Character Diagnosis, Fossils and the Origin of Tetrapods

Panchen, Alec L.; Smithson, Timothy R.

doi:10.1111/j.1469-185x.1987.tb01635.x

Cited by 140 publications

(156 citation statements)

References 95 publications

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“…One essential adaptation in the evolution of tetrapods was the ability to locomote on land, a trait that required significant morphological and functional changes in the appendicular system. Many of these morphological changes can be observed in the fossil record (1)(2)(3)(4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14). Work on basal tetrapod fossils has revealed that even those with digited limbs can be aquatic (5,7).…”

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confidence: 99%

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Behavioral evidence for the evolution of walking and bounding before terrestriality in sarcopterygian fishes

King

Shubin

Coates

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

119

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Tetrapods evolved from sarcopterygian fishes in the Devonian and were the first vertebrates to colonize land. The locomotor component of this transition can be divided into four major events: terrestriality, the origins of digited limbs, solid substrate-based locomotion, and alternating gaits that use pelvic appendages as major propulsors. As the sister group to tetrapods, lungfish are a morphologically and phylogenetically relevant sarcopterygian taxon for understanding the order in which these events occurred. We found that a species of African lungfish (Protopterus annectens) uses a range of pelvic fin-driven, tetrapod-like gaits, including walking and bounding, in an aquatic environment, despite having a derived limb endoskeleton and primitively small, muscularly supported pelvis. Surprisingly, given these morphological traits, P. annectens also lifts its body clear of the substrate using its pelvic fins, an ability thought to be a tetrapod innovation. Our findings suggest that some fundamental features of tetrapod locomotion, including pelvic limb gait patterns and substrate association, probably arose in sarcopterygians before the origin of digited limbs or terrestriality. It follows that the attribution of some of the nondigited Devonian fossil trackways to limbed tetrapods may need to be revisited.T he vertebrate water-to-land transition initiated in the Devonian was a key event in the history of life. The ability to move in a variety of terrestrial and semiterrestrial environments opened up a range of new ecosystems for colonization and led to the diversity of tetrapod clades we see today. One essential adaptation in the evolution of tetrapods was the ability to locomote on land, a trait that required significant morphological and functional changes in the appendicular system. Many of these morphological changes can be observed in the fossil record (1-14). Work on basal tetrapod fossils has revealed that even those with digited limbs can be aquatic (5, 7). Some major questions these findings raised were how tetrapod-like limbs functioned in aquatic habitats, and in what sequence the characteristics of terrestrial tetrapod locomotion were acquired. These characteristics include the broad use of alternating limb movements, as in walking, the use of pelvic appendages as major propulsors, and the use of a bottom substrate (i.e., the solid surface underlying the fluid environment) to generate propulsive force.Whereas body fossils cannot directly inform the order in which these functional traits were acquired, fossil trackways can give us valuable information on how animals moved. Many fossil trackways from the Devonian are indicative of quadrupedal and bipedal gaits very similar to those used by modern terrestrial tetrapods (1,3,9,13,14). That tracks were preserved demonstrates that these animals were walking on a substrate. That these trackways have a cosmopolitan distribution implies that the animals responsible for generating them were themselves widespread, and likely abundant and diverse. Because we can...

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“…Lungfishes, including P. annectens, are the sister group to living tetrapods (2,4,15), and as such are important for understanding the evolution of movement patterns and limb function in this group. P. annectens is clearly specialized relative to other sarcopterygians in that its fins are longer and more slender than all other known examples (16,17).…”

mentioning

confidence: 99%

Behavioral evidence for the evolution of walking and bounding before terrestriality in sarcopterygian fishes

King

Shubin

Coates

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

119

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“…However, now they are reduced to only three relict genera that are found in Australia, Africa, and South America (Neoceratodus, Protopterus, and Lepidosiren;Forey 1987;Cloutier and Forey 1991). Despite much research there is still no general agreement regarding the phylogenetic relationships among Actinistia, Dipnoi, and Rhipidistia (including Tetrapoda; Ahlberg 1991; Cloutier and Ahlberg 1996;Forey 1988Long 1995;Maisey 1996;Marshall and Schultze 1992;Meyer 1995;Nelson 1994;Panchen and Smithson 1987;Rosen et al 1981;Schultze 1994). This controversy will continue until new relevant fossils of intermediate forms connecting the three groups are discovered, and agreement among paleontologists about the homology of some characters (e.g., the choanae) is achieved (Forey 1988;Schultze 1994;Rosen et al 1981).…”

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confidence: 99%

“…Panchen and Smithson 1987). This major evolutionary transition involved many sweeping morphological (e.g., evolution of limbs and air breathing), physiological, and behavioral changes, but nonetheless it seems to have taken place within an astonishingly short period of time of only 10-20 million years (Carroll 1988;Maisey 1996;Cloutier and Ahlberg 1996).…”

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Molecular Phylogenetic Information on the Identity of the Closest Living Relative(s) of Land Vertebrates

