Timeline of fish evolution

From WikiProjectMed
Jump to navigation Jump to search

The evolution of fishes took place over a timeline which spans the Cambrian to the Cenozoic, including during that time in particular the Devonian, which has been dubbed the "age of fishes" for the many changes during that period.

The Late Devonian extinctions played a crucial role in shaping the evolution of fish, or vertebrates in general.[1] Fishes evolved during the Early Paleozoic; by the Devonian, all modern groups (Agnatha, Chondrichthyes, and Osteichthyes) were already present. Devonian aquatic environments were also marked by placoderms and acanthodians, which are only known from fossils, however. After suffering large losses during the Late Devonian extinctions, cartilaginous fishes (Chondrichthyes) and the Actinopterygii among the bony fishes (Osteichthyes) diversified.[2]

The sections below describe the pre-Devonian origin of fish, their Devonian radiation, including the conquest of land by early tetrapods, and the post-Devonian evolution of fishes.

Preceded by
the Proterozoic Eon 		Phanerozoic Eon
Paleozoic Era Mesozoic Era Cenozoic Era
Cambrian Ordovician Silurian Devonian Carboniferous Permian Triassic Jurassic Cretaceous Paleogene Neogene 4ry

Pre Devonian: Origin of fish

Cambrian Cambrian (541–485 Ma): The beginning of the Cambrian was marked by the Cambrian explosion, the sudden appearance of nearly all of the invertebrate animal phyla (molluscs, jellyfish, worms and arthropods, such as crustaceans) in great abundance. The first vertebrates appeared in the form of primitive fish, which were subsequently greatly diversified in the Silurian and Devonian.
Pikaia
External videos
video icon Pikaia gracilens animation
The Burgess Shale

Although Pikaia is not actually "first vertebrate" or "first fish", this is still an important organism to show the early forms of chordates. Pikaia is a genus that appeared about 530 Ma during the Cambrian explosion of multicellular life. It is traditionally considered as transitional fossil between invertebrates and vertebrates,[3] and considered as stem-group chordate in 2012.[4][5] It was a primitive creature with no evidence of eyes, without a well defined head, and less than 2 inches (5 centimetres) long. Pikaia was a sideways-flattened, leaf-shaped animal that swam by throwing its body into a series of S-shaped, zig-zag curves, similar to movement of snakes. Fish inherited the same swimming movement, but they generally have stiffer backbones. It had a pair of large head tentacles and a series of short appendages, which may be linked to gill slits, on either side of its head. The flattened body is divided into pairs of segmented muscle blocks, seen as faint vertical lines. The muscles lie on either side of a flexible structure resembling a rod that runs from the tip of the head to the tip of the tail.[6]

Haikouichthys Haikouichthys (fish from Haikou) is a genus that also appears in the fossil record about 530 Ma, and marks the transition from invertebrate to vertebrates.[7] Haikouichthys is craniates (animals with backbones and distinct heads). Unlike Pikaia, they had eyes. They also had a defined skull and other characteristics that have led paleontologists to label it a true craniate, and even to be popularly characterized as one of the earliest fishes. Cladistic analysis indicates that the animal is probably a basal chordate or a basal craniate;[8] but it does not possess sufficient features to be included uncontroversially even in either stem group.[9][7]
Myllokunmingia Myllokunmingia is a genus that appeared about 530 Ma. It is a chordate, and it has been argued that it is a vertebrate,[10] It is 28 mm long and 6 mm high, and is among the oldest possible craniates.
Conodont Conodonts (cone-teeth) resembled primitive eels. They appeared 495 Ma and were wiped out 200 Ma.[11] Initially they were known only from tooth-like microfossils called conodont elements. These "teeth" have been variously interpreted as filter-feeding apparatuses or as a "grasping and crushing array".[12] Conodonts ranged in length from a centimeter to the 40 cm Promissum.[12] Their large eyes had a lateral position of which makes a predatory role unlikely. The preserved musculature hints that some conodonts (Promissum at least) were efficient cruisers but incapable of bursts of speed.[12] In 2012 researchers classify the conodonts in the phylum Chordata on the basis of their fins with fin rays, chevron-shaped muscles and notochord.[13] Some researchers see them as vertebrates similar in appearance to modern hagfish and lampreys,[14] though phylogenetic analysis suggests that they are more derived than either of these groups.[15]
Ostracoderms Ostracoderms (shell-skinned) are any of several groups of extinct, primitive, jawless fishes that were covered in an armour of bony plates. They appeared in the Cambrian, about 510 million years ago, and became extinct towards the end of the Devonian, about 377 million years ago. Initially Ostracoderms had poorly formed fins, and paired fins, or limbs, first evolved within this group. They were covered with a bony armour or scales and were often less than 30 cm (12 in) long.
Ordov-
ician 		Ordovician (485–443 Ma): Fish, the world's first true vertebrates, continued to evolve, and those with jaws (Gnathostomata) may have first appeared late in this period. Life had yet to diversify on land.
Arandaspis Arandaspis are jawless fish that lived in the early Ordovician period, about 480–470 Ma. It was about 15 cm (6 in) long, with a streamlined body covered in rows of knobbly armoured scutes. The front of the body and the head were protected by hard plates with openings for the eyes, nostrils and gills. Although it was jawless, Arandaspis might have had some moveable plates in its mouth, serving as lips, sucking in food particles. The low position of its mouth suggests it foraged the ocean floor.[16] It is not known how its trunk and caudal fin looked like.[17]
Astraspis Astraspis (star shield) is an extinct genus of primitive jawless fish related to other Ordovician fishes, such as Sacabambaspis and Arandaspis. Fossils show clear evidence of a sensory structure (lateral line system). The arrangement of these organs in regular lines allows the fish to detect the direction and distance from which a disturbance in the water is coming. Arandaspis are thought to have had a mobile tail covered with small protective plates and a head region covered with larger plates. A specimen described by Sansom et al. had relatively large, lateral eyes and a series of eight gill openings on each side.[18]
Pteraspidomorphi Pteraspidomorphi is an extinct class of early jawless fish. The fossils show extensive shielding of the head. Many had hypocercal tails to generate lift to increase ease of movement through the water for their armoured bodies, which were covered in dermal bone. They also had sucking mouth parts and some species may have lived in fresh water.
Thelodonts Thelodonts (nipple teeth) are a class of small, extinct jawless fishes with distinctive scales instead of large plates of armour. There is debate over whether these represent a monophyletic grouping, or disparate stem groups to the major lines of jawless and jawed fish.[19] Thelodonts are united by their characteristic "thelodont scales". This defining character is not necessarily a result of shared ancestry, as it may have been evolved independently by different groups. Thus the thelodonts are generally thought to represent a polyphyletic group.[20] If they are monophyletic, there is no firm evidence on what their ancestral state was.[21] These scales were easily dispersed after death; their small size and resilience makes them the most common vertebrate fossil of their time.[22][23] The fish lived in both freshwater and marine environments, first appearing during the Ordovician, and perishing during the Frasnian–Famennian extinction event of the Late Devonian. They were predominantly deposit-feeding bottom dwellers, although some species may have been pelagic.
The Ordovician ended with the Ordovician–Silurian extinction event (450–440 Ma). Two events occurred that killed off 27% of all families, 57% of all genera and 60% to 70% of all species.[24] Together they are ranked by many scientists as the second largest of the five major extinctions in Earth's history in terms of percentage of genera that became extinct.
Silurian Silurian (443–419 Ma): Many evolutionary milestones occurred during this period, including the appearance of armoured jawless fish, jawed fish, spiny sharks and ray-finned fish.
While it is traditional to refer to the Devonian as the age of fishes, recent findings have shown the Silurian was also a period of considerable diversification. Jawed fish developed movable jaws, adapted from the supports of the front two or three gill arches
Anaspida Anaspida (without shield) is an extinct class of primitive jawless vertebrates that lived during the Silurian and Devonian periods.[25] Anaspids were small, primarily marine agnathans that lacked heavy bony shield and paired fins, but have highly exaggerated hypocercal tails. They first appeared in the Early Silurian, and flourished until the Late Devonian extinction,[26] where most species, save for lampreys, became extinct. Unusually for an agnathan, anaspids did not possess a bony shield or armour. The head is instead covered in an array of smaller, weakly mineralised scales.[27]
Osteostraci Osteostraci ("bony shields") was a class of bony-armored jawless fish that lived from the Middle Silurian to Late Devonian. Anatomically speaking, the osteostracans, especially the Devonian species, were among the most advanced of all known agnathans. This is due to the development of paired fins, and their complicated cranial anatomy. The osteostracans were more similar to lampreys than to jawed vertebrates in possessing two pairs of semicircular canals in the inner ear, as opposed to the three pairs found in the inner ears of jawed vertebrates.[28] Most osteostracans had a massive cephalothorac shield, but all Middle and Late Devonian species appear to have had a reduced, thinner, and often micromeric dermal skeleton.[29] They were probably relatively good swimmers, possessing dorsal fins, paired pectoral fins, and a strong tail.[16]
Spiny sharks Spiny sharks, more formally called "Acanthodians" (having spines), constitute the class Acanthodii. They first appeared by the late Silurian ~420 Ma, and were among the first fishes to evolve jaws. They share features with both cartilaginous fish and bony fish, but they are not true sharks, though leading to them. They became extinct before the end of the Permian ~250 Ma. However, scales and teeth attributed to this group, as well as more derived jawed fish, such as cartilaginous and bony fish, date from the Ordovician ~460 Ma. Acanthodians were generally small shark-like fishes varying from toothless filter-feeders to toothed predators. They were once often classified as an order of the class Placodermi, but recent authorities tend to place the acanthodians as a paraphyletic assemblage leading to modern cartilaginous fish. They are distinguished in two respects: they were the earliest known jawed vertebrates, and they had stout spines supporting all their fins, fixed in place and non-movable (like a shark's dorsal fin), an important defensive adaptation. Their fossils are extremely rare.
Placoderms Placoderms, (plate-like skin), are a group of armoured jawed fishes, of the class Placodermi. The oldest fossils appeared during the late Silurian, and became extinct at the end of the Devonian. Recent studies suggest that the placoderms are possibly a paraphyletic group of basal jawed fishes, and the closest relatives of all living jawed vertebrates. Some placoderms were small, flattened bottom-dwellers, such as antiarchs. However many, particularly the arthrodires, were active midwater predators. Dunkleosteus, which appeared later in the Devonian below, was the largest and most famous of these. The upper jaw was firmly fused to the skull, but there was a hinge joint between the skull and the bony plating of the trunk region. This allowed the upper part of the head to be thrown back and, in arthrodires, allowed them to take larger bites.
Megamastax Megamastax, (big mouth), is a genus of lobe-finned fish which lived during the late Silurian period, about 423 million years ago, in China. Before the discovery of Megamastax, it was thought that jawed vertebrates (gnathostomes) were limited in size and variation before the Devonian period. Megamastax is known only from jaw bones and it is estimated that it reached about 1 metre (3 ft 3 in) long.[30]
Guiyu oneiros Guiyu oneiros, the earliest known bony fish. It has the combination of both ray-finned and lobe-finned features, although analysis of the totality of its features place it closer to lobe-finned fish.[31][32][33]
Andreolepis The extinct genus Andreolepis includes the earliest known ray finned fish Andreolepis hedei, which appeared in the late Silurian, around 420 Ma.[34][35]

