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Conodont

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Template:Short description Template:Distinguish Template:Automatic taxobox Conodonts, are an extinct group of marine jawless vertebrates belonging to the class Conodonta (from Ancient Greek κῶνος (kōnos), meaning "cone", and ὀδούς (odoús), meaning "tooth"). They are primarily known from their hard, mineralised tooth-like structures called "conodont elements" that in life were present in the oral cavity and used to process food. Rare soft tissue remains suggest that they had elongate eel-like bodies with large eyes. Conodonts were a long-lasting group with over 300 million years of existence from the Cambrian (over 500 million years ago) to the beginning of the Jurassic (around 200 million years ago). Conodont elements are highly distinctive to particular species and are widely used in biostratigraphy as indicative of particular periods of geological time.

Discovery and understanding of conodontsEdit

The teeth-like fossils of the conodont were first discovered by Heinz Christian Pander and the results published in Saint Petersburg, Russia, in 1856.<ref name="Cooper, Barry J.-2008">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

It was only in the early 1980s that the first fossil evidence of the rest of the animal was found (see below). In the 1990s exquisite fossils were found in South Africa in which the soft tissue had been converted to clay, preserving even muscle fibres. The presence of muscles for rotating the eyes showed definitively that the animals were primitive vertebrates.<ref>Template:Cite journal</ref>

Nomenclature and taxonomic rankEdit

Through their history of study, "conodont" is a term which has been applied to both the individual fossils and to the animals to which they belonged. The original German term used by Pander was "conodonten", which was subsequently anglicized as "conodonts", though no formal latinized name was provided for several decades. MacFarlane (1923) described them as an order, Conodontes (a Greek translation), which Huddle (1934) altered to the Latin spelling Conodonta.<ref name="Fåhraeus-1983">Template:Cite journal</ref> A few years earlier, Eichenberg (1930) established another name for the animals responsible for conodont fossils: Conodontophorida ("conodont bearers").<ref name="Eichenberg-1930">Template:Cite journal</ref> A few other scientific names were rarely and inconsistently applied to conodonts and their proposed close relatives during 20th century, such as Conodontophoridia, Conodontophora, Conodontochordata, Conodontiformes,<ref name="Bengtson-1976">Template:Cite journal</ref> and Conodontomorpha.

Conodonta and Conodontophorida are by far the most common scientific names used to refer to conodonts, though inconsistencies regarding their taxonomic rank still persist. Bengtson (1976)'s research on conodont evolution identified three morphological tiers of early conodont-like fossils: protoconodonts, paraconodonts, and "true conodonts" (euconodonts).<ref name="Bengtson-1976" /> Further investigations revealed that protoconodonts were probably more closely related to chaetognaths (arrow worms) rather than true conodonts. On the other hand, paraconodonts are still considered a likely ancestral stock or sister group to euconodonts.

The 1981 Treatise on Invertebrate Paleontology volume on the conodonts (Part W revised, supplement 2) lists Conodonta as the name of both a phylum and a class, with Conodontophorida as a subordinate order for "true conodonts". All three ranks were attributed to Eichenberg, and Paraconodontida was also included as an order under Conodonta.<ref>Template:Cite book</ref> This approach was criticized by Fåhraeus (1983), who argued that it overlooked Pander's historical relevance as a founder and primary figure in conodontology. Fåhraeus proposed to retain Conodonta as a phylum (attributed to Pander), with the single class Conodontata (Pander) and the single order Conodontophorida (Eichenberg).<ref name="Fåhraeus-1983" /><ref>Template:Cite journal</ref> Subsequent authors continued to regard Conodonta as a phylum with an ever-increasing number of subgroups.<ref name="Sweet-1988" />

With increasingly strong evidence that conodonts lie within the phylum Chordata, more recent studies generally refer to "true conodonts" as the class Conodonta, containing multiple smaller orders.<ref name="Donoghue-2000" /><ref name="Sweet-2001">Template:Cite journal</ref><ref name="Donoghue-2008">Template:Cite journal</ref> Paraconodonts are typically excluded from the group, though still regarded as close relatives.<ref name="Donoghue-2000" /><ref name="Sweet-2001" /><ref name="Donoghue-2008" /> In practice, Conodonta, Conodontophorida, and Euconodonta are equivalent terms and are used interchangeably.

