Cephalopod

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Cephalopods
Fossil range: Late Cambrian - Recent
A variety of cephalopod forms from Ernst Haeckel's 1904 Kunstformen der Natur.
A variety of cephalopod forms from Ernst Haeckel's 1904 Kunstformen der Natur.
Scientific classification
Kingdom: Animalia
Phylum: Mollusca
Class: Cephalopoda
Cuvier, 1797
Orders

Subclass Nautiloidea

Subclass †Ammonoidea

Subclass Coleoidea

The cephalopods (Greek plural Κεφαλόποδα (kephalópoda); "head-foot") are the mollusc class Cephalopoda characterized by bilateral body symmetry, a prominent head, and a modification of the mollusk foot, a muscular hydrostat, into the form of arms or tentacles. Teuthology, a branch of malacology, is the study of cephalopods.

The class contains two extant subclasses. In the Coleoidea, the mollusk shell has been internalized or is absent; this subclass includes the octopuses, squid, and cuttlefish. In the Nautiloidea the shell remains; this subclass includes the nautilus. There are around 786 distinct living species of Cephalopods. Two important extinct taxa are Ammonoidea, the ammonites, and Belemnoidea, the belemnites.

Cephalopods are found in all the oceans of Earth, at all depths. None of them can tolerate freshwater, but a few species tolerate more or less brackish water.

Contents

[edit] Number of species

There are still discoveries of new species of cephalopods:

  • 1998 - 703 recent species [1]
  • 2001 - 786 recent species [2]
  • 2004 - approximate guess, from 1000 to 1200 species [3]

There are many more fossil species. It is estimated there are around 11,000 extinct taxa.[4]

[edit] Nervous system and behaviour

See also: Cephalopod intelligence

Cephalopods are widely regarded as the most intelligent of the invertebrates and have well developed senses and large brains; larger than the brains of gastropods or bivalves. Except nautiluses, cephalopods have special skin cells called chromatophores that change color and are used for communication and camouflage. The nervous system of cephalopods is the most complex of the invertebrates. The giant nerve fibers of the cephalopod mantle have been a favorite experimental material of neurophysiologists for many years; their large diameter (due to lack of myelination) makes them easier to study.

Cephalopod vision is acute, and training experiments have shown that the Common Octopus can distinguish the brightness, size, shape, and horizontal or vertical orientation of objects. Cephalopods' eyes are also sensitive to the plane of polarization of light. Surprisingly in light of their ability to change color, most are probably color blind.[5] When camouflaging themselves, they use their chromatophores to change brightness and pattern according to the background they see, but their ability to match the specific color of a background probably comes from cells such as iridophores and leucophores that reflect light from the environment.[6] Evidence of color vision has been found in only one species, the Sparkling Enope Squid.[5]

[edit] Circulatory system

Cephalopods are the only molluscs with a closed circulatory system. They have two gill hearts (also known as branchial hearts) that move blood through the capillaries of the gills. A single systemic heart then pumps the oxygenated blood through the rest of the body.[7]

Like most molluscs, cephalopods use hemocyanin, a copper-containing protein, rather than hemoglobin to transport oxygen. As a result, their blood is colorless when deoxygenated and turns blue when exposed to air.[8]

[edit] Locomotion

Cephalopods move primarily by jet propulsion, a very energy-consuming way to travel compared to the tail propulsion used by fish. The relative efficiency of jet propulsion degrades with larger animals. This is probably why many species prefer to use their fins or arms for locomotion if possible. Oxygenated water is taken into the mantle cavity to the gills and through muscular contraction of this cavity, the spent water is expelled through the hyponome, created by a fold in the mantle. Motion of the cephalopods is usually backward as water is forced out anteriorly through the hyponome, but direction can be controlled somewhat by pointing it in different directions.(Campbell, Reece, & Mitchell, p.612)

Some octopus species are also able to walk along the sea bed. Squids and cuttlefish can move short distances in any direction by rippling of a flap of muscle around the mantle.

[edit] Reproduction and life cycle

With a few exceptions, Coleoidea live short lives with rapid growth. Most of the energy extracted from their food is used for growing. The penis in most male Coleoidea is a long and muscular end of the gonoduct used to transfer spermatophores to a modified arm called a hectocotylus. That in turn is used to transfer the spermatophores to the female. In species where the hectocotylus is missing, the penis is long and able to extend beyond the mantle cavity and transfers the spermatophores directly to the female. They tend towards a semelparous reproduction strategy; they lay many small eggs in one batch and die afterwards. The Nautiloidea, on the other hand, stick to iteroparity; they produce a few large eggs in each batch and live for a long time.

[edit] Evolution

The class developed during the Late Cambrian, and were during the Paleozoic and Mesozoic dominant and diverse marine life forms. Small shelly fossils such as Tommotia were previously interpreted as early cephalopods, but today these tiny fossils are recognized as sclerites of larger animals.[9] Hence, the earliest cephalopod known is Plectronoceras from the Late Cambrian Period. Early cephalopods were at the top of the food chain.

The ancient (cohort Belemnoidea) and modern (cohort Neocoleoidea) coleoids, as well as the ammonoids, all diverged from the external shelled nautiloid during the middle Paleozoic Era, between 450 and 300 million years ago. Unlike most modern cephalopods, most ancient varieties had protective shells. These shells at first were conical but later developed into curved nautiloid shapes seen in modern nautilus species. However, some of the straight-shelled nautiloids evolved into belemnites, out of which some evolved into squid and cuttlefish, and others died off. Internal shells still exist in many non-shelled living cephalopod groups but most truly shelled cephalopods, such as the ammonites, became extinct at the end of the Cretaceous.