Devonian: Age of fishes

The Devonian period is broken into the Early, Middle and Late stages. By the start of the Early Devonian 419 mya, jawed fishes had divided into four distinct clades: the placoderms and spiny sharks, both of which are now extinct, and the cartilaginous and bony fishes, both of which are still extant. The modern bony fish, class Osteichthyes, appeared in the late Silurian or early Devonian, about 416 million years ago. Both the cartilaginous and bony fish may have arisen from either the placoderms or the spiny sharks. A subclass of bony fish, the ray-finned fishes (Actinopterygii), have become the dominant group in the post-Paleozoic and modern world, with some 30,000 living species. Meanwhile, another subclass of bony fish, the lobe-finned fishes, became the dominant group on land.

Sea levels in the Devonian were generally high. Marine faunas were dominated by bryozoa, diverse and abundant brachiopods, the enigmatic hederelloids, microconchids and corals. Lily-like crinoids were abundant, and trilobites were still fairly common. Among vertebrates, jawless armoured fish (ostracoderms) declined in diversity, while the jawed fish (gnathostomes) simultaneously increased in both the sea and fresh water. Armoured placoderms were numerous during the lower stages of the Devonian Period but became extinct in the Late Devonian, perhaps because of competition for food against the other fish species. Early cartilaginous (Chondrichthyes) and bony fish (Osteichthyes) also become diverse and played a large role within the Devonian seas. The first abundant genus of shark, Cladoselache, appeared in the oceans during the Devonian Period. The great diversity of fish around at the time have led to the Devonian being given the name "The Age of Fish" in popular culture.

The first ray-finned and lobe-finned bony fish appeared in the Devonian, while the placoderms began dominating almost every known aquatic environment. However, another subclass of Osteichthyes, the Sarcopterygii( which includes lobe-finned fish like coelacanths and lungfish, as well as and tetrapods), was the most diverse group of bony fish in the Devonian. Sarcopterygians are basally characterized by internal nostrils, lobe fins containing a robust internal skeleton, and cosmoid scales.

During the Middle Devonian 393–383 Ma, the armoured jawless ostracoderm fish were declining in diversity; the jawed fish were thriving and increasing in diversity in both the oceans and freshwater. The shallow, warm, oxygen-depleted waters of Devonian inland lakes, surrounded by primitive plants, provided the environment necessary for certain early fish to develop essential characteristics such as well developed lungs and the ability to crawl out of the water and onto the land for short periods of time. Cartilaginous fish, class Chondrichthyes, consisting of sharks, rays and chimaeras, appeared by about 395 million years ago, in the middle Devonian

During the Late Devonian the first forests were taking shape on land. The first tetrapods appeared in the fossil record over a period, the beginning and end of which are marked with extinction events. This lasted until the end of the Devonian 359 mya. The ancestors of all tetrapods began adapting to walking on land, their strong pectoral and pelvic fins gradually evolved into legs (see Tiktaalik).[38] In the oceans, primitive sharks became more numerous than in the Silurian and the late Ordovician. The first ammonite mollusks appeared. Trilobites, the mollusk-like brachiopods and the great coral reefs, were still common.

The Late Devonian extinction occurred at the beginning of the last phase of the Devonian period, the Famennian faunal stage, (the Frasnian-Famennian boundary), about 372.2 Ma. Many fossil agnathan fish, save for the psammosteid heterostracans, make their last appearance shortly before this event. The Late Devonian extinction crisis primarily affected the marine community, and selectively affected shallow warm-water organisms rather than cool-water organisms. The most important group affected by this extinction event were the reef-builders of the great Devonian reef-systems.

A second extinction pulse, the Hangenberg event closed the Devonian period and had a dramatic impact on vertebrate faunas. Placoderms mostly became extinct during this event, as did most members of other groups including lobe-finned fish, acanthodians and early tetrapods in both marine and terrestrial habitats, leaving only a handful of survivors. This event has been related to glaciation in the temperate and polar zones as well as euxinia and anoxia in the seas.

Devonian (419–359 mya): The start of Devonian saw the first appearance of lobe-finned fish, precursors to the tetrapods (animals with four limbs). Major groups of fish evolved during this period, often referred to as the age of fish.[39] See Category:Devonian fish.
D
e
v
o
n
i
a
n 		Early
Devonian 		Early Devonian (419–393 Ma):
Psarolepis Psarolepis (speckled scale) is a genus of extinct lobe-finned fish that lived around 397 to 418 Ma. Fossils of Psarolepis have been found mainly in South China and described by paleontologist Xiaobo Yu in 1998. It is not known for certain which group Psarolepis belongs to, but paleontologists agree that it is close to the common ancestor of lobe-finned and ray-finned fishes.[40]
Holoptychius Holoptychius is an extinct genus from the order of porolepiform lobe-finned fish, extant from 416 to 359 Ma. It was a streamlined predator about 50 centimetres (20 in) long (though it could grow up to 2.5 m), which fed on other bony fish. Its rounded scales and body form indicate that it could have swum quickly through the water to catch prey.[41][42] Similar to other rhipidistians, it had fang-like teeth on its palate in addition to smaller teeth on the jaws. Its asymmetrical tail sported a caudal fin on its lower end. To compensate for the downward push caused by this fin placement, Holoptychius's pectoral fins were placed high on the body.
Ptyctodontida The ptyctodontids (beak-teeth) are an extinct monotypic order of unarmored placoderms, containing only one family. They were extant from the start to the end of the Devonian. With their big heads, big eyes, and long bodies, the ptyctodontids bore a strong resemblance to modern day chimaeras (Holocephali). Their armor was reduced to a pattern of small plates around the head and neck. Like the extinct and related acanthothoracids, and the living and unrelated holocephalians, most of the ptyctodontids are thought to have lived near the sea bottom and preyed on shellfish.
Petalichthyida The Petalichthyida was an order of small, flattened placoderms that existed from the beginning of the Devonian to the Late Devonian. They were typified by splayed fins and numerous tubercles that decorated all of the plates and scales of their armour. They reached a peak in diversity during the Early Devonian and were found throughout the world. Because they had compressed body forms, it is supposed they were bottom-dwellers that chased after or ambushed smaller fish. Their diet is not clear, as none of the fossil specimens found have preserved mouth parts.
Laccognathus Laccognathus (pitted jaw) was a genus of amphibious lobe-finned fish that existed 398–360 Ma.[43] They were characterized by the three large pits (fossae) on the external surface of the lower jaw, which may have had sensory functions.[44] Laccognathus grew to 1–2 metres (3–7 ft) in length. They had very short dorsoventrally flattened heads, less than one-fifth the length of the body.[45] The skeleton was structured so large areas of skin were stretched over solid plates of bone. This bone was composed of particularly dense fibers – so dense that exchange of oxygen through the skin was unlikely. Rather, the dense ossifications served to retain water inside the body as Laccognathus traveled on land between bodies of water.[46]
Middle
Devonian 		Middle Devonian (393–383 Ma): Cartilaginous fish, consisting of sharks, rays and chimaeras, appeared about 395 Ma.
Cheirolepis Cheirolepis (hand fin) was a genus of ray-finned fishes. It was among the most basal of the Devonian ray-finned fish and is considered the first to possess the "standard" dermal cranial bones seen in later ray-finned fish. It was a predatory freshwater fish about 55 centimetres (22 in) long, and based on the size of its eyes it hunted by sight.[16]
Coccosteus Coccosteus (seed bone) is an extinct genus of arthrodire placoderm. The majority of fossils have been found in freshwater sediments, though they may have been able to enter saltwater. They grew up to 40 centimetres (16 in) long. Like all other arthrodires, Coccosteus had a joint between the armour of the body and skull. It also had an internal joint between its neck vertebrae and the back of the skull, allowing it to open its mouth even wider. Along with the longer jaws, this allowed Coccosteus to feed on fairly large prey. As with all other arthrodires, Coccosteus had bony dental plates embedded in its jaws, forming a beak. The beak was kept sharp by having the edges of the dental plates grind away at each other.[47]
Bothriolepis
External videos
video icon BothriolepisAnimal Planet

Bothriolepis (pitted scale) was the most successful genus of antiarch placoderms, if not the most successful genus of any placoderm, with over 100 species spread across Middle to Late Devonian strata across every continent.