Conodont elementsEdit

For a long time, the function and arrangement of conodont elements was enigmatic, since the whole animal was soft-bodied, with the sole exception of the mineralized elements. Upon the conodont animal's demise, the soft tissues would decompose and the individual conodont elements would separate. However, in instances of exceptional preservation the conodont elements may be recovered in articulation.<ref name="Liu">Template:Cite journal</ref> By closely observing these rare specimens, Briggs et al. (1983)<ref name="Briggs-1983" /> were able to for the first time study the anatomy of the complexes formed by the conodont elements arranged as they were in life. Other researchers have continued to revise and reinterpret this initial description.<ref name="Aldridge">Template:Cite journal</ref><ref name=":0" /><ref name="Goudemand">Template:Cite journal</ref>

Lone elementsEdit

Conodont elements consist of mineralised teeth-like structures of varying morphology and complexity. The evolution of mineralized tissues has been puzzling for more than a century. It has been hypothesized that the first mechanism of chordate tissue mineralization began either in the oral skeleton of conodonts or the dermal skeleton of early agnathans.

The element array constituted a feeding apparatus that is radically different from the jaws of modern animals. They are now termed "conodont elements" to avoid confusion. The three forms of teeth, i.e., coniform cones, ramiform bars, and pectiniform platforms, probably performed different functions.

For many years, conodonts were known only from enigmatic tooth-like microfossils (200 micrometers to 5 millimeters in length<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>), which occur commonly, but not always, in isolation and were not associated with any other fossil. Until the early 1980s, conodont teeth had not been found in association with fossils of the host organism, in a konservat lagerstätte.<ref name="Briggs-1983">Template:Cite journal</ref> This is because the conodont animal was soft-bodied, thus everything but the teeth was unsuited for preservation under normal circumstances.

These microfossils are made of hydroxylapatite (a phosphatic mineral).<ref>Template:Cite journal</ref> The conodont elements can be extracted from rock using adequate solvents.<ref>Template:Cite journal</ref><ref>Template:Cite book</ref><ref>Template:Cite journal</ref>

They are widely used in biostratigraphy. Conodont elements are also used as paleothermometers, a proxy for thermal alteration in the host rock, because under higher temperatures, the phosphate undergoes predictable and permanent color changes, measured with the conodont alteration index. This has made them useful for petroleum exploration where they are known, in rocks dating from the Cambrian to the Late Triassic.

Full apparatusEdit

  • Hindeodus elements.jpg

    Complete element set of the conodont Hindeodus parvus

  • Archeognathus primus.png

    Preserved articulated association of conodont elements belonging to the species Archeognathus primus (Ordovician, North America)

The conodont apparatus may comprise a number of discrete elements, including the spathognathiform, ozarkodiniform, trichonodelliform, neoprioniodiform, and other forms.<ref>Template:Cite journal</ref>

In the 1930s, the concept of conodont assemblages was described by Hermann Schmidt<ref>Template:Cite journal</ref> and by Harold W. Scott in 1934.<ref>Harold W. Scott, "The Zoological Relationships of the Conodonts. Journal of Paleontology, Vol. 8, No. 4 (Dec., 1934), pages 448-455 (Stable URL)</ref><ref>Template:Cite journal</ref><ref>Template:Cite journal</ref><ref>Template:Cite journal</ref>

Element typesEdit

File:Manticolepis subrecta.jpg
Model of elements of Manticolepis subrecta – a conodont from the Upper Frasnian of Poland – photography taken in the Geological Museum of the Polish Geological Institute in Warsaw

The arrangement of elements in ozarkodinids and other complex conodonts was first reconstructed from extremely well-preserved taxa by Briggs et al. (1983),<ref name="Briggs-1983" /> although loosely articulated conodont elements are reported as early as 1971.<ref name=":1">Template:Cite journal</ref> Conodont elements are organized into three different groups based upon shape. These groups of shapes are termed S, M, and P elements.<ref name=":0">Template:Cite journal</ref>

The S and M elements are ramiform, elongate, and comb-like structures.<ref name="Aldridge" /> An individual element has a single row of many cusps running down the midline along its top side. These conodont elements are arranged towards the animal's anterior oral surface, forming an interlocking basket of cusps within the mouth. Cusp may point out towards the head of the animal, or back towards the tail.<ref name="Goudemand" /> The number of S and M elements present as well as the direction they point may vary by taxonomic group. M (makellate) elements have a higher position in the mouth and commonly form a symmetrical shape akin to a horseshoe or pick.<ref name="Briggs-1983" /> S elements are further divided into three subtypes:

  • Sa element - an unpaired symmetrical ramiform structure at the front of the mouth. Sometimes known as an S0 element.
  • Sb element - paired asymmetrical structures
  • Sc element - paired highly asymmetrical, bipennate structures

In P elements, a pectiniform (comb-shaped) row of cusps transitions into a broad flat or ridged platform moving towards the base of the element.<ref name="Briggs-1983" /> Platforms and cusps are only found along one side of the structure. Individual elements oriented vertically and arranged in pairs, with platforms and cusps pointing towards the animal's midline. They occur deeper in the throat than the S and M elements. P elements are further divided into two subtypes:

  • Pa element - blade-like structures
  • Pb element - arched structures

The conodont animalEdit

  • Promissum NT small.jpg

    Life restoration of Promissum pulchrum

  • Panderodus.png

    Restoration of Panderodus unicostatus

  • A body fossil of a Panderodus unicostatus (Branson & Mehl, 1933) from the Waukesha Lagerstätte of Wisconsin, USA.png

    A body fossil of Panderodus unicostatus

  • Conodont species size comparison.png

    A size comparison of the three conodont species with preserved body fossils.

