Everything about Tetrapoda totally explained
Tetrapods (
Greek tetrapoda,
Latin quadruped, "four-legged") are
vertebrate animals having four
feet,
legs or leglike
appendages.
Amphibians,
reptiles,
dinosaurs,
birds, and
mammals are all tetrapods, and even the limbless
snakes are tetrapods by descent. The earliest tetrapods radiated from the
Sarcopterygii, or lobe-finned
fish, into air-breathing amphibians in the
Devonian period.
Evolution
Devonian tetrapods
Research by
Jennifer A. Clack and her colleagues showed that the earliest tetrapods, such as
Acanthostega, were wholly aquatic and quite unsuited to life on land. This overturned the earlier view that fish had first invaded the land — either in search of prey (like modern
mudskippers) or to find water when the pond they lived in dried out — and later evolved legs, lungs, etc.
The first tetrapods are now thought to have
evolved in shallow and
swampy
freshwater habitats, towards the end of the Devonian, a little more than 365 million years ago. By the late Devonian, land
plants had stabilized freshwater habitats, allowing the first
wetland ecosystems to develop, with increasingly complex
food webs that afforded new opportunities.
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Freshwater habitats were not the only places to find water filled with organic matter and choked with plants with dense vegetation near the water's edge. Swampy habitats like shallow wetlands, coastal lagoons and large brackish river deltas also existed at this time, and there's much to suggest that this is the kind of environment in which the tetrapods evolved. Early fossil tetrapods have been found in marine sediments, and because fossils of primitive tetrapods in general are found scattered all around the world, they must have spread by following the coastal lines — they couldn't have lived in freshwater only.
The common ancestor of all present
gnathostomes lived in freshwater, and later migrated back to the sea. To deal with the much higher salinity in sea water, they evolved the ability to turn the
nitrogen waste product
ammonia into harmless
urea, storing it in the body to make the blood as salty as the sea water without poisoning the organism.
Ray-finned fishes later returned to freshwater and lost this ability. Since their blood contained more salt than freshwater, they could simply get rid of ammonia through their gills. When they finally returned to the sea again, they couldn't recover their old trick of turning ammonia to urea, and they'd to evolve salt excreting glands instead.
Lungfishes do the same when they're living in water, making ammonia and no urea, but when the water dries up and they're forced to burrow down in the mud, they switch to urea production. Like cartilaginous fishes, the
coelacanth can store urea in its blood, as can the only known amphibians that can live for long periods of time in salt water (the
toad Bufo marinus and the
frog Rana cancrivora). These are traits they've inherited from their ancestors.
If early tetrapods lived in freshwater, and if they lost the ability to produce urea and used ammonia only, they'd have to evolve it from scratch again later. Not a single species of all the ray-finned fishes living today has been able to do that, so it isn't likely the tetrapods would have done so either.
Terrestrial animals that can only produce ammonia would have to drink constantly, making a life on land impossible (a few exceptions exist, as some terrestrial
woodlice can excrete their nitrogenous waste as ammonia gas). This probably also was a problem at the start when the tetrapods started to spend time out of water, but eventually the urea system would dominate completely. Because of this it isn't likely they emerged in freshwater (unless they first migrated into freshwater habitats and then migrated onto land so shortly after that they still hadn't forgot how to make urea), even if some who never went to land (or extinct primitive species that returned to water) of course could have adapted to freshwater lakes and rivers.
Primitive tetrapods developed from a lobe-finned fish (an "osteolepid
sarcopterygian"), with a two-lobed
brain in a flattened
skull, a wide mouth and a short snout, whose upward-facing eyes show that it was a bottom-dweller, and which had already developed adaptations of fins with fleshy bases and
bones (the "
living fossil" coelacanth is a related marine lobe-finned fish without these shallow-water adaptations).
Even more closely related was
Panderichthys, which even had a
choana.
These fishes used their fins as
paddles in shallow-water habitats choked with plants and
detritus. Their fins could also have been used to attach themselves to plants or similar while they were laying in ambush for prey. The universal tetrapod characteristics of front
limbs that bend backward at the
elbow and hind limbs that bend forward at the
knee can plausibly be traced to early tetrapods living in shallow water.
