Invertebrate

Invertebrates
Temporal range: Cryogenian to Present,
Examples of invertebrates from different phyla; clockwise from top-left: Chrysaora fuscescens (a cnidarian), Drosophila melanogaster (an arthropod), Caribbean reef squid (a mollusk), and Hirudo medicinalis (an annelid).
Scientific classification
(unranked): Filozoa
Kingdom: Animalia
Groups included
  • All animal groups not in subphylum Vertebrata

Invertebrates are a paraphyletic group of animals that neither possess nor develop a vertebral column (commonly known as a backbone or spine), derived from the notochord. This is a grouping including all animals apart from the chordate subphylum Vertebrata. Familiar examples of invertebrates include arthropods, mollusks, annelids, echinoderms and cnidarians.

The majority of animal species are invertebrates; one estimate puts the figure at 97%.[1] Many invertebrate taxa have a greater number and variety of species than the entire subphylum of Vertebrata.[2] Invertebrates vary widely in size, from 50 μm (0.002 in) rotifers[3] to the 9–10 m (30–33 ft) colossal squid.[4]

Some so-called invertebrates, such as the Tunicata and Cephalochordata, are more closely related to vertebrates than to other invertebrates. This makes the invertebrates paraphyletic, so the term has little meaning in taxonomy.

Etymology

The word "invertebrate" comes from the Latin word vertebra, which means a joint in general, and sometimes specifically a joint from the spinal column of a vertebrate. The jointed aspect of vertebra is derived from the concept of turning, expressed in the root verto or vorto, to turn.[5] The prefix in- means "not" or "without".[6]

Taxonomic significance

The term invertebrates is not always precise among non-biologists since it does not accurately describe a taxon in the same way that Arthropoda, Vertebrata or Manidae do. Each of these terms describes a valid taxon, phylum, subphylum or family. "Invertebrata" is a term of convenience, not a taxon; it has very little circumscriptional significance except within the Chordata. The Vertebrata as a subphylum comprises such a small proportion of the Metazoa that to speak of the kingdom Animalia in terms of "Vertebrata" and "Invertebrata" has limited practicality. In the more formal taxonomy of Animalia other attributes that logically should precede the presence or absence of the vertebral column in constructing a cladogram, for example, the presence of a notochord. That would at least circumscribe the Chordata. However, even the notochord would be a less fundamental criterion than aspects of embryological development and symmetry[7] or perhaps bauplan.[8]

Despite this, the concept of invertebrates as a taxon of animals has persisted for over a century among the laity,[9] and within the zoological community and in its literature it remains in use as a term of convenience for animals that are not members of the Vertebrata.[10] The following text reflects earlier scientific understanding of the term and of those animals which have constituted it. According to this understanding, invertebrates do not possess a skeleton of bone, either internal or external. They include hugely varied body plans. Many have fluid-filled, hydrostatic skeletons, like jellyfish or worms. Others have hard exoskeletons, outer shells like those of insects and crustaceans. The most familiar invertebrates include the Protozoa, Porifera, Coelenterata, Platyhelminthes, Nematoda, Annelida, Echinodermata, Mollusca and Arthropoda. Arthropoda include insects, crustaceans and arachnids.

Number of extant species

By far the largest number of described invertebrate species are insects. The following table lists the number of described extant species for major invertebrate groups as estimated in the IUCN Red List of Threatened Species, 2014.3.[11]

Invertebrate group Phylum Image Estimated number of
described species[11]
Insects Arthropoda 1,000,000
Arachnids Arthropoda 102,248
Snails Mollusca 85,000
Crustaceans Arthropoda 47,000
Clams Mollusca 20,000
Corals Cnidaria 2,175
Octopi/Squid Mollusca 900
Velvet worms Onychophora 165
Nautilus Mollusca 6
Horseshoe crabs Arthropoda 4
Others
jellyfish, echinoderms,
sponges, other worms etc.
68,658
Total: ~1,300,000

The IUCN estimates that 66,178 extant vertebrate species have been described,[11] which means that over 95% of the described animal species in the world are invertebrates.