  • Typhloesus fossils 2022.jpg

    Fossils of Typhloesus, at one time considered the first conodont body fossil.

Although conodont elements are abundant in the fossil record, fossils preserving soft tissues of conodont animals are known from only a few deposits in the world. One of the first possible body fossils of a conodont were those of Typhloesus, an enigmatic animal known from the Bear Gulch limestone in Montana.<ref name="Conway Morris-1990">Template:Cite journal</ref> This possible identification was based on the presence of conodont elements with the fossils of Typhloesus. This claim was disproved, however, as the conodont elements were actually in the creature's digestive area.<ref name="Conway Morris-2022">Template:Cite journal</ref> That animal is now regarded as a possible mollusk related to gastropods.<ref name="Conway Morris-2022" /> As of 2023, there are only three described species of conodonts that have preserved trunk fossils: Clydagnathus windsorensis from the Carboniferous aged Granton Shrimp Bed in Scotland, Promissum pulchrum from the Ordovician aged Soom Shale in South Africa, and Panderodus unicostatus from the Silurian aged Waukesha Biota in Wisconsin.<ref name="Donoghue-2000" /><ref name="Murdock-2021">Template:Cite journal</ref><ref name="Gabbott-1995">Template:Cite journal</ref> There are other examples of conodont animals that only preserve the head region, including eyes, of the animals known from the Silurian aged Eramosa site in Ontario and Triassic aged Akkamori section in Japan.<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref>

According to these fossils, conodonts had large eyes, fins with fin rays, chevron-shaped muscles and axial line, which were interpreted as notochord or the dorsal nerve cord.<ref name="Murdock-2021" /><ref>Template:Cite book</ref> While Clydagnathus and Panderodus had lengths only reaching Template:Cvt, Promissum is estimated to reach Template:Cvt in length, if it had the same proportions as Clydagnathus.<ref name="Murdock-2021" /><ref name="Gabbott-1995" />

EcologyEdit

DietEdit

Because they are associated with the oral region of the conodont animal, it is accepted that conodont elements are used in the acquisition of food. Two primary hypotheses have arisen as to how this is accomplished. One hypothesis proposed that elements acted as support structures for filamentous soft-tissues.<ref name="Nicoli">Template:Cite journal</ref><ref name=":1" /> These small filaments (cilia) would be used to filter small planktonic organisms out of the water column, analogous to the cnidoblast cells of a coral or the lophophore of a brachiopod.

Another hypothesis contests that the conodont elements were used to actively catch and process prey.<ref name=":1" /><ref name="Goudemand" /> S and M elements could have been independently movable, allowing prey to be captured in the oral region of the animal. Modern hagfish and lampreys scrape at flesh using keratinous blades supported by a simple but effective pulley-like system, involving a string of muscles around a cartilaginous core. An equivalent system might have been present in conodonts.<ref name="Goudemand" /> S and M elements would be able to open and close at will to firmly grasp or pinch at prey, before rotating back to consume the prey element. The blade-like P elements deeper in the throat would process the food by slicing against their counterparts like a pair of scissors,<ref name="Goudemand" /> or grinding against each other like molar teeth.

Current consensus supports the latter hypothesis in which elements are used for predation, not suspension feeding.<ref name="Gabbott-1995" /> One line of evidence for this includes the isometric growth pattern exhibited by S, M, and P elements.<ref name=":1" /> If the conodont animal relied upon a filter feeding strategy then this growth pattern would not provide the necessary surface area needed to support ciliated tissue as the animal grew. There is some evidence for cartilaginous structures similar to those present in modern jawless fish, which are both predators and scavengers.<ref name="Goudemand" /> Wear on some conodont elements suggests that they functioned like teeth, with both wear marks likely created by food as well as by occlusion with other elements.<ref name="Gabbott-1995" /><ref name="Terrill-2022">Template:Cite journal</ref>

It is possible that multiple feeding strategies may have arisen in different groups of conodonts, as they are a diverse clade. A 2009 paper suggested that the genus Panderodus may have utilized venom in the acquisition of prey.<ref name="Szaniawski">Template:Cite journal</ref> Evidence of longitudinal grooves are present on some conodont elements associated with the feeding apparatus of this particular animal. These sorts of grooves are analogous to those present in some extant groups of venomous vertebrates.