Pituriaspida Pituriaspida (hallucinogenic shield) is a class containing two bizarre species of armoured jawless fish with tremendous nose-like rostrums. They lived in estuaries around 390 Ma. The paleontologist Gavin Young, named the class after the hallucinogenic drug pituri, since he thought he might be hallucinating upon viewing the bizarre forms.[48] The better studied species looked like a throwing-dart-like, with an elongate headshield and spear-like rostrum. The other species looked like a guitar pick with a tail, with a smaller and shorter rostrum and a more triangular headshield.
Late Devonian extinction: 375–360 Ma. A prolonged series of extinctions eliminated about 19% of all families, 50% of all genera[24] and 70% of all species. This extinction event lasted perhaps as long as 20 Ma, and there is evidence for a series of extinction pulses within this period.
Late
Devonian 		Late Devonian (383–359 Ma):
Cladoselache Cladoselache was the first abundant genus of early chondrichthyan, related to modern sharks (though probably closer to holocephalans like chimaeras[49]), appearing about 370 Ma.[50] It grew to 6 feet (1.8 m) long, with anatomical features similar to modern mackerel sharks. It had a streamlined body almost entirely devoid of scales, with five to seven gill slits and a short, rounded snout that had a terminal mouth opening at the front of the skull.[50] It had a very weak jaw joint compared with modern-day sharks, but it compensated for that with very strong jaw-closing muscles. Its teeth were multi-cusped and smooth-edged, making them suitable for grasping, but not tearing or chewing. Cladoselache therefore probably seized prey by the tail and swallowed it whole.[50] It had powerful keels that extended onto the side of the tail stalk and a semi-lunate tail fin, with the superior lobe about the same size as the inferior. This combination helped with its speed and agility, which was useful when trying to outswim its probable predator, the heavily armoured 8.8 metres (29 ft) long placoderm fish Dunkleosteus.[51]
Dipterus Dipterus (two wings) is an extinct genus of lungfish from 376 to 361 Ma. It was about 35 centimetres (14 in) long, mostly ate invertebrates, and had lungs, not an air bladder. Like its ancestor Dipnorhynchus it had tooth-like plates on its palate instead of real teeth. However, unlike its modern relatives, in which the dorsal, caudal, and anal fin are fused into one, its fins were still separated. Otherwise Dipterus closely resembled modern lungfish.[52]
Dunkleosteus
External videos
video icon DunkleosteusAnimal Planet

Dunkleosteus is a genus of arthrodire placoderms that existed from 380 to 360 Ma. It grew up to 8.8 metres (29 ft) long[51] and weighed up to 3.6 tonnes.[53] It was a hypercarnivorous apex predator. Apart from its contemporary Titanichthys (below), no other placoderm rivalled it in size. Instead of teeth, Dunkleosteus had two pairs of sharp bony plates, which formed a beak-like structure. Apart from megalodon, it had the most powerful bite of any fish,[54] generating bite forces in the same league as Tyrannosaurus rex and the modern crocodile.[55]

Titanichthys Titanichthys is a genus of giant, aberrant marine placoderm that lived in shallow seas. Many of the species approached Dunkleosteus in size and build. Unlike its relative, however, the various species of Titanichys had small, ineffective-looking mouth-plates that lacked a sharp cutting edge. It is assumed that Titanichthys was a filter feeder that used its capacious mouth to swallow or inhale schools of small, anchovy-like fish, or possibly krill-like zooplankton, and that the mouth-plates retained the prey while allowing the water to escape as it closed its mouth.
Materpiscis
External videos
video icon The mother fishNature

Materpiscis (mother fish) is a genus of ptyctodontid placoderm from about 380 Ma. Known from only one specimen, it is unique in having an unborn embryo present inside, and with remarkable preservation of a mineralised placental feeding structure (umbilical cord). This makes Materpiscis the first known vertebrate to show viviparity, or giving birth to live young.[56] The specimen was named Materpiscis attenboroughi in honour of David Attenborough.[57]

Hyneria Hyneria is a genus of predatory lobe-finned fish, about 2.5 m (8.2 ft) long, that lived 360 million years ago.[58]
Rhizodonts Rhizodonts were an order of lobe-finned fish that survived to the end of the Carboniferous, 377–310 Ma. They reached huge sizes. The largest known species, Rhizodus hibberti grew up to 7 metres in length, making it the largest freshwater fish known.

Fish to tetrapods

Further information: Tetrapod § Evolution, and List of transitional fossils § Fish to Tetrapods
A cladogram of the evolution of tetrapods showing some of the best-known transitional fossils. It starts with Eusthenopteron at the bottom, indisputably still a fish, through Panderichthys, Tiktaalik, Acanthostega and Ichthyostega to Pederpes at the top, indisputably a tetrapod

The first tetrapods are four-legged, air-breathing, terrestrial animals from which the land vertebrates descended, including humans. They evolved from lobe-finned fish of the clade Sarcopterygii, appearing in coastal water in the middle Devonian, and giving rise to the first amphibians.[59]

The group of lobe-finned fishes that were the ancestors of the tetrapod are grouped together as the Rhipidistia,[60] and the first tetrapods evolved from these fish over the relatively short timespan 385–360 Ma. The early tetrapod groups themselves are grouped as Labyrinthodontia. They retained aquatic, fry-like tadpoles, a system still seen in modern amphibians. From the 1950s to the early 1980s it was thought that tetrapods evolved from fish that had already acquired the ability to crawl on land, possibly so they could go from a pool that was drying out to one that was deeper. However, in 1987, nearly complete fossils of Acanthostega from about 363 Ma showed that this Late Devonian transitional animal had legs and both lungs and gills, but could never have survived on land: its limbs and its wrist and ankle joints were too weak to bear its weight; its ribs were too short to prevent its lungs from being squeezed flat by its weight; its fish-like tail fin would have been damaged by dragging on the ground. The current hypothesis is that Acanthostega, which was about 1 metre (3.3 ft) long, was a wholly aquatic predator that hunted in shallow water. Its skeleton differed from that of most fish, in ways that enabled it to raise its head to breathe air while its body remained submerged, including: its jaws show modifications that would have enabled it to gulp air; the bones at the back of its skull are locked together, providing strong attachment points for muscles that raised its head; the head is not joined to the shoulder girdle and it has a distinct neck.[61]

Until the 1980s early transitional lobe-finned fishes, such as the Eusthenopteron shown here, were depicted as emerging onto land. Paleontologists now widely agree this did not happen, and they were strictly aquatic.[62]
External videos
video icon Tetrapod Evolution Animal Planet
1 2 3 4 5
video icon Evolution fish with fingers Transitional fossilsYouTube

The Devonian proliferation of land plants may help to explain why air-breathing would have been an advantage: leaves falling into streams and rivers would have encouraged the growth of aquatic vegetation; this would have attracted grazing invertebrates and small fish that preyed on them; they would have been attractive prey but the environment was unsuitable for the big marine predatory fish; air-breathing would have been necessary because these waters would have been short of oxygen, since warm water holds less dissolved oxygen than cooler marine water and since the decomposition of vegetation would have used some of the oxygen.[61]

There are three major hypotheses as to how tetrapods evolved their stubby fins (proto-limbs). The traditional explanation is the "shrinking waterhole hypothesis" or "desert hypothesis" posited by the American paleontologist Alfred Romer. He believed limbs and lungs may have evolved from the necessity of having to find new bodies of water as old waterholes dried up.[63]

The second hypothesis is the "inter-tidal hypothesis" put forward in 2010 by a team of Polish paleontologists led by Grzegorz Niedźwiedzki. They argued that sarcopterygians may have first emerged unto land from intertidal zones rather than inland bodies of water. Their hypothesis is based on the discovery of the 395 million-year-old Zachełmie tracks in Zachełmie, Poland, the oldest ever discovered fossil evidence of tetrapods.[59][64]

The third hypothesis, the "woodland hypothesis", was proposed by the American paleontologist Gregory J. Retallack in 2011. He argues that limbs may have developed in shallow bodies of water in woodlands as a means of navigating in environments filled with roots and vegetation. He based his conclusions on the evidence that transitional tetrapod fossils are consistently found in habitats that were formerly humid and wooded floodplains.[65]

Research by Jennifer A. Clack and her colleagues showed that the very earliest tetrapods, animals similar to Acanthostega, were wholly aquatic and quite unsuited to life on land. This is in contrast to 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.

Two ideas about the homology of arms, hands and digits have existed in the past 130 years. First that digits are unique to tetrapods[66][67] and second that antecedents were present in the fins of early sarcopterygian fish.[68] Until recently it was believed that "genetic and fossil data support the hypothesis that digits are evolutionary novelties".[69]p. 640. However new research that created a three-dimensional reconstruction of Panderichthys, a coastal fish from the Devonian period 385 million years ago, shows that these animals already had many of the homologous bones present in the forelimbs of limbed vertebrates.[70] For example, they had radial bones similar to rudimentary fingers but positioned in the arm-like base of their fins.[70] Thus there was in the evolution of tetrapods a shift such that the outermost part of the fins were lost and eventually replaced by early digits. This change is consistent with additional evidence from the study of actinopterygians, sharks and lungfish that the digits of tetrapods arose from pre-existing distal radials present in more primitive fish.[70][71] Controversy still exists since Tiktaalik, a vertebrate often considered the missing link between fishes and land-living animals, had stubby leg-like limbs that lacked the finger-like radial bones found in the Panderichthys. The researchers of the paper commented that it "is difficult to say whether this character distribution implies that Tiktaalik is autapomorphic, that Panderichthys and tetrapods are convergent, or that Panderichthys is closer to tetrapods than Tiktaalik. At any rate, it demonstrates that the fish–tetrapod transition was accompanied by significant character incongruence in functionally important structures.".[70]p. 638.

From the end of the Devonian to the Mid Carboniferous a 30 million year gap occurs in the fossil record. This gap, called Romer's gap, is marked by the absence of ancestral tetrapod fossils and fossils of other vertebrates that look well-adapted for life on land.[72]

Transition from lobe-finned fishes to tetrapods
~385 Ma Eusthenopteron
External videos
video icon EusthenopteronAnimal Planet

Genus of extinct lobe-finned fishes that has attained an iconic status from its close relationships to tetrapods. Early depictions of this animal show it emerging onto land, however paleontologists now widely agree that it was a strictly aquatic animal.[62] The genus Eusthenopteron is known from several species that lived during the Late Devonian period, about 385 Ma. It was the object of intense study from the 1940s to the 1990s by the paleoichthyologist Erik Jarvik.[73]

Gogonasus Gogonasus (snout from Gogo) was a lobe-finned fish known from 3-dimensionally preserved 380 million-year-old fossils found in the Gogo Formation. It was a small fish reaching 30–40 cm (12–16 in) in length. Its skeleton shows several tetrapod-like features. They included the structure of its middle ear, and its fins show the precursors of the forearm bones, the radius and ulna. Researchers believe it used its forearm-like fins to dart out of the reef to catch prey. Gogonasus was first described in 1985 by John A. Long. For almost 100 years Eusthenopteron has been the role model for demonstrating stages in the evolution of lobe-finned fishes to tetrapods. Gogonasus now replaces Eusthenopteron in being a better preserved representative without any ambiguity in interpreting its anatomy.