Characteristics

The trait that is common to all invertebrates is the absence of a vertebral column (backbone): this creates a distinction between invertebrates and vertebrates. The distinction is one of convenience only; it is not based on any clear biologically homologous trait, any more than the common trait of having wings functionally unites insects, bats, and birds, or than not having wings unites tortoises, snails and sponges. Being animals, invertebrates are heterotrophs, and require sustenance in the form of the consumption of other organisms. With a few exceptions, such as the Porifera, invertebrates generally have bodies composed of differentiated tissues. There is also typically a digestive chamber with one or two openings to the exterior.

Morphology and symmetry

The body plans of most multicellular organisms exhibit some form of symmetry, whether radial, bilateral, or spherical. A minority, however, exhibit no symmetry. One example of asymmetric invertebrates includes all gastropod species. This is easily seen in snails and sea snails, which have helical shells. Slugs appear externally symmetrical, but their pneumostome (breathing hole) is located on the right side. Other gastropods develop external asymmetry, such as Glaucus atlanticus that develops asymmetrical cerata as they mature. The origin of gastropod asymmetry is a subject of scientific debate.[12]

Other examples of asymmetry are found in fiddler crabs and hermit crabs. They often have one claw much larger than the other. If a male fiddler loses its large claw, it will grow another on the opposite side after moulting. Sessile animals such as sponges are asymmetrical[13] alongside coral colonies (with the exception of the individual polyps that exhibit radial symmetry); alpheidae claws that lack pincers; and some copepods, polyopisthocotyleans, and monogeneans which parasitize by attachment or residency within the gill chamber of their fish hosts).

Nervous system

Neurons differ in invertebrates from mammalian cells. Invertebrates cells fire in response to similar stimuli as mammals, such as tissue trauma, high temperature, or changes in pH. The first invertebrate in which a neuron cell was identified was the medicinal leech, Hirudo medicinalis.[14][15]

Learning and memory using nociceptors in the sea hare, Aplysia has been described.[16][17][18] Mollusk neurons are able to detect increasing pressures and tissue trauma.[19]

Neurons have been identified in a wide range of invertebrate species, including annelids, molluscs, nematodes and arthropods.[20][21]

Respiratory system

Tracheal system of dissected cockroach. The largest tracheae run across the width of the body of the cockroach and are horizontal in this image. Scale bar, 2 mm.
The tracheal system branches into progressively smaller tubes, here supplying the crop of the cockroach. Scale bar, 2.0 mm.

One type of invertebrate respiratory system is the open respiratory system composed of spiracles, tracheae, and tracheoles that terrestrial arthropods have to transport metabolic gases to and from tissues.[22] The distribution of spiracles can vary greatly among the many orders of insects, but in general each segment of the body can have only one pair of spiracles, each of which connects to an atrium and has a relatively large tracheal tube behind it. The tracheae are invaginations of the cuticular exoskeleton that branch (anastomose) throughout the body with diameters from only a few micrometres up to 0.8 mm. The smallest tubes, tracheoles, penetrate cells and serve as sites of diffusion for water, oxygen, and carbon dioxide. Gas may be conducted through the respiratory system by means of active ventilation or passive diffusion. Unlike vertebrates, insects do not generally carry oxygen in their haemolymph.[23]

A tracheal tube may contain ridge-like circumferential rings of taenidia in various geometries such as loops or helices. In the head, thorax, or abdomen, tracheae may also be connected to air sacs. Many insects, such as grasshoppers and bees, which actively pump the air sacs in their abdomen, are able to control the flow of air through their body. In some aquatic insects, the tracheae exchange gas through the body wall directly, in the form of a gill, or function essentially as normal, via a plastron. Note that despite being internal, the tracheae of arthropods are shed during moulting (ecdysis).[24]

Reproduction

Like vertebrates, most invertebrates reproduce at least partly through sexual reproduction. They produce specialized reproductive cells that undergo meiosis to produce smaller, motile spermatozoa or larger, non-motile ova.[25] These fuse to form zygotes, which develop into new individuals.[26] Others are capable of asexual reproduction, or sometimes, both methods of reproduction.

Social interaction

Social behavior is widespread in invertebrates, including cockroaches, termites, aphids, thrips, ants, bees, Passalidae, Acari, spiders, and more.[27] Social interaction is particularly salient in eusocial species but applies to other invertebrates as well.

