annual Review of Ecology, Evolution, and Systematics, 39: 571-592.
Example 1: tetrapod limb
Transformation of early tetrapod limb involves modification of bones, loss of some bones, addition of other bones
Formation and growth of these bones is regulated by gene expression during development. Changes in the regulation result in evolutionary changes in the adult.
In earliest development, the precursors of the bones are similar in tetrapods and their closest relatives.
Developmental biology (ontogeny) is an important aid to paleontologists for identifying or confirming homologies in radically transformed groups
Sauripterusfinned tetrapod
Baramedafinned tetrapod
Tiktaalikfinned tetrapod
Eusthenopteronfinned tetrapod
Gogonasusfinned tetrapod
Sterropterygionfinned tetrapod
Rhizodopsisfinned tetrapod
Acanthostegalimbed tetrapod
Tulerpetonlimbed tetrapod
Greererpetonlimbed tetrapod
Westlothianalimbed tetrapod
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Example 2: HOX genes and regionalization
HOX (homeobox) genes control the boundaries of morphological regions
They are shared by all bilateral organisms, maybe all animals in general
HOX genes are expressed in different areas of the developing embryo in the same order as they are found on chromosomes
Expression of these genes create boundaries inside which structures develop differently, such as cervical versus thoracic regions
Expression in Mammal Embryo
Position on Chromosomes
Expression in Fly Embryo
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Wellik, 2009. Current Topics in Developmental Biology, 88: 257-278.
Mutation in HOX gene doubles the axis bone (C2)
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Müller et al., 2010. PNAS, 107: 2118-2123.
Evolution of cervical-dorsal boundary in amniotesEvidence for shifts in HOX expression
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Evans, 1993. Miller’s Anatomy of the Dog
Developing thoracic vertebra and rib in a dogBlue = cartilageRed = bone ossification center
Example 3: vertebral evolution
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Early development of the centrum in the chick (from Patten, 1958. Foundations of Embryology.)
Early vertebral development
Somites
Vertebrae are modeled around notochord from somite tissue
Each vertebra develops between somites, receiving tissue from one in front and one behind
Directly related to evolutionary transformations in vertebrae of early tetrapods
9 day mouse embryo, before skeletal development begins
Neural tube
Heart
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
(tree from Coates, et al. 2008. Annual Review of Ecology, Evolution, and Systematics, 39: 571-592)
Vertebral evolution in early tetrapodsLissamphibians retain intercentrum, amniotes retain pleurocentrum
Neural arch
Intercentrum
Pleurocentrum
Mastodontosaurus
Eryops
Icthyostega
Seymouria
Amniote
Anterior
Department of Geological Sciences | Indiana University (c) 2011, P. David Polly
G404 Geobiology
Scientific papers for further readingBolker, J. A. and R. A. Raff. 1996. Developmental genetics and traditional homology. Bioessays, 18: 489-494.
Coates, M. I., M. Ruta, and M. Friedman. 2008. Ever since Owen: changing perspectives on the early evolution of tetrapods. Annual Review of Ecology, Evolution, and Systematics, 39: 571-592.
Müller, J., T. M. Scheyer, J. J. Head, P. M. Barrett, I. Werneburg, P. G. P. Ericson, D. Pol, and M. R. Sánchez-Villagra. 2010. Homeotic effects, somitogenesis and the evolution of vertebral numbers in recent and fossil amniotes. PNAS, 107: 2118-2123.
Polly, P. D. 2007. Limbs in mammalian evolution. Pp. 245-268, in Fins into Limbs: Evolution, Development, and Transformation, Brian K Hall (ed.). University of Chicago Press: Chicago.
Wellick, D. M. 2009. Hox genes and vertebrate axial pattern. Current Topics in Developmental Biology, 88: 257- 278.