~385 Ma 		Panderichthys Adapted to muddy shallows, and capable of some kind of shallow water or terrestrial body flexion locomotion. Had the ability to prop itself up.[74]
They had large tetrapod-like heads, and are thought to be the most crownward stem fish-tetrapod with paired fins.

~375 Ma 		Tiktaalik A fish with limb-like fins that could take it onto land.[75] It is an example from several lines of ancient sarcopterygian fish developing adaptations to the oxygen-poor shallow-water habitats of its time, which led to the evolution of tetrapods.[61] Paleontologists suggest that it is representative of the transition between non-tetrapod vertebrates (fish) such as Panderichthys, known from fossils 380 million years old, and early tetrapods such as Acanthostega and Ichthyostega, known from fossils about 365 million years old. Its mixture of primitive fish and derived tetrapod characteristics led one of its discoverers, Neil Shubin, to characterize Tiktaalik as a "fishapod".[76][77]

365 Ma 		Acanthostega A fish-like early labyrinthodont that occupied swamps and changed views about the early evolution of tetrapods.[61] It had eight digits on each hand (the number of digits on the feet is unclear) linked by webbing, it lacked wrists, and was generally poorly adapted to come onto land.[78] Subsequent discoveries revealed earlier transitional forms between Acanthostega and completely fish-like animals.[79]

374–359 Ma 		Ichthyostega
External videos
video icon IchthyostegaAnimal Planet
video icon Pierce et al. Vertebral Architecture
1 2 3 4 5YouTube

Until finds of other early tetrapods and closely related fishes in the late 20th century, Ichthyostega stood alone as the transitional fossil between fish and tetrapods, combining a fishlike tail and gills with an amphibian skull and limbs. It possessed lungs and limbs with seven digits that helped it navigate through shallow water in swamps.


359–345 Ma 		Pederpes Pederpes is the earliest known fully terrestrial tetrapod. It is included here to complete the transition of lobe-finned fishes to tetrapods, even though Pederpes is no longer a fish.

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. 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 is 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 could not have lived in freshwater only.

Post Devonian

  • During the Carboniferous period, fish diversity seemingly declined and reached low levels during the Permian period.[2]
  • The Mesozoic Era began about 252 million years ago in the wake of the Permian-Triassic event, the largest mass extinction in Earth's history, and ended about 66 million years ago with the Cretaceous–Paleogene extinction event, another mass extinction that killed off non-avian dinosaurs, as well as other plant and animal species. It is often referred to as the Age of Reptiles because reptiles were the dominant vertebrates of the time. The Mesozoic witnessed the gradual rifting of the supercontinent Pangaea into separate landmasses. The climate alternated between warming and cooling periods; overall the Earth was hotter than it is today. Bony fishes remained largely unaffected by the Permian-Triassic extinction event.[80]
  • The Mesozoic saw the diversification of neopterygian fishes, the clade that consists of holostean and teleost fishes. Most of them were small in size.[80] The diversity of body shape variety in Triassic, Jurassic, and Early Cretaceous neopterygian fishes has been documented,[81] revealing that the accumulation of novel body shapes in teleost fishes was predominantly gradual throughout this 150 million year period (250Mya - 100Mya). Holostean fishes appear to accumulate body shape variety (so called disparity) between the early Triassic and Toarcian, after which the amount of variety seen among their body shapes remained stable until the end of the Early Cretaceous.[81]
Carbon-
iferous 		Carboniferous (359–299 Ma): Sharks underwent a major evolutionary radiation during the Carboniferous.[82] It is believed that this evolutionary radiation occurred because the decline of the placoderms at the end of the Devonian period caused many environmental niches to become unoccupied and allowed new organisms to evolve and fill these niches.[82]
Coastal seas during the Carboniferous: The first 15 million years of the Carboniferous has very few terrestrial fossils. This gap in the fossil record, is called Romer's gap after the American palaentologist Alfred Romer. While it has long been debated whether the gap is a result of fossilisation or relates to an actual event, recent work indicates the gap period saw a drop in atmospheric oxygen levels, indicating some sort of ecological collapse.[83] The gap saw the demise of the Devonian fish-like ichthyostegalian labyrinthodonts, and the rise of the more advanced temnospondyl and reptiliomorphan amphibians that so typify the Carboniferous terrestrial vertebrate fauna.

The Carboniferous seas were inhabited by many fish, mainly Elasmobranchs (sharks and their relatives). These included some, like Psammodus, with crushing pavement-like teeth adapted for grinding the shells of brachiopods, crustaceans, and other marine organisms. Other sharks had piercing teeth, such as the Symmoriida; some, the petalodonts, had peculiar cycloid cutting teeth. Most of the sharks were marine, but the Xenacanthida invaded fresh waters of the coal swamps. Among the bony fish, the Palaeonisciformes found in coastal waters also appear to have migrated to rivers. Sarcopterygian fish were also prominent, and one group, the Rhizodonts, reached very large size.

Most species of Carboniferous marine fish have been described largely from teeth, fin spines and dermal ossicles, with smaller freshwater fish preserved whole. Freshwater fish were abundant, and include the genera Ctenodus, Uronemus, Acanthodes, Cheirodus, and Gyracanthus.
Stethacanthus

As a result of the evolutionary radiation, carboniferous cartilaginous fishes assumed a wide variety of bizarre shapes—including cartilaginous fishes (holocephalian, relative of modern ratfishes[84]) of the family Stethacanthidae, which possessed a flat brush-like dorsal fin with a patch of denticles on its top.[82] Stethacanthus's unusual fin may have been used in mating rituals.[82] Apart from the fins, Stethacanthidae resembled Falcatus (below).

Falcatus Falcatus is a genus of small cladodont-toothed cartilaginous fishes that lived 335–318 Ma. They were about 25–30 cm (10–12 in) long.[85] They are characterised by the prominent fin spines that curved anteriorly over their heads.
Belantsea Belantsea is a representative of the Carboniferous to Permian order Petalodontiformes. Petalodontiforms are characterized by their peculiar teeth. The group became extinct in the late Permian (Wuchiapingian). One of the last survivors was Janassa, which superficially looked like modern rays, though it is not closely related with them.
Orodus Orodus is another cartilaginous fish of the Carboniferous, a genus from the family Orodontidae that lived into the early Permian from 303 to 295 Ma. It grew to 2 m (6.5 ft) in length.
Chondrenchelys Chondrenchelys is an extinct genus of cartilaginous fish from the Carboniferous period. It had an elongate, eel-like body. Chondrenchelys is a holocephalan and a distant relative of modern ratfishes.[86]
Edestus
Tooth whorl

Edestus is a genus of the extinct eugeneodontid order, a group of cartilaginous fishes that is related with modern chimerids (ratfishes). Other Carboniferous genera aare Bobbodus, Campodus, and Ornithoprion. Eugeneodontids were common during the Carboniferous period. Members of this order typically had tooth whorls, mostly formed by their lower jaws. In Edestus, both the upper and lower jaws formed a tooth whorl. Some species of Edestus could reach body lengths of 6.7 m (22 ft).

Permian Permian (298–252 Ma):
Helicoprion
Tooth whorl

Helicoprion is arguably the most iconic genus of the extinct Eugeneodontida. This order of cartilaginous fishes is related with extant chimerids (ratfishes). Eugeneodontids disappeared during the Permian period, with only a few genera surviving into the earliest Triassic (Caseodus, Fadenia). Typically, members of this group had tooth whorls. Species of Helicoprion could reach between 5 and 8 m (16.5 and 26 ft) in size.

Triodus Triodus is a genus of xenacanthid cartilaginous fish. The order Xenacanthida existed during the Carboniferous to Triassic period, and is well known from many complete skeletons from the early Permian. They typically had a prominent dorsal fin spine, which in some species was attached to the back of their skull, while in others it was located more posteriorly. Xenacanthids were ferocious freshwater predators.
Acanthodes Acanthodes is an extinct genus of spiny shark (Acanthodii).[87] It had gills but no teeth,[88] and was presumably a filter feeder.[16] Acanthodes had only two skull bones and were covered in cubical scales. Each paired pectoral and pelvic fins had one spine, as did the single anal and dorsal fins, giving it a total of six spines, less than half that of many other spiny sharks.[16] Acanthodians share qualities of both bony fish (osteichthyes) and cartilaginous fish (chondrichthyes), and it has been suggested that they may have been stem chondrichthyans and stem gnathostomes.[89][90] Spiny sharks became extinct in the Permian.
Palatinichthys Megalichthyids are an extinct family of lobe-finned fish. They are tetrapodomorphs, a group of lobe-finned fish that is closely related with land-living vertebrates. Megalichthyids survived into the Permian, but became extinct during this period. Palatinichthys from the early Permian of Germany was one of the last survivors of this clade.[80]
Acrolepis Acrolepis is a genus of palaeoniscoid ray-finned fish that existed during the Carboniferous to Triassic period. It had elongate jaws and its eyes were located in the front of the skull. Acrolepis had a heterocercal tail fin and fusiform body. The body was covered in thick ganoid scales. This morphology is typical for many late Palaeozoic ray-fins.
The Permian ended with the most extensive extinction event recorded in paleontology: the Permian-Triassic extinction event. 90% to 95% of marine species became extinct, as well as 70% of all land organisms. It is also the only known mass extinction of insects.[91][92] Recovery from the Permian-Triassic extinction event was protracted; land ecosystems took 30M years to recover,[93] and marine ecosystems took even longer.[24] However, bony fishes were mostly not affected by this extinction event.[80][94]
Triassic Triassic (252–201 Ma): The fish fauna of the Early Triassic was remarkably uniform, reflecting the fact that the surviving families dispersed globally after the Permian-Triassic extinction.[80] A considerable radiation of ray-finned fishes occurred during the Triassic, laying the foundation for many modern fishes.[95] See Category:Triassic fish.
Foreyia
Ticinepomis

The Middle Triassic Foreyia, along with Ticinepomis, is one of the earliest known members of the family Latimeriidae, which also includes the extant coelacanth Latimeria. Foreyia had an atypical body shape for a coelacanth, a group that is otherwise known for their conservative morphology. Rebellatrix is another Triassic coelacanth with an aberrant morphology. This genus is characterized by a forked caudal fin, suggesting that Rebellatrix was a fast swimmer. Coelacanths had one of their highest post-Devonian diversity during the Early Triassic.[96]

Saurichthys
Gravid female

Saurichthyiformes are an extinct clade of ray-finned fish that evolved shortly before the Permian-Triassic extinction, and that rapidly diversified after the event. The Triassic genus Saurichthys comprises over 50 species, some reaching up to 1.5 metres (4.9 ft) in length. Some Middle Triassic species show evidence for viviparity in the form of embryos that are preserved in females, and gonopodia in males. This is the earliest case of a viviparous ray-finned fish.[97] Saurichthys was also the first ray-fin to show adaptations for ambush predation.[98]

Perleidus
Colobodus jaws

Perleidus was a ray-finned fish from the Middle Triassic. About 15 centimetres (6 in) in length, it was a marine predatory fish with jaws that hung vertically under the braincase, allowing them to open wide.[16] The Triassic Perleidiformes were very diverse in shape and showed distinct feeding specializations in their teeth. Colobodus, for example, had strong, button-like teeth. Some perleidiforms, such as Thoracopterus, were the first ray-fins to glide over water, much like extant flying fish, with which they are only distantly related.