It is now clear that the common ancestor of the bony fishes had a primitive air-breathing
lung (later evolved into a
swim bladder in most ray-finned fishes). This suggests that it evolved in warm shallow waters, the kind of habitat the lobe finned fishes were living and made use of their simple lung when the oxygen level in the water became too low.
The lungfishes are now considered as being the closest living relatives of the tetrapods, even closer than the coelacanth.
Fleshy lobe fins supported on bones rather than ray-stiffened fins seems to have been an original trait of the bony fishes (
Osteichthyes). The lobe-finned ancestors of the tetrapods evolved them further, while the ancestors of the ray-finned (
Actinopterygii) fishes evolved their fins in the opposite direction. The most primitive group of the ray-fins, the
bichirs, still have fleshy frontal fins.
Nine
genera of Devonian tetrapods have been described, several known mainly or entirely from lower
jaw material. All of them were from the European-North American
supercontinent, which comprised
Europe,
North America and
Greenland. The only exception is a single
Gondwanan genus,
Metaxygnathus, which has been found in
Australia.
The first Devonian tetrapod identified from
Asia was recognized from a
fossil jawbone reported in 2002. The
Chinese tetrapod
Sinostega pani was discovered among fossilized tropical plants and lobe-finned fish in the red
sandstone sediments of the
Ningxia Hui Autonomous Region of northwest China. This finding substantially extended the geographical range of these animals and has raised new questions about the worldwide distribution and great taxonomic diversity they achieved within a relatively short time.
These earliest tetrapods were not terrestrial. The earliest confirmed terrestrial forms are known from the early
Carboniferous deposits, some 20 million years later. Still, they may have spent very brief periods out of water and would have used their legs to paw their way through the
mud.
Why they went to land in the first place is still debated. One reason could be that the small juveniles who had completed their
metamorphosis had what it took to make use of what land had to offer. Already adapted to breathe air and move around in shallow waters near land as a protection (just as modern fish (and amphibians) often spent the first part of their life in the comparative safety of shallow waters like
mangrove forests), two very different niches partially overlapped each other, with the young juveniles in the diffuse line between. One of them was overcrowded and dangerous while the other was much safer and much less crowded, offering less competition over resources. The terrestrial niche was also a much more challenging place for primary aquatic animals, but because of the way evolution and the selection pressure works, those juveniles who could take advantage of this would be rewarded. Once they gained a small foothold on land, evolution took care of the rest, thanks to all their preadaptations and being at the right place at the right time.
At this time there were a lot of invertebrates crawling around on land and near water, in moist soil and wet litter, more than big enough to give the small ones a good meal. Some were even big enough to eat small tetrapods, but land would still be a much safer place and offer more than the waters if they knew how to make use of it.
Adults would be too heavy and slow and demand bigger prey. Small juveniles were much lighter, faster and was satisfied with relatively small invertebrates. Modern
mudskippers are said to be able to snap insects in flight while on land, so maybe we shouldn't underestimate the early juvenile tetrapods either.
Initially making only tentative forays onto land, as the generations went by they adapted to terrestrial environments and spent longer periods away from the water, also spending a longer part of their childhood on land before returning to the water for the rest of their life. It is possible also the adults started to spend some time on land as the skeletal modifications in early tetrapods as
Ichthyostega suggests, but only to bask in the sun close to the water's edge, not to hunt or move around. It is a fact that the first true tetrapods adapted to terrestrial locomotion were small. Only later did they increase in size.
The fully grown obviously kept most of the anatomical and other forms of adaptations from their juvenile stage, giving them modified limbs and other traits of terrestrial properties. To be successful adults they first had to be successful juveniles. The adults of some of the smaller species were in that case probably able to move on land too when sufficiently evolved.
If some sort of
neoteny or dwarfism occurred, making the animals sexually mature and fully grown while still living on land, they'd only need to visit water to drink and reproduce.
Carboniferous tetrapods
Until the
1990s, there was a 30 million year gap in the fossil record between the late Devonian tetrapods and the reappearance of tetrapod fossils in recognizable mid-
Carboniferous amphibian lineages. It was referred to as "
Romer's Gap", after the
palaeontologist who recognized it.
