Ichthyosaur

Ichthyosauria
Fossil range: 245–90 Ma
Middle Triassic - Late Cretaceous
Adult and juvenile Stenopterygius quadriscissus
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Sauropsida
Subclass: Diapsida
Superorder: †Ichthyopterygia
Order: Ichthyosauria
Blainville, 1835
Families

Ichthyosauridae
Leptopterygiidae
Mixosauridae
Ophthalmosauridae
Shastasauridae
Stenopterygiidae
Temnodontosauridae
Toretocnemidae

Ichthyosaurs (Greek for "fish lizard" - ιχθυς/ichthys meaning "fish" and σαυρος/sauros meaning "lizard") were giant marine reptiles that resembled fish and dolphins. Ichthyosaurs thrived during much of the Mesozoic era; based on fossil evidence, they first appeared approximately 245 million years ago (mya) and disappeared about 90 million years ago, about 25 million years before the dinosaurs became extinct. During the middle Triassic Period, ichthyosaurs evolved from as-yet unidentified land reptiles that moved back into the water, in a development parallel to that of the ancestors of modern-day dolphins and whales. They were particularly abundant in the Jurassic Period, until they were replaced as the top aquatic predators by plesiosaurs in the Cretaceous Period. They belong to the order known as Ichthyosauria or Ichthyopterygia ('fish flippers' - a designation introduced by Sir Richard Owen in 1840, although the term is now used more for the parent clade of the Ichthyosauria).

Contents

Description

Platypterygius kiprijanovi - Albian-Cenomanian of Kursk region (Russia)

Ichthyosaurs averaged 2–4 metres (6.6–13 ft) in length (although a few were smaller, and some species grew much larger), with a porpoise-like head and a long, toothed snout. Built for speed, like modern tuna, some ichthyosaurs appear also to have been deep divers, like some modern whales (Motani, 2000). It has been estimated that ichthyosaurs could swim at speeds up to 40 kilometres per hour (25 mph).[1] Similar to modern cetaceans such as whales and dolphins, they were air-breathing.

According to weight estimates by Ryosuke Motani[2] a 2.4 meters (8 ft) Stenopterygius weighed around 163–68 kilograms (360–150 lb) whilst a 4 meters (13 ft) Ophthalmosaurus icenicus weighed 930–950 kilograms (1.03–1.05 short tons).

Although ichthyosaurs looked like fish, they were not. Biologist Stephen Jay Gould said the ichthyosaur was his favorite example of convergent evolution, where similarities of structure are analogous not homologous, for this group:

converged so strongly on fishes that it actually evolved a dorsal fin and tail in just the right place and with just the right hydrological design. These structures are all the more remarkable because they evolved from nothing — the ancestral terrestrial reptile had no hump on its back or blade on its tail to serve as a precursor.

Historical illustration of an Ichthyosaur from 1863, note the missing dorsal fin

In fact the earliest reconstructions of ichthyosaurs omitted the dorsal fin, which had no hard skeletal structure, until finely-preserved specimens recovered in the 1890s from the Holzmaden lagerstätten in Germany revealed traces of the fin. Unique conditions permitted the preservation of soft tissue impressions.[3]

Ichthyosaur 'paddle' (Charmouth Heritage Coast Centre).

Ichthyosaurs had fin-like limbs, which were possibly used for stabilisation and directional control, rather than propulsion, which would have come from the large shark-like tail. The tail was bi-lobed, with the lower lobe being supported by the caudal vertebral column, which was "kinked" ventrally to follow the contours of the ventral lobe.

Apart from the obvious similarities to fish, the ichthyosaurs also shared parallel developmental features with dolphins, lamnid sharks, and tunas. This gave them a broadly similar appearance, possibly implied similar activity levels (including thermoregulation), and presumably placed them broadly in a similar ecological niche.

Ichthyosaur vertebrae from the Sundance Formation (Jurassic) of Natrona County, Wyoming. Note the characteristic"figure-8" cross-section for this variety. Scale in mm.

Reproduction

They were viviparous (bore live young). Some adult fossils have even been found containing fetuses. Although they were reptiles and descended from egg-laying ancestors, viviparity is not as unexpected as it first appears. Air-breathing marine creatures must either come ashore to lay eggs, like turtles and some sea snakes, or else give birth to live young in surface waters, like whales and dolphins. Given their streamlined bodies, heavily adapted for fast swimming, it would have been difficult for ichthyosaurs to move far enough on land to lay eggs.