Robustichthys Robustichthys is a Middle Triassic ionoscopiform ray-finned fish. They belong to the clade Halecomorphi, which were once diverse during the Mesozoic Era, but which are today represented by only a single species, the bowfin. Halecomorphs are holosteans, a clade which first appeared in the fossil record during the Triassic.[99]
Semionotus
Thick scales

Semionotiformes are an extinct order of holostean ray-finned fish that existed from during the Mesozoic Era. They were characterized by thick scales and specialized jaws. They are relatives of modern gars, both belonging to the clade Ginglymodi. This clade first appears in the fossil record during the Triassic. Once diverse, they are only represented by a few species today.[99]

Pholidophorus Pholidophorus was an extinct genus of teleost, around 40 centimetres (16 in) long, from about 240–140 Ma. Although not closely related to the modern herring, it was somewhat like herring in appearance and niche. It had a single dorsal fin, a symmetrical tail, and an anal fin placed towards the rear of the body. It had large eyes and was probably a fast swimming predator, hunting planktonic crustaceans and smaller fish.[100] A very early teleost/teleosteomorph, Pholidophorus had many primitive characteristics such as ganoid scales and a spine that was partially composed of cartilage, rather than bone.[100] Teleosts first appeared in the fossil record during the Triassic. One of the earliest members is Prohalecites (Ladinian).
The Triassic ended with the Triassic–Jurassic extinction event. About 23% of all families, 48% of all genera (20% of marine families and 55% of marine genera) and 70% to 75% of all species became extinct.[101] Ray-finned fishes, however, remained largely unaffected by this extinction event.[94] Non-dinosaurian archosaurs continued to dominate aquatic environments, while non-archosaurian diapsids continued to dominate marine environments.[101]
Jurassic Jurassic (201–145 Ma): During the Jurassic period, the primary vertebrates living in the seas were fish and marine reptiles. The latter include ichthyosaurs who were at the peak of their diversity, plesiosaurs, pliosaurs, and marine crocodiles of the families Teleosauridae and Metriorhynchidae.[102] Numerous turtles could be found in lakes and rivers.[103][104] See Category:Jurassic fish.
Pachycormiformes
Hypsocormus

Pachycormiformes are an extinct order of ray-finned fish that existed from the Early Jurassic to the K-Pg extinction (below). They were characterized by serrated pectoral fins, reduced pelvic fins and a bony rostrum. Their relations with other fish are unclear.

Leedsichthys Along with its close pachycormid relatives Bonnerichthys and Rhinconichthys, Leedsichthys is part of a lineage of large-sized filter-feeders that swam the Mesozoic seas for over 100 million years, from the middle Jurassic until the end of the Cretaceous period. Pachycormids might represent an early branch of Teleostei, the group most modern bony fishes belong to; in that case Leedsichthys is the largest known teleost fish.[105] In 2003, a fossil specimen 22 meters (72 feet) long was unearthed.[106]
Ichthyodectiformes
This fossil Ichthyodectiform from the Lower Jurassic is one of the best conserved fossil fishes worldwide

The order Ichthyodectiformes (literally "fish-biters") was a family of marine actinopterygian fish. They first appeared 156 Ma during the Late Jurassic and disappeared during the K-Pg extinction event 66 Ma. They were most diverse throughout the Cretaceous period. Most ichthyodectids ranged between 1 and 5 meters (3.5 and 16.5 ft) in length. All known taxa were predators, feeding on smaller fish; in several cases, larger Ichthyodectidae preyed on smaller members of the family. Some species had remarkably large teeth, though others, such as Gillicus arcuatus, had small ones and sucked in their prey. The largest Xiphactinus was 20 feet long, and appeared in the Late Cretaceous (below).

Cret-
aceous 		Cretaceous (145–66 Ma): See Category:Cretaceous fish.
Sturgeon True sturgeons appear in the fossil record during the Upper Cretaceous. Since that time, sturgeons have undergone remarkably little morphological change, indicating their evolution has been exceptionally slow and earning them informal status as living fossils.[107][108] This is explained in part by the long generation interval, tolerance for wide ranges of temperature and salinity, lack of predators due to size, and the abundance of prey items in the benthic environment.
Cretoxyrhina

Cretoxyrhina mantelli was a large shark that lived about 100 to 82 million years ago, during the mid Cretaceous period. It is commonly known as the Ginsu Shark. This shark was first identified by a famous Swiss Naturalist, Louis Agassiz in 1843, as Cretoxyhrina mantelli. However, the most complete specimen of this shark was discovered in 1890, by the fossil hunter Charles H. Sternberg, who published his findings in 1907. The specimen consisted of a nearly complete associated vertebral column and over 250 associated teeth. This kind of exceptional preservation of fossil sharks is rare because a shark's skeleton is made of cartilage, which is not prone to fossilization. Charles dubbed the specimen Oxyrhina mantelli. This specimen represented a 20-foot-long (6.1 m) shark.

Enchodus

Enchodus is an extinct genus of bony fish. It flourished during the Upper Cretaceous and was small to medium in size. One of the genus' most notable attributes are the large "fangs" at the front of the upper and lower jaws and on the palatine bones, leading to its misleading nickname among fossil hunters and paleoichthyologists, "the saber-toothed herring". These fangs, along with a long sleek body and large eyes, suggest Enchodus was a predatory species.

Xiphactinus
External videos
video icon XiphactinusYouTube

Xiphactinus is an extinct genus of large predatory marine bony fish of the Late Cretaceous. They grew more than 4.5 metres (15 feet) long.[109]

Ptychodus Ptychodus is a genus of extinct shark (previously considered as hybodontiformes but later denied[110]) that lived from the late Cretaceous to the Paleogene.[111][112] Ptychodus mortoni (pictured) was about 32 feet (9.8 metres) long and was unearthed in Kansas, United States.[113]
The end of the Cretaceous was marked by the Cretaceous–Paleogene extinction event (K-Pg extinction). There are substantial fossil records of jawed fishes across the K–T boundary, which provides good evidence of extinction patterns of these classes of marine vertebrates. Within cartilaginous fish, approximately 80% of the sharks, rays, and skates families survived the extinction event,[114] and more than 90% of teleost fish (bony fish) families survived.[115] There is evidence of a mass kill of bony fishes at a fossil site immediately above the K–T boundary layer on Seymour Island near Antarctica, apparently precipitated by the K–Pg extinction event.[116] However, the marine and freshwater environments of fishes mitigated environmental effects of the extinction event,[117] and evidence shows that there was a major increase in size and abundance of teleosts immediately after the extinction, apparently due to the elimination of their ammonite competitors (there was no similar change in shark populations across the boundary).[118]
Cenozoic
Era 		Cenozoic Era (66 Ma to present): The current era has seen great diversification of bony fishes. Over half of all living vertebrate species (about 32,000 species) are fishes (non-tetrapod craniates), a diverse set of lineages that inhabit all the world's aquatic ecosystems, from snow minnows (Cypriniformes) in Himalayan lakes at elevations over 4,600 metres (15,100 feet) to flatfishes (order Pleuronectiformes) in the Challenger Deep, the deepest ocean trench at about 11,000 metres (36,000 feet). Fishes of myriad varieties are the main predators in most of the world's water bodies, both freshwater and marine.
Amphistium Amphistium is a 50-million-year-old fossil fish that has been identified as an early relative of the flatfish, and as a transitional fossil.[119] In a typical modern flatfish, the head is asymmetric with both eyes on one side of the head. In Amphistium, the transition from the typical symmetric head of a vertebrate is incomplete, with one eye placed near the top of the head.[120]
Otodus megalodon
External videos
video icon Megalodon Giant SharkNational Geographic (full documentary)
video icon Megalodon battle History Channel
video icon The Nightmarish Megalodon Discovery

Megalodon is an extinct species of shark that lived about 28 to 1.5 Ma. It looked much like a stocky version of the great white shark, but was much larger with estimated length reaching up to 20.3 metres (67 ft).[121] Found in all oceans[122] it was one of the largest and most powerful predators in vertebrate history,[123] and probably had a profound impact on marine life.[124]