Insects recognize information transmitted by other insects.[28][29][30]

Phyla

The fossil coral Cladocora from the Pliocene of Cyprus

The term invertebrates covers several phyla. One of these are the sponges (Porifera). They were long thought to have diverged from other animals early.[31] They lack the complex organization found in most other phyla.[32] Their cells are differentiated, but in most cases not organized into distinct tissues.[33] Sponges typically feed by drawing in water through pores.[34] Some speculate that sponges are not so primitive, but may instead be secondarily simplified.[35] The Ctenophora and the Cnidaria, which includes sea anemones, corals, and jellyfish, are radially symmetric and have digestive chambers with a single opening, which serves as both the mouth and the anus.[36] Both have distinct tissues, but they are not organized into organs.[37] There are only two main germ layers, the ectoderm and endoderm, with only scattered cells between them. As such, they are sometimes called diploblastic.[38]

The Echinodermata are radially symmetric and exclusively marine, including starfish (Asteroidea), sea urchins, (Echinoidea), brittle stars (Ophiuroidea), sea cucumbers (Holothuroidea) and feather stars (Crinoidea).[39]

The largest animal phylum is also included within invertebrates: the Arthropoda, including insects, spiders, crabs, and their kin. All these organisms have a body divided into repeating segments, typically with paired appendages. In addition, they possess a hardened exoskeleton that is periodically shed during growth.[40] Two smaller phyla, the Onychophora and Tardigrada, are close relatives of the arthropods and share these traits. The Nematoda or roundworms, are perhaps the second largest animal phylum, and are also invertebrates. Roundworms are typically microscopic, and occur in nearly every environment where there is water.[41] A number are important parasites.[42] Smaller phyla related to them are the Kinorhyncha, Priapulida, and Loricifera. These groups have a reduced coelom, called a pseudocoelom. Other invertebrates include the Nemertea or ribbon worms, and the Sipuncula.

Another phylum is Platyhelminthes, the flatworms.[43] These were originally considered primitive, but it now appears they developed from more complex ancestors.[44] Flatworms are acoelomates, lacking a body cavity, as are their closest relatives, the microscopic Gastrotricha.[45] The Rotifera or rotifers, are common in aqueous environments. Invertebrates also include the Acanthocephala or spiny-headed worms, the Gnathostomulida, Micrognathozoa, and the Cycliophora.[46]

Also included are two of the most successful animal phyla, the Mollusca and Annelida.[47][48] The former, which is the second-largest animal phylum by number of described species, includes animals such as snails, clams, and squids, and the latter comprises the segmented worms, such as earthworms and leeches. These two groups have long been considered close relatives because of the common presence of trochophore larvae, but the annelids were considered closer to the arthropods because they are both segmented.[49] Now, this is generally considered convergent evolution, owing to many morphological and genetic differences between the two phyla.[50]

Among lesser phyla of invertebrates are the Hemichordata, or acorn worms,[51] and the Chaetognatha, or arrow worms. Other phyla include Acoelomorpha, Brachiopoda, Bryozoa, Entoprocta, Phoronida, and Xenoturbellida.

Classification of invertebrates

Invertebrates can be classified into several main categories, some of which are taxonomically obsolescent or debatable, but still used as terms of convenience. Each however appears in its own article at the following links.[52]

History

The earliest animal fossils appear to be those of invertebrates. 665-million-year-old fossils in the Trezona Formation at Trezona Bore, West Central Flinders, South Australia have been interpreted as being early sponges.[53] Some paleontologists suggest that animals appeared much earlier, possibly as early as 1 billion years ago[54] though they probably became multicellular in the Tonian. Trace fossils such as tracks and burrows found in the late Neoproterozoic era indicate the presence of triploblastic worms, roughly as large (about 5 mm wide) and complex as earthworms.[55]

Around 453 MYA, animals began diversifying, and many of the important groups of invertebrates diverged from one another. Fossils of invertebrates are found in various types of sediment from the Phanerozoic.[56] Fossils of invertebrates are commonly used in stratigraphy.[57]

Classification

Carl Linnaeus divided these animals into only two groups, the Insecta and the now-obsolete Vermes (worms). Jean-Baptiste Lamarck, who was appointed to the position of "Curator of Insecta and Vermes" at the Muséum National d'Histoire Naturelle in 1793, both coined the term "invertebrate" to describe such animals and divided the original two groups into ten, by splitting Arachnida and Crustacea from the Linnean Insecta, and Mollusca, Annelida, Cirripedia, Radiata, Coelenterata and Infusoria from the Linnean Vermes. They are now classified into over 30 phyla, from simple organisms such as sea sponges and flatworms to complex animals such as arthropods and molluscs.

