Radiodonta


Radiodonta is an order of stem-group arthropods that was successful worldwide during the Cambrian period, and included the earliest large predators known. They may be referred to as radiodonts, radiodontans, radiodontids, anomalocarids, or anomalocaridids, although the latter originally refer to the family Anomalocarididae, which previously included all but recently only a few species of this order. Some of the most famous species of radiodonts are the Cambrian taxa Anomalocaris canadensis, Hurdia victoria, Peytoia nathorsti, and Amplectobelua symbrachiata, the Ordovician Aegirocassis benmoulai and the Devonian Schinderhannes bartelsi.

Etymology

The name Radiodonta refers to the radial arrangement of tooth plates surrounding the mouth, although these features are suggested to be absent in some radiodont species.

Definition

The original diagnosis of order Radiodonta in 1996 is as follows:In 2014, the clade Radiodonta was defined phylogenetically as a clade including any taxa closer to Anomalocaris canadensis than Paralithodes camtschaticus. In 2019, it was redefined morphologically as animal bearing head carapace complex with central and lateral elements; outgrowths from frontal appendages bearing auxiliary spines; and reduced anterior flaps or bands of lamellae and strong tapering of body from anterior to posterior.
benmoulai'', the largest radiodont.

Description

Most radiodonts are significantly large compared to other Cambrian fauna, with body length usually ranging between 30 and 50 centimeters. The largest described radiodont being the Ordovician Aegirocassis benmoulai, which may have grown up to 2 meters long. The 8 centimeters Lyrarapax are one of the smallest radiodonts, with juvenile of L. unguispinus measured only about 18 milimeters.
The body of a radiodont could be divided into two regions: head and trunk. The head is composed of only one body segment known as ocular somite, covered by sclerites, bore arthropodized frontal appendages, ventral mouthparts, and stalked compound eyes. While the tapering trunk is composed of multiple body segments, each associated with pairs of flaps and gill-like structures.

Frontal appendage

The anterior structures on the head are a pair of frontal appendages. They may referred as 'claws', 'grasping appendages', 'feeding appendages', or 'great appendages' in previous studies, but recently the latter was no longer used as the frontal appendages were considered non-homologous to megacheiran great appendages. They are scleritzed and segmented, bearing ventral spines on most of their segmental units, and the endites may bore additional rows of spines on their anterior and posterior margins. The frontal appendage could divided into two regions: the shaft and distal articulated region. Triangular region covered by soft cuticle, may occur between the ventral side of each podomere and provide flexibility. Their pre-ocular and protocerebral origin suggest they are homologous to the primary antennae of Onychophora and the labrum of Euarthropoda, and not homologous with the chelicerae of Chelicerata nor the antennae and great appendages of other arthropods, which are deutocerebral. Since the morphology of the frontal appendages, especially those of the endites are always differ between species, they are one of the most important characters in species identification. In fact, many radiodonts are only known from a handful of fossilized frontal appendages.

Oral cone

The mouth is on the ventral side of the head, behind the attachment point of frontal appendages and is surrounded by a ring of tooth plates, forming the mouthpart known as oral cone. 3 or 4 tooth plates might enlarged, giving the oral cone a triradial or tetraradial appearance. The inner margin of tooth plates have spikes facing towards the mouth opening. Additional rows of internal tooth plates may occur in some hurdiid genera. Detail reconstruction of amplectobeluid oral cones are speculative, but they possibly did not present a typical radial arrangement.

Head sclerites, eyes and trunk

Three head sclerites forming by a central H-element and a pair of P-elements, they cover the dorsal and laterovental surface of the animal's head respectively. The P-elements may connect to each other as well as H-element by a narrow anterior extension. The head carapace complex are small and ovoid in Anomalocarididae and Amplectobeluidae, but often enlarged in Hurdiidae. The head bore two stalked compound eyes, which may have mobility, and located between the gaps forming by the posterior regions of H-element and P-element.
Contrary to the original diagnosis, the division of body segments can be visible externally and no known member of Radiodonta is known to have pediform trunk appendages. The trunk have numerous body segments, tapering from anterior to posterior, with the anterior 3 or 4 segments significantly constricted into a neck region.
The trunk appendages were fin-like body flaps, usually one pair of ventral flap per body segment, each slightly overlapped on the one more anterior to it, but additional, non-overlapping set of small dorsal flaps may occur in some Hurdiid species. The flaps may have numerous vein-like structures known as strengthening rays. The flaps on the neck region, called anterior flaps or neck flaps, are significantly reduced. In some species, jaw-like feeding appendages called gnathobase-like structures arosed from each of the base of their reduced neck flaps. Numerous elongated blade-like extension arranged in a row, forming bands of gill-like structure known as setal blades or lamellae, covered the dorsal surface of each body segment. At least in Aegirocassis, each lanceolate blades are cover in wrinkles.
The ventral flaps may be homologous to the endopod of the biramous limbs of euarthropods and lobopodous limbs of gilled lobopodians, and the dorsal flaps and setal blades may be homologous to the exopod and gill-bearing dorsal flaps of the former taxa. The trunk may end either with 1 to 3 pairs of tail fan, two long furcae, an elongated terminal structure, or a featureless blunt tip.