References

  1. ^ Sallan, L. C.; Coates, M. I. (June 2010). "End-Devonian extinction and a bottleneck in the early evolution of modern jawed vertebrates". Proceedings of the National Academy of Sciences. 107 (22): 10131–10135. Bibcode:2010PNAS..10710131S. doi:10.1073/pnas.0914000107. PMC 2890420. PMID 20479258.
  2. ^ a b Friedman, Matt; Sallan, Lauren Cole (June 2012). "Five hundred million years of extinczion and recovery: A Phanerozoic survey of large-scale diversity patterns in fishes". Palaeontology. 55 (4): 707–742. Bibcode:2012Palgy..55..707F. doi:10.1111/j.1475-4983.2012.01165.x. S2CID 59423401.
  3. ^ Dawkins 2004, p. 289: "Obviously vertebrates must have had ancestors living in the Cambrian, but they were assumed to be invertebrate forerunners of the true vertebrates — protochordates. Pikaia has been heavily promoted as the oldest fossil protochordate."
  4. ^ Morris SC (1979). "The Burgess Shale (Middle Cambrian) fauna". Annual Review of Ecology and Systematics. 10: 327–349. doi:10.1146/annurev.es.10.110179.001551. JSTOR 2096795.
  5. ^ Morris SC, Caron JB (2012). "Pikaia gracilens Walcott, a stem-group chordate from the Middle Cambrian of British Columbia" (PDF). Biological Reviews. 87 (2): 480–512. doi:10.1111/j.1469-185X.2012.00220.x. PMID 22385518. S2CID 27671780. Archived from the original (PDF) on 2012-05-27. Retrieved 2013-01-19.
  6. ^ Palmer 2000, p. 66-67.
  7. ^ a b Shu, D.-G.; Conway Morris, S.; Han, J.; et al. (January 2003). "Head and backbone of the Early Cambrian vertebrate Haikouichthys". Nature. 421 (6922): 526–529. Bibcode:2003Natur.421..526S. doi:10.1038/nature01264. PMID 12556891. S2CID 4401274.
  8. ^ The Cambrian: 2 Archived 2013-02-17 at the Wayback Machine Palaeos. Modified 26 October 2002. Retrieved 20 January 2013.
  9. ^ Donoghue, P.C.J.; Purnell, M.A. (2005). "Genome duplication, extinction and vertebrate evolution" (PDF). Trends in Ecology & Evolution. 20 (6): 312–319. doi:10.1016/j.tree.2005.04.008. PMID 16701387. Archived from the original (PDF) on 2008-12-17. Retrieved 2013-01-08.
  10. ^ Shu, D-G.; et al. (November 4, 1999). "Lower Cambrian vertebrates from south China". Nature. 402 (6757): 42–46. Bibcode:1999Natur.402...42S. doi:10.1038/46965. S2CID 4402854.
  11. ^ De Renzi M, Budorov K, Sudar M (1996). "The extinction of conodonts-in terms of discrete elements-at the Triassic-Jurassic boundary". Cuadernos de Geología Ibérica. 20: 347–364. Archived from the original on 2016-08-06. Retrieved 2013-01-20.
  12. ^ a b c Gabbott, S.E.; R. J. Aldridge; J. N. Theron (1995). "A giant conodont with preserved muscle tissue from the Upper Ordovician of South Africa". Nature. 374 (6525): 800–803. Bibcode:1995Natur.374..800G. doi:10.1038/374800a0. S2CID 4342260.
  13. ^ Briggs, D. (May 1992). "Conodonts: a major extinct group added to the vertebrates". Science. 256 (5061): 1285–1286. Bibcode:1992Sci...256.1285B. doi:10.1126/science.1598571. PMID 1598571.
  14. ^ Milsom, Clare; Rigby, Sue (2004). "Vertebrates". Fossils at a Glance. Victoria, Australia: Blackwell Publishing. p. 88. ISBN 978-0-632-06047-4.
  15. ^ Donoghue, P.C.J.; Forey, P.L.; Aldridge, R.J. (2000). "Conodont affinity and chordate phylogeny". Biological Reviews. 75 (2): 191–251. doi:10.1111/j.1469-185X.1999.tb00045.x. PMID 10881388. S2CID 22803015. Archived from the original on 2020-04-13. Retrieved 2008-04-07.
  16. ^ a b c d e f Palmer, D., ed. (1999). The Marshall Illustrated Encyclopedia of Dinosaurs and Prehistoric Animals. London: Marshall Editions. p. 23. ISBN 978-1-84028-152-1.
  17. ^ Ritchie, Alexander; Gilbert-Tomlinson, Joyce (1977). "First Ordovician vertebrates from the Southern Hemisphere". Alcheringa: An Australasian Journal of Palaeontology. 1 (4): 351–368. doi:10.1080/03115517708527770. ISSN 0311-5518.
  18. ^ Sansom IJ, Smith MP, Smith MM, Turner P (1997). "Astraspis: The anatomy and histology of an Ordovician fish" (PDF). Palaeontology. 40 (3): 625–642. Archived from the original (PDF) on 2013-10-29.
  19. ^ Turner, S.; Tarling, D. H. (1982). "Thelodont and other agnathan distributions as tests of Lower Paleozoic continental reconstructions". Palaeogeography, Palaeoclimatology, Palaeoecology. 39 (3–4): 295–311. Bibcode:1982PPP....39..295T. doi:10.1016/0031-0182(82)90027-X.
  20. ^ Sarjeant & Halstead 1995.
  21. ^ Donoghue 2000, p. 206.
  22. ^ Turner1999, p. 42–78.
  23. ^ The early and mid Silurian. See Kazlev, M.A.; White, T (March 6, 2001). "Palaeos: Thelodonti". Palaeos.com. Archived from the original on 2007-10-28. Retrieved October 30, 2007.
  24. ^ a b c Baez. John (2006) Extinction Archived 2013-01-30 at the Wayback Machine University of California. Retrieved 20 January 2013.
  25. ^ Ahlberg 2001, p. 188.
  26. ^ Hall & Hanken 1993, p. 131.
  27. ^ Janvier 2003.
  28. ^ Sansom, R. S. (2009). "Phylogeny, classification and character polarity of the Osteostraci (Vertebrata)". Journal of Systematic Palaeontology. 7: 95–115. doi:10.1017/S1477201908002551. S2CID 85924210.
  29. ^ Otto, M.; Laurin, M. (2001). "Microanatomy of the dermal skeleton of Balticaspis latvica (Osteostraci, Middle Devonian)". Journal of Vertebrate Paleontology. 21 (1): 186–189. doi:10.1671/0272-4634(2001)021[0186:motdso]2.0.co;2. S2CID 85964670. Archived from the original on 2020-09-03. Retrieved 2014-05-04.
  30. ^ Choo, Brian; Zhu, Min; Zhao, Wenjin; Jia, Liaotao; Zhu, You'an (2014). "The largest Silurian vertebrate and its palaeoecological implications". Scientific Reports. 4: 5242. Bibcode:2014NatSR...4E5242C. doi:10.1038/srep05242. PMC 4054400. PMID 24921626.
  31. ^ Zhu M, Zhao W, Jia L, Lu J, Qiao T, Qu Q (2009). "The oldest articulated osteichthyan reveals mosaic gnathostome characters". Nature. 458 (7237): 469–474. Bibcode:2009Natur.458..469Z. doi:10.1038/nature07855. PMID 19325627. S2CID 669711.
  32. ^ Coates M.I. (2009). "Palaeontology: Beyond the Age of Fishes". Nature. 458 (7237): 413–414. Bibcode:2009Natur.458..413C. doi:10.1038/458413a. PMID 19325614. S2CID 4384525.
  33. ^ Pharyngula Archived 2012-03-09 at the Wayback MachineScience blogs, 1 April 2009.
  34. ^ Min Z; Schultze, Hans-Peter (1997). "The oldest sarcopterygian fish" (PDF). Lethaia. 30 (4): 293–304. doi:10.1111/j.1502-3931.1997.tb00472.x. Archived from the original on 2020-09-03. Retrieved 2017-12-12.
  35. ^ Märss T (2001). "Andreolepis (Actinopterygii) in the upper Silurian of northern Eurasia". Proceedings of the Estonian Academy of Sciences. 50 (3): 174–189. doi:10.3176/geol.2001.3.03. S2CID 67798212. Archived from the original on 2020-08-01. Retrieved 2020-06-07.
  36. ^ Parry, S.F.; Noble S.R.; Crowley Q.G.; Wellman C.H. (2011). "A high-precision U–Pb age constraint on the Rhynie Chert Konservat-Lagerstätte: time scale and other implications". Journal of the Geological Society. 168 (4). London: Geological Society: 863–872. doi:10.1144/0016-76492010-043.
  37. ^ Kaufmann, B.; Trapp, E.; Mezger, K. (2004). "The numerical age of the Upper Frasnian (Upper Devonian) Kellwasser horizons: A new U-Pb zircon date from Steinbruch Schmidt(Kellerwald, Germany)". The Journal of Geology. 112 (4): 495–501. Bibcode:2004JG....112..495K. doi:10.1086/421077.
  38. ^ Amos, Jonathan (6 January 2010). "Fossil tracks record 'oldest land-walkers'". BBC News. Archived from the original on 24 August 2018. Retrieved 4 December 2012.
  39. ^ "Age of Fishes Museum - Home". www.ageoffishes.org.au. Archived from the original on 14 March 2019. Retrieved 25 March 2019.
  40. ^ Benton 2005, p. 65.
  41. ^ The Marshall Illustrated Encyclopedia of Dinosaurs and Prehistoric Animals 1999, p. 43.
  42. ^ Holland T (2010). "Upper Devonian osteichthyan remains from the Genoa River, Victoria, Australia". Memoirs of Museum Victoria. 67: 35–44. doi:10.24199/j.mmv.2010.67.04.
  43. ^ Dell'Amore, C. (September 12, 2011). "Ancient Toothy Fish Found in Arctic—Giant Prowled Rivers". National Geographic Daily News. Archived from the original on September 24, 2011. Retrieved September 13, 2011.
  44. ^ Tom Avril (September 12, 2011). "Fish fossil sheds light on 'Euramerica' phase". The Inquirer. Archived from the original on September 15, 2012. Retrieved September 15, 2011.
  45. ^ Vorobyeva, E.I. (2006). "A new species of Laccognathus (Porolepiform Crossopterygii) from the Devonian of Latvia". Paleontol. J. 40 (3). Physorg.com: 312–322. doi:10.1134/S0031030106030129. S2CID 129696592.