Significance of the group

Invertebrates are animals without a vertebral column. This has led to the conclusion that invertebrates are a group that deviates from the normal, vertebrates. This has been said to be because researchers in the past, such as Lamarck, viewed vertebrates as a "standard": in Lamarck's theory of evolution, he believed that characteristics acquired through the evolutionary process involved not only survival, but also progression toward a "higher form", to which humans and vertebrates were closer than invertebrates were. Although goal-directed evolution has been abandoned, the distinction of invertebrates and vertebrates persists to this day, even though the grouping has been noted to be "hardly natural or even very sharp." Another reason cited for this continued distinction is that Lamarck created a precedent through his classifications which is now difficult to escape from. It is also possible that some humans believe that, they themselves being vertebrates, the group deserves more attention than invertebrates.[58] In any event, in the 1968 edition of Invertebrate Zoology, it is noted that "division of the Animal Kingdom into vertebrates and invertebrates is artificial and reflects human bias in favor of man's own relatives." The book also points out that the group lumps a vast number of species together, so that no one characteristic describes all invertebrates. In addition, some species included are only remotely related to one another, with some more related to vertebrates than other invertebrates (see Paraphyly).[59]

In research

For many centuries, invertebrates were neglected by biologists, in favor of big vertebrates and "useful" or charismatic species.[60] Invertebrate biology was not a major field of study until the work of Linnaeus and Lamarck in the 18th century.[60] During the 20th century, invertebrate zoology became one of the major fields of natural sciences, with prominent discoveries in the fields of medicine, genetics, palaeontology, and ecology.[60] The study of invertebrates has also benefited law enforcement, as arthropods, and especially insects, were discovered to be a source of information for forensic investigators.[40]

Two of the most commonly studied model organisms nowadays are invertebrates: the fruit fly Drosophila melanogaster and the nematode Caenorhabditis elegans. They have long been the most intensively studied model organisms, and were among the first life-forms to be genetically sequenced. This was facilitated by the severely reduced state of their genomes, but many genes, introns, and linkages have been lost. Analysis of the starlet sea anemone genome has emphasised the importance of sponges, placozoans, and choanoflagellates, also being sequenced, in explaining the arrival of 1500 ancestral genes unique to animals.[61] Invertebrates are also used by scientists in the field of aquatic biomonitoring to evaluate the effects of water pollution and climate change.[62]

See also

  • Invertebrate zoology
  • Invertebrate paleontology
  • Marine invertebrates
  • Pain in invertebrates