Zardoya

Meyer

1997

Naturwissenschaften

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The phylogenetic position of tetrapods relative to the other two living sarcopterygian lineages (lungfishes and the coelacanth) has been subject to debate for many decades, yet remains unresolved. There are three possible alternatives for the phylogenetic relationships among these three living lineages of sarcopterygians, i.e., lungfish as living sister group of tetrapods, the coelacanth as closest living relative of tetrapods, and lungfish and coelacanth equally closely related to tetrapods. To resolve this important evolutionary question several molecular data sets have been collected in recent years, the largest being the almost complete 28S rRNA gene sequences (about 3500 bp) and the complete mitochondrial genomes of the coelacanth and a lungfish (about 16 500 bp each). Phylogenetic analyses of several molecular data sets had not provided unequivocal support for any of the three hypotheses. However, a lungfish+tetrapod or a lungfish+coelacanth clade were predominantly favored over a coelacanth+tetrapod grouping when the entire mitochondrial genomes alone or in combination with the nuclear 28S rRNA gene data were analyzed with maximum parsimony, neighbor-joining, and maximum likelihood phylogenetic methods. Also, current paleontological and morphological data seem to concur with these molecular results. Therefore the currently available molecular data seems to rule out a coelacanth+tetrapod relationship, the traditional textbook hypothesis. These tentative molecular phylogenetic results point to the inherent difficulty in resolving relationships among lineages which apparently originated in rapid succession during the Devonian.Correspondence to: A. Meyer Present address: 1 Museo nacional de Ciencias Naturales, Jose Gutierrez Abascal, 2, E-28006 Madrid, Spain 2 Department of Biology, University of Constance, Postfach 5560, D-78457 Constance, Germany; e-mail: axel.meyer@uni.konstanz.de T he transition from life in water to life on land was perhaps one of the most significant events in the evolution of vertebrates (e.g. Panchen and Smithson 1987). This major evolutionary transition involved many sweeping morphological (e.g., evolution of limbs and air breathing), physiological, and behavioral changes, but nonetheless it seems to have taken place within an astonishingly short period of time of only 10-20 million years (Carroll 1988;Maisey 1996;Cloutier and Ahlberg 1996). It is well established that the early tetrapods evolved from lobe-finned fishes (Sarcopterygii) and not from rayfinned fishes (Actinopterygii; e.g., Romer 1966). However, due to the general scarcity of fossils, and the difficulty in character definitions, hence homology assignments, it has been highly controversial which lineage of the sarcopterygians is the one most closely related to land vertebrates (Cloutier and Ahlberg 1996;Forey 1988;Schultze 1994; for a review see Meyer 1995). Sarcopterygians are currently divided into three major groups (Table 1): Rhipidistia, Actinistia, and Dipnoi (e.g., Carroll 1988; Schultze 1994; Table 1). Rhipidisti...

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“…Previously, Panchen and Smithson (1987) discussed many of the points made here. (1) Cladistic methodology is necessary for a solution to this problem.…”

Section: Toward a Resolution Of The Origin Of Tetrapodsmentioning

confidence: 99%

Molecules, fossils, and the origin of tetrapods

Meyer

Dolven

1992

J Mol Evol

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Summary. Since the discovery of the coelacanth, L a t i m e r i a c h a l u m n a e , more than 50 years ago, paleontologists and comparative morphologists have debated whether coelacanths or lungfishes, two groups of lobe-finned fishes, are the closest living relatives of land vertebrates (Tetrapoda). Previously, Meyer and Wilson (1990) determined partial DNA sequences from two conservative mitochondrial genes and found support for a close relationship of lungfishes to tetrapods. We present additional D N A sequences from the 12S r R N A mitochondrial gene for three species of the two lineages of lungfishes that were not represented in the first study: Protopterus a n n e c t e n s a n d Protopterus aethiopicus from Africa and N e o c e r a t o d u s forsteri (kindly provided by B. Hedges and L. Maxson) from Australia. This extended data set tends to group the two lepidosirenid lungfish lineages (Lepidosiren and Protopterus) with N e o c e r a t o d u s as their sister group. All lungfishes seem to be more closely related to tetrapods than the coelacanth is. This result appears to rule out the possibility that the coelacanth lineage gave rise to land vertebrates. The common ancestor of lungfishes and tetrapods might have possessed multiple morphological traits that are shared by lungfishes and tetrapods [Meyer and Wilson (1990) listed 14 such traits]. Those traits that seem to link L a t i m e r i a and tetrapods are arguably due to convergent evolution or reversals and not to common descent. In this way, the molecular tree facilitates an evolutionary interpretation of the morphological differences among the living forms. We recommended that the extinct groups of lobe-finned fishes be placed onto the molecular tree that has lungfishes and not the coelacanth more closely related to tetrapods. The placement of fossils would help to furOffprint requests to: Axel Meyer ther interpret the sequence of morphological events and innovations associated with the origin of tetrapods but appears to be problematic because the quality of fossils is not always high enough, and differences among paleontologists in the interpretation of the fossils have stood in the way of a consensus opinion for the branching order among lobefinned fishes. Marshall and Schultze (1992) criticized the morphological analysis presented by Meyer and Wilson (1990) and suggest that 13 of the 14 morphological traits that support the sister group relationship of lungfishes and tetrapods are not shared derived characters. Here we present further alternative viewpoints to the ones of Marshall and Schultze (1992) from the paleontological literature. We argue that all available information (paleontological, neontological, and molecular data) and rigorous cladistic methodology should be used when relating fossils and extant taxa in a phylogenetic framework. K e y w o r d s : Polymerase chain reaction --12S rRNA --Coelacanth --L a t i m e r i a c h a l u m n a e -- Ray-finned fishes --Lungfishes --L e p i d o s i r e n --Protopterus --N e o c e r a t o d u s ...

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Character Diagnosis, Fossils and the Origin of Tetrapods

Cited by 140 publications

References 95 publications

Behavioral evidence for the evolution of walking and bounding before terrestriality in sarcopterygian fishes

Behavioral evidence for the evolution of walking and bounding before terrestriality in sarcopterygian fishes

Molecular Phylogenetic Information on the Identity of the Closest Living Relative(s) of Land Vertebrates

Molecules, fossils, and the origin of tetrapods

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