Crocodiles, most sea turtles and some lizards, control offspring gender by manipulating the temperature of the eggs' environment. I.e., they do not have of distinct sex chromosomes. Live-bearing reptiles do not regulate sex through incubation temperature. A recent study examined 94 living species of reptiles, birds and mammals and found that the genetic control of sex appears to be crucial to live birth and that genetics likely controlled gender in ichthyosaurs, mosasaurs and other extinct marine reptiles.[4]

Feeding

For their food, many of the fish-shaped ichthyosaurs relied heavily on ancient cephalopod kin of squids called belemnites. Some early ichthyosaurs had teeth adapted for crushing shellfish. They also most likely fed on fish, and a few of the larger species had heavy jaws and teeth that indicated they fed on smaller reptiles. Ichthyosaurs ranged so widely in size, and survived for so long, that they are likely to have had a wide range of prey. Typical ichthyosaurs have very large eyes, protected within a bony ring, suggesting that they may have hunted at night.

History of discoveries

The genus had first been described in 1699 from fossil fragments discovered in Wales.

The first fossil vertebrae were published twice in 1708 as tangible mementos of the Universal Deluge. The first complete ichthyosaur fossil was found in 1811 by Mary Anning in Lyme Regis, along what is now called the Jurassic Coast. She subsequently discovered three separate species.

In 1905, the Saurian Expedition led by John C. Merriam of the University of California and financed by Annie Alexander, found 25 specimens in central Nevada, which during the Triassic was under a shallow ocean. Several of the specimens are now in the collection of the University of California Museum of Paleontology. Other specimens are embedded in the rock and visible at Berlin–Ichthyosaur State Park in Nye County. In 1977, the Triassic ichthyosaur Shonisaurus became the State Fossil of Nevada. Nevada is the only state to possess a complete skeleton, 17 m (55 ft) of this extinct marine reptile. In 1992, Canadian ichthyologist Dr. Elizabeth Nicholls (Curator of Marine Reptiles at the Royal Tyrrell Museum) uncovered the largest known specimen, a 23 m-long (75 ft) example.

Evolutionary history

Grippia longirostris from early Triassic of Spitsbergen

The earliest ichthyosaurs, looking more like finned lizards than the familiar fish or dolphin forms, are known from the Early and Early-Middle (Olenekian and Anisian) Triassic strata of Canada, China, Japan, and Spitsbergen in Norway. These primitive forms included the genera Chaohusaurus, Grippia, and Utatsusaurus.

These very early proto-ichthyosaurs, which are now classified as Ichthyopterygia rather than as ichthyosaurs proper (Motani 1997, Motani et al. 1998), quickly gave rise to true ichthyosaurs sometime around the boundary between the Early Triassic and Middle Triassic. These later diversified into a variety of forms, including the sea serpent like Cymbospondylus, which reached 10 metres, and smaller more typical forms like Mixosaurus. By the Late Triassic, ichthyosaurs consisted of both classic Shastasauria and more advanced, "dolphin"-like Euichthyosauria (Californosaurus, Toretocnemus) and Parvipelvia (Hudsonelpidia, Macgowania). Experts disagree over whether these represent an evolutionary continuum, with the less specialised shastosaurs a paraphyletic grade that was evolving into the more advanced forms (Maisch and Matzke 2000), or whether the two were separate clades that evolved from a common ancestor earlier on (Nicholls and Manabe 2001).

Shonisaurus popularis.

During the Carnian and Norian, shastosaurs reached huge sizes. Shonisaurus popularis, known from a number of specimens from the Carnian of Nevada, was 15 metres long. Norian shonisaurs are known from both sides of the Pacific. Himalayasaurus tibetensis and Tibetosaurus (probably a synonym) have been found in Tibet. These large (10 to 15 metres long) ichthyosaurs probably belong to the same genus as Shonisaurus (Motani et al., 1999; Lucas, 2001, pp. 117–119). While the gigantic Shonisaurus sikanniensis, whose remains were found in the Pardonet formation of British Columbia by Elizabeth Nicholls, reached as much as 21 metres in length - the largest marine reptile known to date.

These giants (along with their smaller cousins) seemed to have disappeared at the end of the Norian. Rhaetian (latest Triassic) ichthyosaurs are known from England, and these are very similar to those of the Early Jurassic. Like the dinosaurs, the ichthyosaurs and their contemporaries the plesiosaurs survived the end-Triassic extinction event, and immediately diversified to fill the vacant ecological niches of the earliest Jurassic.

Ichthyosaurus sp. fossil

The Early Jurassic, like the Late Triassic, was the heyday of the ichthyosaurs, which are represented by four families and a variety of species, ranging from one to ten metres in length. Genera include Eurhinosaurus, Ichthyosaurus, Leptonectes, Stenopterygius, and the large predator Temnodontosaurus, along with the persistently primitive Suevoleviathan, which was little changed from its Norian ancestors. All these animals were streamlined, dolphin-like forms, although the more primitive animals were perhaps more elongated than the advanced and compact Stenopterygius and Ichthyosaurus.