Internal structures

Traces of muscles, digestive system and nervous system were described from some radiodont fossils. Pairs of well-developed muscles which were connected to the ventral flaps, located at the lateral cavities of each body segment. Between the lateral muscles is a sophiciated digestive system, formed by widening the foregut and hindgut, both connected by a narrow midgut associated with 6 pairs of gut divercula. Compared to the three-segmented brain of euarthropod and two-segmented brain of onychophoran, the brain of radiodont is composed of only one brain segment originating from the ocular somite, the protocerebrum. Nerves of frontal appendages and compound eyes arose from the anterior and lateral regions of the brain, respectively. Posterior to the brain was a pair of apparently unfused ventral nerve cord which ran through the animal's neck region.

Paleoecology

Physiology

Radiodonts were interpreted as nektonic or nektobenthic animals, with their morphology suggesting an active swimming lifestyle. The muscular, overlapping ventral flaps may have propelled the animal through the water, possibly by moving in a wave-like formation resembling modern rays and cuttlefish. Pairs of dorsal flaps, which make up a tail fan in some species, may help steering and/or stabilizing the animal during locomotion. In Anomalocaris, morphology of the tail fan even suggests it could rapidly change its swimming direction efficiently. Bands of setal blades with wrinkling lanceolate blades may increased the surface area, suggesting they were gills, providing the animal's respiratory function. Abundance of the remains of scleritzed structures such as disarticulated frontal appendages and head carapace complex, suggest that mass moulting events may have occurred among radiodonts, a behavior which also has been reported in some other Cambrian arthropods such as trilobites.

Diet

Radiodonts had diverse feeding strategies, which could be categorized as raptorial predators, sediment sifters, or suspension, filter feeders. For example, raptorial predators like Anomalocaris and Amplectobeluids might have been able to catch agile prey by using their raptorial frontal appendages, the latter even bore a robust endite for holding prey like a pincer. With the smaller head carapace complex and large surface of arthrodial membranes, frontal appendages of these taxa had greater flexibility. Stout frontal appendages of sediment sifters like Hurdia and Peytoia have serrated endites with mesial curvature, which could form a basket-like trap for raking through sediment and leading food items towards the well-developed oral cone. Some species may have other features significantly specialized for a sediment sifting lifestyle, such as Cambroraster with its dome-like H-element similar to the carapace of a horseshoe crab. Endites of frontal appendages from suspension/filter feeders like Tamisiocaris and Aegirocassis have flexible, densely-packed auxiliary spines, which could filter out organic components such as mesozooplankton and phytoplankton down to 0.5mm. Frontal appendages of Caryosyntrips, which are unusual for radiodonts in having the direction of endite-bearing surfaces opposing one another and may have been able to manipulate and crush prey in a scissor-like slicing or grasping motion.
, showing enlarged endites.
Oral cones of radiodonts may able to perform suction and/or biting ability. Alongside frontal appendages, differentiation of oral cones between genera suggest preferences of different diet as well. For example, the triradial oral cone of Anomalocaris with irregular, tuberculated toothplates and smaller opening may adapted to small and active prey; while the rigid tetraradial oral cones of Hurdia and Cambroraster'' with larger opening and additional tooth plates may capable to consume larger food item.