References

  1. May, Robert M. (16 September 1988). "How Many Species Are There on Earth?". Science. 241 (4872): 1441–1449. Bibcode:1988Sci...241.1441M. doi:10.1126/science.241.4872.1441. JSTOR 1702670. PMID 17790039. S2CID 34992724. Archived from the original on 15 November 2016. Retrieved 17 June 2014.
  2. Richards, O. W.; Davies, R.G. (1977). Imms' General Textbook of Entomology: Volume 1: Structure, Physiology and Development Volume 2: Classification and Biology. Berlin: Springer. ISBN 978-0-412-61390-6.
  3. Howey, Richard L. (1999). "Welcome to the Wonderfully Weird World of Rotifers". Micscape Magazine. Retrieved 19 February 2010.
  4. Roper, C.F.E. & P. Jereb (2010). Family Cranchiidae. In: P. Jereb & C.F.E. Roper (eds.) Cephalopods of the world. An annotated and illustrated catalogue of species known to date. Volume 2. Myopsid and Oegopsid Squids. FAO Species Catalogue for Fishery Purposes No. 4, Vol. 2. FAO, Rome. pp. 148–178.
  5. Tucker, T. G. (1931). A Concise Etymological Dictionary of Latin. Halle (Saale): Max Niemeyer Verlag.
  6. Skeat, Walter William (1882). An etymological dictionary of the English language. Clarendon Press. p. 301.
  7. Pechenik, Jan (1996). Biology of the Invertebrates. Dubuque: Wm. C. Brown Publishers. ISBN 978-0-697-13712-8.
  8. Brusca, Richard C.; Brusca, Gary J. (1990). Invertebrates. Sunderland: Sinauer Associates. ISBN 978-0-87893-098-2.
  9. Brown, Lesley (1993). The New shorter Oxford English dictionary on historical principles. Oxford [Eng.]: Clarendon. ISBN 978-0-19-861271-1.
  10. Louis Agassiz (21 March 2013). Essay on Classification. Courier Corporation. pp. 115–. ISBN 978-0-486-15135-9.
  11. The World Conservation Union. 2014. IUCN Red List of Threatened Species, 2014.3. Summary Statistics for Globally Threatened Species. Table 1: Numbers of threatened species by major groups of organisms (1996–2014).
  12. Louise R. Page (2006). "Modern insights on gastropod development: Reevaluation of the evolution of a novel body plan". Integrative and Comparative Biology. 46 (2): 134–143. doi:10.1093/icb/icj018. PMID 21672730.
  13. Symmetry, biological, cited at FactMonster.com from The Columbia Electronic Encyclopedia (2007).
  14. Nicholls, J.G. and Baylor, D.A., (1968). Specific modalities and receptive fields of sensory neurons in CNS of the leech. Journal of Neurophysiology, 31: 740–756
  15. Pastor, J., Soria, B. and Belmonte, C., (1996). Properties of the nociceptive neurons of the leech segmental ganglion. Journal of Neurophysiology, 75: 2268–2279
  16. Byrne, J.H., Castellucci, V.F. and Kandel, E.R., (1978). Contribution of individual mechanoreceptor sensory neurons to defensive gill-withdrawal reflex in Aplysia. Journal of Neurophysiology, 41: 418–431
  17. Castellucci, V., Pinsker, H., Kupfermann, I. and Kandel, E.R., (1970). Neuronal mechanisms of habituation and dishabituation of the gill-withdrawal reflex in Aplysia. Science, 167: 1745–1748
  18. Fischer, T.M., Jacobson, D.A., Counsell, A.N., et al., (2011). Regulation of low-threshold afferent activity may contribute to short-term habituation in Aplysia californica. Neurobiology of Learning and Memory, 95: 248-259
  19. Illich, P.A and Walters, E.T., (1997). Mechanosensory neurons innervating Aplysia siphon encode noxious stimuli and display nociceptive sensitization. The Journal of Neuroscience, 17: 459-469
  20. Eisemann, C.H., Jorgensen, W.K., Merritt, D.J., Rice, M.J., Cribb, B.W., Webb, P.D. and Zalucki, M.P., (1984). "Do insects feel pain? — A biological view". Cellular and Molecular Life Sciences, 40: 1420–1423
  21. St John Smith, E. and Lewin, G.R., (2009). Nociceptors: a phylogenetic view. Journal of Comparative Physiology A, 195: 1089-1106
  22. Wasserthal, Lutz T. (1998). Chapter 25: The Open Hemolymph System of Holometabola and Its Relation to the Tracheal Space. In "Microscopic Anatomy of Invertebrates". Wiley-Liss, Inc. ISBN 0-471-15955-7.
  23. Westneat, Mark W.; Betz, Oliver; Blob, Richard W.; Fezzaa, Kamel; Cooper, James W.; Lee, Wah-Keat (January 2003). "Tracheal Respiration in Insects Visualized with Synchrotron X-ray Imaging". Science. 299 (5606): 558–560. Bibcode:2003Sci...299..558W. doi:10.1126/science.1078008. PMID 12543973. S2CID 43634044.
  24. Ewer, John (11 October 2005). "How the Ecdysozoan Changed Its Coat". PLOS Biology. 3 (10): e349. doi:10.1371/journal.pbio.0030349. ISSN 1545-7885. PMC 1250302. PMID 16207077.
  25. Schwartz, Jill (2010). Master the GED 2011 (w/CD). Peterson's. p. 371. ISBN 978-0-7689-2885-3.
  26. Hamilton, Matthew B. (2009). Population genetics. Wiley-Blackwell. p. 55. ISBN 978-1-4051-3277-0.
  27. The Evolution of Social Behavior in Insects and Arachnids. Cambridge University Press. 1997. ISBN 978-0521589772.
  28. Riley, J.; Greggers, U.; Smith, A.; Reynolds, D.; Menzel, R. (2005). "The flight paths of honeybees recruited by the waggle dance". Nature. 435 (7039): 205–207. Bibcode:2005Natur.435..205R. doi:10.1038/nature03526. PMID 15889092. S2CID 4413962.
  29. Seeley T.D.; Visscher P.K.; Passino K.M. (2006). "Group decision making in honey bee swarms". American Scientist. 94 (3): 220–229. doi:10.1511/2006.3.220.
  30. Frisch, Karl von. (1967) The Dance Language and Orientation of Bees. Cambridge, Massachusetts: The Belknap Press of Harvard University Press.