[edit] Classification

Chambered Nautilus (Nautilus pompilius)
Chambered Nautilus (Nautilus pompilius)
Common Cuttlefish (Sepia officinalis)
Common Cuttlefish (Sepia officinalis)
Atlantic Bobtail (Sepiola atlantica)
Atlantic Bobtail (Sepiola atlantica)
European Squid (Loligo vulgaris)
European Squid (Loligo vulgaris)
Common Octopus (Octopus vulgaris)
Common Octopus (Octopus vulgaris)

The classification as listed here (and on other cephalopod articles) follows largely from Current Classification of Recent Cephalopoda (May 2001), plus fossil groups from several sources. The three subclasses are traditional, corresponding to the three orders of cephalopods recognized by Bather (1888b). Parentheses indicate extinct groups.

Class Cephalopoda

Other classifications differ, primarily in how the various decapod orders are related, and whether they should be orders or families.

[edit] Shevyrev classification

Shevyrev (2005) suggested a division into eight subclasses, mostly comprising the more diverse and numerous fossil forms.

Class Cephalopoda Cuvier 1795

  • Subclass Ellesmeroceratoidea Flower 1950
  • Subclass Endoceratoidea Teichert, 1933
  • Subclass Actinoceratoidea Teichert, 1933
  • Subclass Nautiloidea Agassiz, 1847
  • Subclass Orthoceratoidea Kuhn, 1940
  • Subclass Bactritoidea Shimansky, 1951
  • Subclass Ammonoidea Zittel, 1884
  • Subclass Coleoidea Bather, 1888

The first mention of Coleoidea appears in (Bather, 1888a) among this article's references.

[edit] Cladistic classification

Another recent system divides all cephalopods into two clades. One includes nautilus and most fossil nautiloids. The other clade (Neocephalopoda or Angusteradulata) is closer to modern coleoids, and includes belemnoids, ammonoids, and many orthocerid families. There are also stem group cephalopods of the traditional Ellesmerocerida that belong to neither clade (Berthold & Engeser, 1987; Engeser 1997).

[edit] See also

[edit] Notes

  1. ^ [updated 28-Nov-2000] [cit. 12-Dec-2003] http://www.cephbase.dal.ca/spdb/allsp.cfm
  2. ^ [updated 13-Jun-2003] [cit. 27-Feb-2005] http://www.cephbase.utmb.edu/spdb/allsp.cfm
  3. ^ Brune, R., H. (2004) Encyklopedie ulit a lastur. – Rebo Productions, Dobřejovice, 1. vydání, 336 pp., page 16. (in Czech)
  4. ^ Ivanov M., Hrdličková, S. & Gregorová, R. (2001) Encyklopedie zkamenělin. – Rebo Productions, Dobřejovice, 1. vydání, 312 pp., page 139. (in Czech)
  5. ^ a b Messenger, John B.; Roger T. Hanlon (1998). Cephalopod Behaviour. Cambridge: Cambridge University Press, 17-21. ISBN 0-521-64583-2. 
  6. ^ Hanlon and Messenger, 68.
  7. ^ Wells, M.J. (1980). "Nervous control of the heartbeat in octopus". Journal of Experimental Biology 85 (1): 112. 
  8. ^ Ghiretti-Magaldi, A.; Ghiretti, F. (October 1992). "The Pre-history of Hemocyanin. The Discovery of Copper in the Blood of Molluscs". Cellular and Molecular Life Sciences 48 (10). Birkhäuser Basel. 
  9. ^ Begtson, Stefan (1970). "The Lower Cambrian fossil Tommotia". Lethaia 3: 363–392. 

[edit] References

  • Bather, F.A. 1888a. Shell-growth in Cephalopoda (Siphonopoda). Annals and Magazine of Natural History, Series 6, Vol. 1: 298-310
  • Bather, F.A. 1888b. Professor Blake and Shell-Growth in Cephalopoda. Annals and Magazine of Natural History. Series 6, Vol. 1: 421-426.
  • Berthold, Thomas, & Engeser, Theo. 1987. Phylogenetic analysis and systematization of the Cephalopoda (Mollusca). Verhandlungen Naturwissenschaftlichen Vereins in Hamburg. (NF) 29: 187-220.
  • Engeser (1997). Fossil Nautiloidea Page. Archived from the original on 2006-09-25.
  • Felley, J., Vecchione, M., Roper, C. F. E., Sweeney, M. & Christensen, T., 2001-2003: Current Classification of Recent Cephalopoda. internet: National Museum of Natural History: Department of Systematic Biology: Invertebrate Zoology: http://www.mnh.si.edu/cephs/
  • Shevyrev, A.A. 2005. The Cephalopod Macrosystem: A Historical Review, the Present State of Knowledge, and Unsolved Problems: 1. Major Features and Overall Classification of Cephalopod Mollusks. Paleontological Journal. 39(6):606-614. Translated from Paleontologicheskii Zhurnal No. 6, 2005, 33-42.
  • Campbell, Neil A., Reece, Jane B., and Mitchell, Lawrence G.: Biology, fifth edition. Addison Wesley Longman, Inc. Menlo Park, California. 1999 ISBN 0-8053-6566-4

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