  46. ^ Witzman, F. (2011). "A New Species of Laccognathus (Sarcopterygii, Porolepiformes) from the Late Devonian of Ellesmere Island, Nunavut, Canada". Journal of Vertebrate Paleontology. 31 (5): 981–996. Bibcode:2011JVPal..31..981D. doi:10.1080/02724634.2011.599462. S2CID 140604758.
  47. ^ The Marshall Illustrated Encyclopedia of Dinosaurs and Prehistoric Animals 1999, p. 32.
  48. ^ Long 1996.
  49. ^ Coates, Michael I.; Finarelli, John A.; Sansom, Ivan J.; Andreev, Plamen S.; Criswell, Katharine E.; Tietjen, Kristen; Rivers, Mark L.; La Riviere, Patrick J. (2018-01-10). "An early chondrichthyan and the evolutionary assembly of a shark body plan". Proceedings of the Royal Society B: Biological Sciences. 285 (1870): 20172418. doi:10.1098/rspb.2017.2418. ISSN 0962-8452. PMC 5784200. PMID 29298937.
  50. ^ a b c The Marshall Illustrated Encyclopedia of Dinosaurs and Prehistoric Animals 1999, p. 26.
  51. ^ a b Ferrón, Humberto G.; Martínez-Pérez, Carlos; Botella, Héctor (2017-12-06). "Ecomorphological inferences in early vertebrates: reconstructing Dunkleosteus terrelli (Arthrodira, Placodermi) caudal fin from palaeoecological data". PeerJ. 5: e4081. doi:10.7717/peerj.4081. ISSN 2167-8359. PMC 5723140. PMID 29230354.
  52. ^ The Marshall Illustrated Encyclopedia of Dinosaurs and Prehistoric Animals 1999, p. 45.
  53. ^ Monster fish crushed opposition with strongest bite ever Archived 2013-04-02 at the Wayback Machine. The Sydney Morning Herald. November 30, 2006.
  54. ^ "Press release: Ancient predator had strongest bite of any fish, rivaling bite of large alligators and T. rex". Field Museum via EurekAlert!. November 28, 2006. Archived from the original on August 10, 2017. Retrieved August 9, 2017.
  55. ^ Roy Britt, Robert (28 November 2006). "Prehistoric Fish Had Most Powerful Jaws". LiveScience. Archived from the original on 2020-09-03. Retrieved 2009-04-26.
  56. ^ Long, J. A.; Trinajstic, K.; Young, G. C.; Senden, T. (2008). "Live birth in the Devonian period". Nature. 453 (7195): 650–652. Bibcode:2008Natur.453..650L. doi:10.1038/nature06966. PMID 18509443. S2CID 205213348.
  57. ^ Fossil reveals oldest live birth Archived 2009-02-28 at the Wayback Machine BBC News, 28 May 2008.
  58. ^ Thomson, K. S. (1968). "A new Devonian fish (Crossopterygii: Rhipidistia) considered in relation to the origin of the Amphibia". Postilla. 124.
  59. ^ a b Grzegorz Niedźwiedzki; Piotr Szrek; Katarzyna Narkiewicz; Marek Narkiewicz; Per E. Ahlberg (2010). "Tetrapod trackways from the early Middle Devonian period of Poland". Nature. 463 (7277). Nature Publishing Group: 43–48. Bibcode:2010Natur.463...43N. doi:10.1038/nature08623. PMID 20054388. S2CID 4428903.
  60. ^ Gordon, M. S.; Graham, J. B.; Wang, T. (2004). "Revisiting the Vertebrate Invasion of the Land". Physiological and Biochemical Zoology. 77 (5): 697–699. doi:10.1086/425182. S2CID 83750933.
  61. ^ a b c d Clack, J. A. (November 2005). "Getting a Leg Up on Land". Scientific American. Archived from the original on 2020-07-28. Retrieved 2008-09-06.
  62. ^ a b Laurin M.; Meunier F. J.; Germain D.; Lemoine M. (2007). "A Microanatomical and Histological Study of the Paired Fin Skeleton of the Devonian Sarcopterygian Eusthenopteron Foordi". Journal of Paleontology. 81: 143–153. doi:10.1666/0022-3360(2007)81[143:AMAHSO]2.0.CO;2. ISSN 0022-3360. S2CID 131170482.
  63. ^ "Fish-Tetrapod Transition Got A New Hypothesis In 2011". Science 2.0. December 27, 2011. Archived from the original on January 14, 2012. Retrieved January 2, 2012.
  64. ^ Shanta Barley (6 January 2010). "Oldest footprints of a four-legged vertebrate discovered". New Scientist. Archived from the original on 17 March 2010. Retrieved January 3, 2010.
  65. ^ Retallack, Gregory (2011). "Woodland Hypothesis for Devonian Tetrapod Evolution". Journal of Geology. 119 (3). University of Chicago Press: 235–258. Bibcode:2011JG....119..235R. doi:10.1086/659144. S2CID 128827936.
  66. ^ Holmgren, N (1933). "On the origin of the tetrapod limb". Acta Zoologica. 14 (2–3): 185–295. doi:10.1111/j.1463-6395.1933.tb00009.x.
  67. ^ Vorobyeva EI (1992). "The role of development and function in formation of tetrapod like pectoral fins". Zh. Obshch. Biol. 53: 149–158.
  68. ^ Watson DMS (1913). "On the primitive tetrapod limb". Anat. Anzeiger. 44: 24–27.
  69. ^ Shubin N, Tabin C, Carroll S (1997). "Fossils, genes and the evolution of animal limbs". Nature. 388 (6643): 639–48. Bibcode:1997Natur.388..639S. doi:10.1038/41710. PMID 9262397. S2CID 2913898.
  70. ^ a b c d Boisvert CA, Mark-Kurik E, Ahlberg PE (2008). "The pectoral fin of Panderichthys and the origin of digits". Nature. 456 (7222): 636–8. Bibcode:2008Natur.456..636B. doi:10.1038/nature07339. PMID 18806778. S2CID 2588617. Archived from the original on 2014-01-04. Retrieved 2013-02-15.
  71. ^ Than, Ker (September 24, 2008). "Ancient Fish Had Primitive Fingers, Toes". National Geographic News. Archived from the original on September 27, 2008.
  72. ^ Ahlberg, P. E.; Milner, A. R. (April 1994). "The Origin and Early Diversification of Tetrapods". Nature. 368 (6471): 507–514. Bibcode:1994Natur.368..507A. doi:10.1038/368507a0. S2CID 4369342.
  73. ^ Geological Survey of Canada (2008-02-07). "Past lives: Chronicles of Canadian Paleontology: Eusthenopteron - the Prince of Miguasha". Archived from the original on 2004-12-11. Retrieved 2009-02-10.
  74. ^ Nature: The pelvic fin and girdle of Panderichthys and the origin of tetrapod locomotion Archived 2012-08-12 at the Wayback Machine
  75. ^ Edward B. Daeschler; Neil H. Shubin; Farish A. Jenkins Jr (6 April 2006). "A Devonian tetrapod-like fish and the evolution of the tetrapod body plan". Nature. 440 (7085): 757–763. Bibcode:2006Natur.440..757D. doi:10.1038/nature04639. PMID 16598249.
  76. ^ John Noble Wilford, The New York Times, Scientists Call Fish Fossil the Missing Link Archived 2017-11-15 at the Wayback Machine, Apr. 5, 2006.
  77. ^ Shubin, Neil (2008). Your Inner Fish. Pantheon. ISBN 978-0-375-42447-2.
  78. ^ "Acanthostega gunneri Archived 2004-12-24 at the Wayback Machine," Devonian Times.
  79. ^ Daeschler, E. B.; Shubin, N. H.; Jenkins, F. A. (April 2006). "A Devonian tetrapod-like fish and the evolution of the tetrapod body plan". Nature. 440 (7085): 757–763. Bibcode:2006Natur.440..757D. doi:10.1038/nature04639. PMID 16598249. S2CID 4413217.
  80. ^ a b c d e Romano, Carlo; Koot, Martha B.; Kogan, Ilja; Brayard, Arnaud; Minikh, Alla V.; Brinkmann, Winand; Bucher, Hugo; Kriwet, Jürgen (February 2016). "Permian-Triassic Osteichthyes (bony fishes): diversity dynamics and body size evolution". Biological Reviews. 91 (1): 106–147. doi:10.1111/brv.12161. PMID 25431138. S2CID 5332637.
  81. ^ a b Clarke, John T.; Friedman, Matt (August 2018). "Body-shape diversity in Triassic–Early Cretaceous neopterygian fishes: sustained holostean disparity and predominantly gradual increases in teleost phenotypic variety". Paleobiology. 44 (3): 402–433. Bibcode:2018Pbio...44..402C. doi:10.1017/pab.2018.8. ISSN 0094-8373. S2CID 90207334. Archived from the original on 2020-09-03. Retrieved 2019-12-12.
  82. ^ a b c d R. Aidan Martin. "A Golden Age of Sharks". Biology of Sharks and Rays. Archived from the original on 2008-05-22. Retrieved 2008-06-23.
  83. ^ Ward P.; Labandeira, C.; Laurin, M.; Berner, R. A.; et al. (2006). "Confirmation of Romer's Gap is a low oxygen interval constraining the timing of initial arthropod and vertebrate terrestrialization". Proceedings of the National Academy of Sciences. 103 (45): 16818–16822. Bibcode:2006PNAS..10316818W. doi:10.1073/pnas.0607824103. PMC 1636538. PMID 17065318.
  84. ^ Coates, Michael I.; Gess, Robert W.; Finarelli, John A.; Criswell, Katharine E.; Tietjen, Kristen (2017). "A symmoriiform chondrichthyan braincase and the origin of chimaeroid fishes". Nature. 541 (7636): 208–211. Bibcode:2017Natur.541..208C. doi:10.1038/nature20806. ISSN 1476-4687. PMID 28052054. S2CID 4455946.
  85. ^ Lund, Richard; Grogan, Eileen (2006). "Fossil Fish of Bear Gulch: Falcatus falcatus". Archived from the original on 2008-08-21.
  86. ^ Finarelli, John A.; Coates, Michael I. (1 March 2014). "Chondrenchelys problematica (Traquair, 1888) redescribed: a Lower Carboniferous, eel-like holocephalan from Scotland". Earth and Environmental Science Transactions of the Royal Society of Edinburgh. 105 (1): 35–59. doi:10.1017/S1755691014000139. S2CID 130533675.