  31. Bhamrah, H. S.; Kavita Juneja (2003). An Introduction to Porifera. Anmol Publications PVT. LTD. p. 58. ISBN 978-81-261-0675-2.
  32. Sumich, James L. (2008). Laboratory and Field Investigations in Marine Life. Jones & Bartlett Learning. p. 67. ISBN 978-0-7637-5730-4.
  33. Jessop, Nancy Meyer (1970). Biosphere; a study of life. Prentice-Hall. p. 428.
  34. Sharma, N. S. (2005). Continuity And Evolution Of Animals. Mittal Publications. p. 106. ISBN 978-81-8293-018-6.
  35. Dunn et al. 2008. "Broad phylogenomic sampling improves resolution of the animal tree of life". Nature 06614.
  36. Langstroth, Lovell; Libby Langstroth; Todd Newberry; Monterey Bay Aquarium (2000). A living bay: the underwater world of Monterey Bay. University of California Press. p. 244. ISBN 978-0-520-22149-9.
  37. Safra, Jacob E. (2003). The New Encyclopædia Britannica, Volume 16. Encyclopædia Britannica. p. 523. ISBN 978-0-85229-961-6.
  38. Kotpal, R. L. (2012). Modern Text Book of Zoology: Invertebrates. Rastogi Publications. p. 184. ISBN 978-81-7133-903-7.
  39. Alcamo, Edward (1998). Biology Coloring Workbook. The Princeton Review. p. 220. ISBN 978-0-679-77884-4.
  40. Gunn, Alan (2009). Essential forensic biology. John Wiley and Sons. p. 214. ISBN 978-0-470-75804-5.
  41. Prewitt, Nancy L.; Larry S. Underwood; William Surver (2003). BioInquiry: making connections in biology. John Wiley. p. 289. ISBN 978-0-471-20228-8.
  42. Schmid-Hempel, Paul (1998). Parasites in social insects. Princeton University Press. p. 75. ISBN 978-0-691-05924-2.
  43. Gilson, Étienne (2004). El espíritu de la filosofía medieval. Ediciones Rialp. p. 384. ISBN 978-84-321-3492-0.
  44. Ruiz-Trillo, Iñaki; Riutort, Marta; Littlewood, D. Timothy J.; Herniou, Elisabeth A.; Baguñà, Jaume (March 1999). "Acoel Flatworms: Earliest Extant Bilaterian Metazoans, Not Members of Platyhelminthes". Science. 283 (5409): 1919–1923. Bibcode:1999Sci...283.1919R. doi:10.1126/science.283.5409.1919. ISSN 0036-8075. PMID 10082465. S2CID 6079655.
  45. Todaro, Antonio. "Gastrotricha: Overview". Gastrotricha: World Portal. University of Modena & Reggio Emilia. Retrieved 26 January 2008.
  46. Kristensen, Reinhardt Møbjerg (July 2002). "An Introduction to Loricifera, Cycliophora, and Micrognathozoa". Integrative and Comparative Biology. 42 (3): 641–651. doi:10.1093/icb/42.3.641. PMID 21708760.
  47. "Biodiversity: Mollusca". The Scottish Association for Marine Science. Archived from the original on 8 July 2006. Retrieved 19 November 2007.
  48. Russell, Bruce J. (Writer), Denning, David (Writer) (2000). Branches on the Tree of Life: Annelids (VHS). BioMEDIA ASSOCIATES.
  49. Eernisse, Douglas J.; Albert, James S.; Anderson, Frank E. (1 September 1992). "Annelida and Arthropoda are not sister taxa: A phylogenetic analysis of spiralean metazoan morphology". Systematic Biology. 41 (3): 305–330. doi:10.2307/2992569. ISSN 1063-5157. JSTOR 2992569.
  50. Eernisse, Douglas J.; Kim, Chang Bae; Moon, Seung Yeo; Gelder, Stuart R.; Kim, Won (September 1996). "Phylogenetic Relationships of Annelids, Molluscs, and Arthropods Evidenced from Molecules and Morphology". Journal of Molecular Evolution. 43 (3): 207–215. Bibcode:1996JMolE..43..207K. doi:10.1007/PL00006079. PMID 8703086.
  51. Tobin, Allan J.; Jennie Dusheck (2005). Asking about life. Cengage Learning. p. 497. ISBN 978-0-534-40653-0.
  52. "What Are the Main Groups of Invertebrates?". 4 August 2015.
  53. Maloof, Adam C.; Rose, Catherine V.; Beach, Robert; Samuels, Bradley M.; Calmet, Claire C.; Erwin, Douglas H.; Poirier, Gerald R.; Yao, Nan; Simons, Frederik J. (17 August 2010). "Possible animal-body fossils in pre-Marinoan limestones from South Australia". Nature Geoscience. 3 (9): 653. Bibcode:2010NatGe...3..653M. doi:10.1038/ngeo934.
  54. Campbell. Neil A.; Jane B. Reece (2005). Biology (7 ed.). Pearson, Benjamin Cummings. p. 526. ISBN 978-0-8053-7171-0.
  55. Seilacher, A.; Bose, P.K.; Pflüger, F. (October 1998). "Animals More Than 1 Billion Years Ago: Trace Fossil Evidence from India". Science. 282 (5386): 80–83. Bibcode:1998Sci...282...80S. doi:10.1126/science.282.5386.80. ISSN 0036-8075. PMID 9756480.
  56. Clarkson, Euan Neilson Kerr (1998). Invertebrate palaeontology and evolution. Wiley-Blackwell. ISBN 978-0-632-05238-7.
  57. Kummel, Bernhard (1954). Status of invertebrate paleontology, 1953. Ayer Publishing. p. 93. ISBN 978-0-405-12715-1.
  58. Barnes, Richard Stephen Kent (2001). The Invertebrates: A Synthesis. Wiley-Blackwell. p. 3. ISBN 978-0-632-04761-1.
  59. Barnes, Robert D. (1968). Invertebrate Zoology (2nd ed.). W.B. Saunders. OCLC 173898.
  60. Ducarme, Frédéric (2015). "Why study invertebrates? A philosophical argument from Aristotle". No Bones (Smithsonian Institution website).
  61. N.H. Putnam, NH; et al. (July 2007). "Sea anemone genome reveals ancestral eumetazoan gene repertoire and genomic organization". Science. 317 (5834): 86–94. Bibcode:2007Sci...317...86P. doi:10.1126/science.1139158. ISSN 0036-8075. PMID 17615350. S2CID 9868191.
  62. Lawrence, J.E.; Lunde, K.B.; Mazor, R.D.; Bêche, L.A.; McElravy, E.P.; Resh, V.H. (2010). "Long-Term Macroinvertebrate Responses to Climate Change: Implications for Biological Assessment in Mediterranean-Climate Streams". Journal of the North American Benthological Society. 29 (4): 1424–1440. doi:10.1899/09-178.1. S2CID 84679634.