LifestyleEdit

Studies have concluded that conodonts taxa occupied both pelagic (open ocean) and nektobenthic (swimming above the sediment surface) niches.<ref name="Terrill-2022" /> The preserved musculature suggests that some conodonts (Promissum at least) were efficient cruisers, but incapable of bursts of speed.<ref name="Gabbott-1995" /> Based on isotopic evidence, some Devonian conodonts have been proposed to have been low-level consumers that fed on zooplankton.<ref name="Terrill-2022" />

A study on the population dynamics of Alternognathus has been published. Among other things, it demonstrates that at least this taxon had short lifespans lasting around a month.<ref>Template:Cite journal</ref> A study Sr/Ca and Ba/Ca ratios of a population of conodonts from a carbonate platform from the Silurian of Sweden found that the different conodont species and genera likely occupied different trophic niches.<ref name="Terrill-2022" />

Classification and phylogenyEdit

AffinitiesEdit

Template:As of, scientists classify the conodonts in the phylum Chordata on the basis of their fins with fin rays, chevron-shaped muscles and notochord.<ref name="Briggs-1992">Template:Cite journal</ref>

Milsom and Rigby envision them as vertebrates similar in appearance to modern hagfish and lampreys,<ref name="Milsom-2004">Template:Cite book</ref> and phylogenetic analysis suggests they are more derived than either of these groups.<ref name="Donoghue-2000">Template:Cite journal</ref> However, this analysis comes with one caveat: the earliest conodont-like fossils, the protoconodonts, appear to form a distinct clade from the later paraconodonts and euconodonts. Protoconodonts are probably not relatives of true conodonts, but likely represent a stem group to Chaetognatha, an unrelated phylum that includes arrow worms.<ref name="Szaniawski, H.-2002">Template:Cite journal</ref>

Moreover, some analyses do not regard conodonts as either vertebrates or craniates, because they lack the main characteristics of these groups.<ref name="Nowlan-2010">Template:Cite journal</ref> More recently it has been proposed that conodonts may be stem-cyclostomes, more closely related to hagfish and lampreys than to jawed vertebrates, based on similarities in the shape of their fins, and the idea that the conodont elements may be homologous with lamprey and hagfish tooth plates.<ref>Template:Cite journal</ref>

Ingroup relationsEdit

Individual conodont elements are difficult to classify in a consistent manner, but an increasing number of conodont species are now known from multi-element assemblages, which offer more data to infer how different conodont lineages are related to each other. The following is a simplified cladogram based on Sweet and Donoghue (2001),<ref name="Sweet-2001" /> which summarized previous work by Sweet (1988)<ref name="Sweet-1988" /> and Donoghue et al. (2000):<ref name="Donoghue-2000" />

Template:CladeOnly a few studies approach the question of conodont ingroup relationships from a cladistic perspective, as informed by phylogenetic analyses. One of the broadest studies of this nature was the analysis of Donoghue et al. (2008), which focused on "complex" conodonts (Prioniodontida and other descendant groups):<ref name="Donoghue-2008" />

Evolutionary historyEdit

File:Conodonts.jpg
Conodont elements from the Deer Valley Member of the Mauch Chunk Formation in Pennsylvania, Maryland, and West Virginia, US
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The earliest fossils of conodonts are known from the Cambrian period. Conodonts extensively diversified during the early Ordovician, reaching their apex of diversity during the middle part of the period, and experienced a sharp decline during the late Ordovician and Silurian, before reaching another peak of diversity during the mid-late Devonian. Conodont diversity declined during the Carboniferous, with an extinction event at the end of the middle Tournaisian<ref>Template:Cite journal</ref> and a prolonged period of significant loss of diversity during the Pennsylvanian.<ref name="Shi-2021">Template:Cite journal</ref><ref>Template:Cite journal</ref> Only a handful of conodont genera were present during the Permian, though diversity increased after the P-T extinction during the Early Triassic.

Diversity continued to decline during the Middle and Late Triassic, culminating in their extinction soon after the Triassic-Jurassic boundary. Much of their diversity during the Paleozoic was likely controlled by sea levels and temperature, with the major declines during the Late Ordovician and Late Carboniferous due to cooler temperatures, especially glacial events and associated marine regressions which reduced continental shelf area. However, their final demise is more likely related to biotic interactions, perhaps competition with new Mesozoic taxa.<ref>Template:Cite journal</ref>

TaxonomyEdit

Conodonta taxonomy based on Sweet (1988),<ref name="Sweet-1988">Template:Cite book</ref> Sweet & Donoghue (2001),<ref name="Sweet-2001" /> and Mikko's Phylogeny Archive.<ref name="Haaramo-2007">Mikko's Phylogeny Archive [1] {{#invoke:citation/CS1|citation |CitationClass=web }}</ref>Template:Clarification needed

See alsoEdit

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ReferencesEdit

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Further readingEdit

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External linksEdit

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