During the "gap", tetrapod backbones developed, as did limbs with digits and other adaptations for terrestrial life.
Ears,
skulls and
vertebral columns all underwent changes too. The number of digits on
hands and feet became standardized at five, as lineages with more digits died out. The very few tetrapod fossils found in the "gap" are all the more precious.
The transition from an aquatic lobe-finned fish to an air-breathing amphibian was a momentous occasion in the evolutionary history of the
vertebrates. For an animal to live in a
gravity-neutral, aqueous environment and then invade one that's entirely different required major changes to the overall body plan, both in form and in function.
Eryops is an example of an animal that made such adaptations. It retained and refined most of the traits found in its fish ancestors. Sturdy
limbs supported and transported its body while out of water. A thicker, stronger
backbone prevented its body from sagging under its own weight. Also, by utilizing vestigial fish jaw bones, a rudimentary ear was developed, allowing
Eryops to hear airborne
sound.
By the
Visean age of mid-Carboniferous times the early tetrapods had radiated into at least three main branches. Recognizable basal-group tetrapods are representative of the
temnospondyls (for example
Eryops) and similarly primitive
anthracosaurs, which were the relatives and ancestors of the
Amniota. Depending on whichever authorities one follows,
modern amphibians (frogs,
salamanders and
caecilians) are derived from one or the other (or possibly both, although this is now a minority position) of these two groups. The first amniotes are known from the early part of the
Late Carboniferous, and during the
Triassic counted among their number the earliest
mammals,
turtles, and
crocodiles (
lizards and
birds appeared in the
Jurassic, and
snakes in the
Cretaceous). As living members of the tetrapod clan — that's of the tetrapod "crown-group" — these varied tetrapods represent the
phylogenetic end-points of these two divergent lineages. A third, more primitive,
Carboniferous group, the
baphetids, left no modern survivors. Finally, the
Lepospondyli are an extinct Palaeozoic group of uncertain relationships.
Permian tetrapods
In the
Permian period, as the separate tetrapod lineages each developed in their own way, the term "tetrapoda" becomes less useful. In addition to temnospondyl and anthracosaur clades among the early "amphibia" (labyrinthodonts), there were two important divergent clades of amniotes, the
Sauropsida and the
Synapsida, of which the latter were the most important and successful Permian animals. Each of these lineages, however, remains grouped with the tetrapoda, just as
Homo sapiens could be considered a very highly-specialized kind of
lobe-finned fish.
Living tetrapods
There are three main categories of living ("
crown group") tetrapods, all of which also include many
extinct groups:
Amphibia : frogs and toads, newts and salamanders, and caecilians
;Sauropsida : birds and modern reptiles
Synapsida : mammals
Note that snakes and other legless reptiles are considered tetrapods because they're descended from ancestors who had a full complement of limbs. Similar considerations apply to caecilians and aquatic mammals.
Classification
All early tetrapods and tetrapodomorphs that were not true amphibians or amniotes were once placed together in the
paraphyletic group
Labyrinthodontia. Labyrinthodonts were distinguished mainly by their complex dentine infolding
tooth structure, a feature shared with crossopterygian fish. The labyrinthodonts were divided into the
Ichthyostegalia (another paraphyletic assemblage of primitive tetrapods and kin, such as
Ichthyostega), the
Temnospondyli (possibly members of
Amphibia), and the
Anthracosauria (close relatives of
amniotes). The main difference between the three groups was based on their respective vertebral structures. The Anthracosauria had small pleurocentra, which grew and fused, becoming the true
centrum in later vertebrates. In contrast, the Temnospondyli had a conservative vertebral column in which the pleurocentra remained small in primitive forms, vanishing entirely in the more advanced ones. The intercentra are large and form a complete ring.
Although the temnospondyls flourished in many forms in the Late
Paleozoic and
Triassic, they were an entirely self-contained group and didn't give rise to any later tetrapod groups. It was the sister group
Anthracosauria that gave rise to the reptiles.
Tetrapod groups
A partial taxonomy of the tetrapods:
Phylum Chordata