Further reading

  • Hyman, L. H. 1940. The Invertebrates (6 volumes) New York : McGraw-Hill. A classic work.
  • Anderson, D. T. (Ed.). (2001). Invertebrate zoology (2nd ed.). Oxford: Oxford University Press.
  • Brusca, R. C., & Brusca, G. J. (2003). Invertebrates (2nd ed.). Sunderland, Mass. : Sinauer Associates.
  • Miller, S.A., & Harley, J.P. (1996). Zoology (4th ed.). Boston: WCB/McGraw-Hill.
  • Pechenik, Jan A. (2005). Biology of the invertebrates. Boston: McGraw-Hill, Higher Education. pp. 590 pp. ISBN 978-0-07-234899-6.
  • Ruppert, E. E., Fox, R. S., & Barnes, R. D. (2004). Invertebrate zoology: a functional evolutionary approach. Belmont, CA: Thomas-Brooks/Cole.
  • Adiyodi, K.G. & Adyiodi, R.G. (Eds) 1983- . Reproductive Biology of Invertebrates. Wiley, New York. (Many volumes.)
  • Giese, A.G. & Pearse, J.S. (Eds) 1974- . Reproduction of Marine Invertebrates. Academic Press, New York. (Many volumes.)
  • Advances in Invertebrate Reproduction. Elsevier Science, Amsterdam. (Five volumes.)

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