Ophthalmosaurus icenius

Ichthyosaurs were still common in the Middle Jurassic, but had now decreased in diversity. All belonged to the single clade Ophthalmosauria. Represented by the 4 metre long Ophthalmosaurus and related genera, they were very similar to Ichthyosaurus, and had attained a perfect "tear-drop" streamlined form. The eyes of Ophthalmosaurus were huge, and it is likely that these animals hunted in dim and deep water (Motani 2000).

Ichthyosaurs seemed to decrease in diversity even further with the Cretaceous. Only three genera are known, Caypullisaurus, Maiaspondylus, and Platypterygius, although they had a worldwide distribution. This last ichthyosaur genus became extinct during the Cenomanian-Turonian extinction event early in the Late Cretaceous (as did the pliosaurs). Interestingly, less hydrodynamically efficient animals like mosasaurs and long-necked plesiosaurs flourished. It could be that the ichthyosaurian over-specialisation was a contributing factor to their extinction, possibly being unable to 'keep up' with the fast swimming and highly evasive new teleost fish, which had become dominant at this time, against which the sit-and-wait ambush strategies of the mosasaurs proved superior (Lingham-Soliar 1999).

Taxonomy

Phylogeny

The following cladogram is based on "Ryosuke Motani Ichthyosaur Page":[5]

Ichthyosauria

Cymbospondylus

      

Mixosauria

Merriamosauria

Shastasauridae

Euichthyosauria

Toretocnemus

      

Californosaurus

Parvipelvia

Macgowania, Hudsonelpidia, Suevoleviathan

      

Eurhinosauria


Temnodontosaurus

Thunnosauria

Stenopterygius



Ichthyosaurus


Ophthalmosauridae










Geologic formations

The following is a list of geologic formations with ichthyosaur fossils.

Name Age Location Notes

Franciscan Formation

Hosselkus Limestone

Los Molles Formation

Oxford Clay

Solnhofen Limestone

Sulphur Mountain Formation

Sundance Formation

In popular culture

hundred feet long" (William Butcher trans.) much, much larger than it was in reality.

References

  1. http://www.genetologisch-onderzoek.nl/index.php/42/beeldende-kunst/
  2. http://www.ucmp.berkeley.edu/people/motani/ichthyo/weight.html
  3. Martill D.M. 1993. Soupy Substrates: A Medium for the Exceptional Preservation of Ichthyosaurs of the Posidonia Shale (Lower Jurassic) of Germany. Kaupia - Darmstädter Beiträge zur Naturgeschichte 2: 77-97
  4. Carroll, Sean B. (March 22, 2010). "For Extinct Monsters of the Deep, a Little Respect". The New York Times. http://www.nytimes.com/2010/03/23/science/23creatures.html?src=sch&pagewanted=all. 
  5. Ryosuke Motani homepage - Phylogeny of Ichthyosaurs
  • Ellis, Richard, (2003) Sea Dragons - Predators of the Prehistoric Oceans. University Press of Kansas ISBN 0-7006-1269-6
  • Stephen Jay Gould, "Bent out of Shape" in Eight Little Piggies.
  • Lingham-Soliar, T. (1999): A functional analysis of the skull of Goronyosaurus nigeriensis (Squamata: Mosasauridae) and Its Bearing on the Predatory Behavior and Evolution of the Enigmatic Taxon. N. Jb. Geol. Palaeont. Abh. 2134 (3):355-74
  • Maisch, M. W. & Matzke, A. T. (2000) The ichthyosauria. Stuttgarter Beitraege zur Naturkunde. Serie B. Geologie und Palaeontologie. 2000; (298):1-159.
  • McGowan, Christopher (1992) Dinosaurs, Spitfires and Sea Dragons, Harvard University Press, ISBN 0-674-20770-X
  • McGowan, Christopher & Motani, Ryosuke, (2003) Ichthyopterygia, Handbook of Paleoherpetology, Part 8, Verlag Dr. Friedrich Pfeil
  • Motani, R. (1997), Temporal and spatial distribution of tooth implantation in ichthyosaurs, in JM Callaway & EL Nicholls (eds.), Ancient Marine Reptiles. Academic Press. pp. 81–103.
  • Motani, R. (2000), Rulers of the Jurassic Seas, Scientific American vol.283, no. 6
  • Motani, R., Minoura, N. & Ando, T. (1998), Ichthyosaurian relationships illuminated by new primitive skeletons from Japan. Nature 393:255-257.
  • Motani, R., Manabe, M., and Dong, Z-M, (1999) The status of Himalayasaurus tibetensis (Ichthyopterygia) pdf, Paludicola2(2):174-181.
  • Nicholls, E. L. & Manabe, M. 2001. A new genus of ichthyosaur from the Late Triassic Pardonet Formation of British Columbia: bridging the Triassic-Jurassic gap. Canadian Journal of Earth Sciences 38:983-1002.

External links