  87. ^ Edinburgh, Royal Physical Society of (1880). Proceedings of the Royal Physical Society of Edinburgh. Vol. V. p. 115. Archived from the original on 2020-08-01. Retrieved 2020-06-07.
  88. ^ Nicholson, Henry Alleyne; Richard Lydekker (1889). A Manual of Palaeontology. p. 966. Archived from the original on 2020-08-01. Retrieved 2020-06-07.
  89. ^ "Study Sheds New Light on Common Ancestor of All Jawed Vertebrates". Sci-News.com. 15 June 2012. Archived from the original on 21 October 2012.
  90. ^ Coates, Michael I.; Finarelli, John A.; Davis, Samuel P. (1 June 2012). "Acanthodes and shark-like conditions in the last common ancestor of modern gnathostomes". Nature. 486 (7402): 247–250. Bibcode:2012Natur.486..247D. doi:10.1038/nature11080. PMID 22699617. S2CID 4304310.
  91. ^ Alden, Andrew (17 March 2017). "The Permian-Triassic Extinction". ThoughtCo. Archived from the original on 25 March 2019.
  92. ^ "GeoKansas--Geotopics--Mass Extinctions". Archived from the original on 2012-09-20. Retrieved 2012-12-04.
  93. ^ Sahney, S.; Benton, M.J. (2008). "Recovery from the most profound mass extinction of all time". Proceedings of the Royal Society B: Biological Sciences. 275 (1636): 759–65. doi:10.1098/rspb.2007.1370. PMC 2596898. PMID 18198148.
  94. ^ a b Smithwick, Fiann M.; Stubbs, Thomas L. (2 February 2018). "Phanerozoic survivors: Actinopterygian evolution through the Permo‐Triassic and Triassic‐Jurassic mass extinction events". Evolution. 72 (2): 348–362. doi:10.1111/evo.13421. PMC 5817399. PMID 29315531.
  95. ^ Bony fishes Archived 2013-06-06 at the Wayback Machine SeaWorld. Retrieved 2 February 2013.
  96. ^ Cavin, Lionel; Furrer, H.; Obrist, C. (2013). "New coelacanth material from the Middle Triassic of eastern Switzerland, and comments on the taxic diversity of actinistans". Swiss Journal of Geosciences. 106 (2): 161–177. doi:10.1007/s00015-013-0143-7. S2CID 140189669.
  97. ^ Maxwell; et al. (2018). "Re‐evaluation of the ontogeny and reproductive biology of the Triassic fish Saurichthys (Actinopterygii, Saurichthyidae)". Palaeontology. 61: 559–574. doi:10.5061/dryad.vc8h5.
  98. ^ Kogan; et al. (2015). "The invisible fish: hydrodynamic constraints for predator-prey interaction in fossil fish Saurichthys compared to recent actinopterygians". Biology Open. 4 (12): 1715–1726. doi:10.1242/bio.014720. PMC 4736038. PMID 26603471.
  99. ^ a b López-Arbarello, Adriana; Sferco, Emilia (March 2018). "Neopterygian phylogeny: the merger assay". Royal Society Open Science. 5 (3): 172337. Bibcode:2018RSOS....572337L. doi:10.1098/rsos.172337. PMC 5882744. PMID 29657820.
  100. ^ a b The Marshall Illustrated Encyclopedia of Dinosaurs and Prehistoric Animals 1999, p. 38–39.
  101. ^ a b "extinction". Math.ucr.edu. Archived from the original on 2012-06-30. Retrieved 2008-11-09.
  102. ^ Motani, R. (2000), Rulers of the Jurassic Seas, Scientific American vol.283, no. 6
  103. ^ Wings, Oliver; Rabi, Márton; Schneider, Jörg W.; Schwermann, Leonie; sun, Ge; Zhou, Chang-Fu; Joyce, Walter G. (2012). "An enormous Jurassic turtle bone bed from the Turpan Basin of Xinjiang, China". Naturwissenschaften. 114 (11): 925–935. Bibcode:2012NW.....99..925W. doi:10.1007/s00114-012-0974-5. PMID 23086389. S2CID 17423081.
  104. ^ Gannon, Megan (October 31, 2012). "Jurassic turtle graveyard found in China". Livescience.com. Archived from the original on November 5, 2012. Retrieved December 4, 2012.
  105. ^ Liston, Jeff, M. Newbrey, T. Challands and C. Adams (2013) "Growth, age and size of the Jurassic pachycormid Leedsichthys problematicus (Osteichthyes: Actinopterygii) Archived 2016-03-04 at the Wayback Machine." in G. Arratia, H. P. Schultze and M. V. H. Wilson (Eds) Mesozoic Fishes 5 – Global Diversity and Evolution, : Pages 145-175, F. Pfeil. ISBN 9783899370539.
  106. ^ "Biggest Fish Ever Found" Unearthed in U.K. Archived 2016-08-12 at the Wayback Machine National Geographic News, 1 October 2003.
  107. ^ B. G. Gardiner (1984) Sturgeons as living fossils. Pp. 148–152 in N. Eldredge and S.M. Stanley, eds. Living fossils. Springer-Verlag, New York.
  108. ^ Krieger J.; Fuerst P.A. (2002). "Evidence for a Slowed Rate of Molecular Evolution in the Order Acipenseriformes". Molecular Biology and Evolution. 19 (6): 891–897. doi:10.1093/oxfordjournals.molbev.a004146. PMID 12032245.
  109. ^ Rafferty, John P (2010) The Mesozoic Era: Age of Dinosaurs Archived 2020-08-01 at the Wayback Machine Page 219, Rosen Publishing Group. ISBN 9781615301935.
  110. ^ Hoffman, Brian L.; Hageman, Scott A.; Claycomb, Gregory D. (2016). "Scanning electron microscope examination of the dental enameloid of the Cretaceous durophagous shark Ptychodus supports neoselachian classification". Journal of Paleontology. 90 (4): 741–762. Bibcode:2016JPal...90..741H. doi:10.1017/jpa.2016.64. ISSN 0022-3360. S2CID 132252846.
  111. ^ Fossils (Smithsonian Handbooks) by David Ward (Page 200)
  112. ^ The paleobioloy Database Ptychodus entry Archived 2013-07-26 at the Wayback Machine accessed on 8/23/09
  113. ^ "BBC - Earth News - Giant predatory shark fossil unearthed in Kansas"
  114. ^ MacLeod N, Rawson PF, Forey PL, Banner FT, Boudagher-Fadel MK, Bown PR, Burnett JA, Chambers P, Culver S, Evans SE, Jeffery C, Kaminski MA, Lord AR, Milner AC, Milner AR, Morris N, Owen E, Rosen BR, Smith AB, Taylor PD, Urquhart E, Young JR (1997). "The Cretaceous–Tertiary biotic transition". Journal of the Geological Society. 154 (2): 265–292. Bibcode:1997JGSoc.154..265M. doi:10.1144/gsjgs.154.2.0265. S2CID 129654916.
  115. ^ Patterson, C (1993). Osteichthyes: Teleostei. In: The Fossil Record 2 (Benton, MJ, editor). Springer. pp. 621–656. ISBN 978-0-412-39380-8.
  116. ^ Zinsmeister WJ (1 May 1998). "Discovery of fish mortality horizon at the K–T boundary on Seymour Island: Re-evaluation of events at the end of the Cretaceous". Journal of Paleontology. 72 (3): 556–571. Bibcode:1998JPal...72..556Z. doi:10.1017/S0022336000024331. S2CID 132206016. Archived from the original on 2007-10-30. Retrieved 2007-08-27.
  117. ^ Robertson DS, McKenna MC, Toon OB, Hope S, Lillegraven JA (2004). "Survival in the first hours of the Cenozoic" (PDF). GSA Bulletin. 116 (5–6): 760–768. Bibcode:2004GSAB..116..760R. doi:10.1130/B25402.1. Archived from the original (PDF) on 2015-10-22. Retrieved 2016-01-06.
  118. ^ Sibert, E. C.; Norris, R. D. (2015-06-29). "New Age of Fishes initiated by the Cretaceous−Paleogene mass extinction". PNAS. 112 (28): 8537–8542. Bibcode:2015PNAS..112.8537S. doi:10.1073/pnas.1504985112. PMC 4507219. PMID 26124114.
  119. ^ "Odd Fish Find Contradicts Intelligent-Design Argument". National Geographic. July 9, 2008. Archived from the original on 2018-05-28. Retrieved 2008-07-17.
  120. ^ Matt Friedman (2008-07-10). "The evolutionary origin of flatfish asymmetry". Nature. 454 (7201): 209–212. Bibcode:2008Natur.454..209F. doi:10.1038/nature07108. PMID 18615083. S2CID 4311712.
  121. ^ Perez, Victor J.; Leder, Ronny M.; Badaut, Teddy (2021-03-09). "Body length estimation of Neogene macrophagous lamniform sharks (Carcharodon and Otodus) derived from associated fossil dentitions". Palaeontologia Electronica. 24 (1): 1–28. doi:10.26879/1140. ISSN 1094-8074. S2CID 232216009.
  122. ^ Pimiento, Catalina; Dana J. Ehret; Bruce J. MacFadden; Gordon Hubbell (May 10, 2010). Stepanova, Anna (ed.). "Ancient Nursery Area for the Extinct Giant Shark Megalodon from the Miocene of Panama". PLOS ONE. 5 (5). Panama: PLoS.org: e10552. Bibcode:2010PLoSO...510552P. doi:10.1371/journal.pone.0010552. PMC 2866656. PMID 20479893.
  123. ^ Wroe, S.; Huber, D. R.; Lowry, M.; McHenry, C.; Moreno, K.; Clausen, P.; Ferrara, T. L.; Cunningham, E.; Dean, M. N.; Summers, A. P. (2008). "Three-dimensional computer analysis of white shark jaw mechanics: how hard can a great white bite?" (PDF). Journal of Zoology. 276 (4): 336–342. doi:10.1111/j.1469-7998.2008.00494.x. Archived (PDF) from the original on 2018-11-27. Retrieved 2013-01-12.
  124. ^ Lambert, Olivier; Giovanni Bianucci; Klaas Post; Christian de Muizon; Rodolfo Salas-Gismondi; Mario Urbina; Jelle Reumer (1 July 2010). "The giant bite of a new raptorial sperm whale from the Miocene epoch of Peru". Nature. 466 (7302). Peru: 105–108. Bibcode:2010Natur.466..105L. doi:10.1038/nature09067. PMID 20596020. S2CID 4369352.

Sources

Retrieved from "https://mdwiki.org/wiki/Timeline_of_fish_evolution"