Classification

Taxomomic affinities

Most analyses suggest that radiodonts are stem-group arthropods and sister to deuteropoda, a clade including upper stem and crown Euarthropoda. This interpretation is support by numerous arthropod-like features found on radiodonts, such as compound eyes, digestive glands, arthropodization, trunk appendages forming by dorsal and ventral elements, cuticularized foregut and hindgut, as well as protocerebral anterior sclerite. The constricted neck region with feeding appendicular structures of some radiodont may also shed light on the origin of sophiciated arthropod head, which is form by the fusion of multiple anterior body segments.
Taxa just basal to the radiodont and euarthropod branch are Pambdelurion, Kerygmachela and Opabinia, three radiodont-like dinocaridid genera usually referred as 'gilled lobopodians'. They have body flaps, digestive glands and specialized frontal appendages like radiodont, but the frontal appendages are not arthropodized and they bore lobopod underneath each of their flaps. Opabinia is more derived by having radiodont-like stalked eyes, tail fan, setal blades, and even euarthropod-like posterior mouth opening. Taxa even basal to 'gilled lobopodians' are siberiids like Megadictyon and Jianshanopodia, a group of lobopodians bore robust frontal appendages and digestive glands, but no body flaps. Such intermediate forms between lobopodian and radiodont/euarthropod suggest that the total-group arthropoda arose from a paraphyletic lobopodian grade, alongside the other two extant panarthropod phyla Tardigrada and Onychophora.
or 'great appendage arthropod', a class of possible stem-chelicerate previously thought to be radiodont's close relative.
s" which may actually soft like those of Opabinia, and "ventral biramus appendages" which may in fact present flap muscles and/or setal blades like those of other radiodonts.
Previous studies may suggest radiodonts as a group other than stem-arthropods, such as cycloneuralian worms undergone convergent with arthropods ; stem chelicerates alongside megacheirans a.k.a great appendage arthropods ; or Schinderhannes bartelsi, which resolved as a hurdiid radiodont in recent analyses, as a species more closely related to euarthropods than other radiodonts. However, neither each of them were supported by later investigations. The radial mouthparts are not cycloneuralian-exclusive and more likely present result of convergent evolution or ecdysozoan plesimorphy, since they also have been found in panarthropods such as tardigrade and some lobopodians; the megacheiran great appendages were considered to be deutocerebral, which are non-homologous to the radiodont protocerebral frontal appendages; putative euarthropod characters found on the single Schinderhannes fossil is questionable and may present other radiodont-like structures.

Interrelationships

Traditionally, Radiodonta included all taxa under the class Dinocaridida, and taxa currently included within Radiodonta have been placed within one family, Anomalocarididae, hence the common name 'anomalocaridid' and it was still occasionally used to refer the whole order even after reclassification. Recently, the basal dinocaridid genera Pambdelurion, Kerygmachela and Opabinia were placed outside of Radiondonta, and most of the radiodont species were reclassified within three new families: Amplectobeluidae, Tamisiocarididae, and Hurdiidae. Including Anomalocarididae, the four recent radiodont families may form the clade Anomalocarida.
yunnanensis, a poorly-preserved megacheiran previously misinterpreted as 'radiodont with legs'.
The original description of the order Radiodonta included Anomalocaris, Laggania, Hurdia, Proboscicaris, Amplectobelua, Cucumericrus, and Parapeytoia. However, Proboscicaris is now regarded as a junior synonym of Hurdia, and Parapeytoia is considered to be a megacheiran. The position of Cucumericrus within Radiodonta is unclear, as it was either unselected by phylogenetic analysis or resolved in a polytomy with Radiodonta and Euarthropoda.
, a genus suggest to be one of the most basal radiodont.
based on phylogenetic analysis.
Under Radiodonta, Caryosyntrips is the basal-most genus alongside Cucumericrus. The genus Anomalocaris always found to be non-monophyletic, usually with Anomalocaris kunmingensis and Anomalocaris briggsi resolved as a member of Amplectobeluidae and Tamisiocarididae respectively. Interrelationship of Amplectobeluidae is uncertain, as the amplectobeluid affinities of Lyrarapax and Ramskoeldia were occasionally questioned. Monophyly of the speciose family Hurdiidae is well-supported by several derived characters, with Tamisiocarididae often suggested to be its sister group.
  • Radiodonta
  • *Cucumericrus
  • *Caryosyntrips
  • * Anomalocarida
  • **Paranomalocaris
  • **Laminacaris
  • **Anomalocarididae
  • ***Anomalocaris
  • **Amplectobeluidae
  • ***Lyrarapax
  • *** Amplectobelua
  • *** Ramskoeldia
  • **Tamisiocarididae
  • ***Tamisiocaris
  • *** Anomalocaris briggsi
  • **Hurdiidae
  • ***Aegirocassis
  • *** Peytoia
  • *** Schinderhannes
  • *** Hurdia
  • *** Ursulinacaris
  • *** Stanleycaris
  • *** Pahvantia
  • *** Cambroraster
  • ***Zhenghecaris
The first in-depth phylogenetic analysis of Radiodonta was conducted by Vinther et al. in 2014, and it was expanded by Cong et al. later that year by the addition of Lyrarapax unguispinus. The analysis was further modified in 2015 by Van Roy et al. with modified characters and the inclusion of Cucumericrus decoratus and Aegirocassis benmoulai''.