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Radiodonta

January 01, 1970

Radiodonta is an extinct order of stem-group arthropods that was successful worldwide during the Cambrian period. They may be referred to as radiodonts,[1][2][3] radiodontans,[4][5] radiodontids,[6] anomalocarids,[7] or anomalocaridids,[8][9][10] although the last two originally refer to the family Anomalocarididae, which previously included all species of this order but is now restricted to only a few species.[7] Radiodonts are distinguished by their distinctive frontal appendages, which are morphologically diverse and used for a variety of functions. Radiodonts included the earliest large predators known, but they also included sediment sifters and filter feeders.[11] Some of the most famous species of radiodonts are the Cambrian taxa Anomalocaris canadensis, Hurdia victoria, Peytoia nathorsti, Titanokorys gainessii, Cambroraster falcatus and Amplectobelua symbrachiata, the Ordovician Aegirocassis benmoulai and the Devonian Schinderhannes bartelsi.

Radiodonta
Temporal range: Cambrian Stage 3 – Early Devonian, 521–400 Ma
Left to right, top to bottom: Amplectobelua symbrachiata, Anomalocaris canadensis, Aegirocassis benmoulai, Peytoia nathorsti, Lyrarapax unguispinus, Cambroraster falcatus, and Hurdia victoria
Scientific classification
Kingdom:
Animalia
Phylum:
Arthropoda
Class:
Dinocaridida
Order:
Radiodonta
Collins, 1996
Families

Etymology edit

The name Radiodonta (Latin for radius "spoke of a wheel" and Greek for odoús "tooth") refers to the radial arrangement of tooth plates (oral cone) surrounding the mouth,[6] although these features are suggested to be absent in some radiodont species.[4][1]

Definition edit

The original diagnosis of order Radiodonta in 1996 is as follows:[6]

Radiodontids are bilaterally symmetrical, elongate arthropods with a nonmineralized cuticle typically most robust in the jaws and claws. The body is subdivided into two tagmata, much like the prosoma and opisthosoma of chelicerate arthropods. Typically, the front part shows no external segmentation, bears one pair of preoral claws, a pair of prominent eyes, and ventral jaws with radiating teeth. Some forms have additional rows of teeth and three or four postoral gnathobasic limb pairs. The trunk is metameric, typically with about 13 segments laterally developing imbricating lobes for swimming and gills for respiration, and may end in a prominent three-part tail. Some forms have gnathobasic trunk limbs.

In 2014, the clade Radiodonta was defined phylogenetically as a clade including any taxa closer to Anomalocaris canadensis than Paralithodes camtschaticus.[7] In 2019, it was redefined morphologically as animal bearing head carapace complex with central (H-) and lateral (P-) elements; outgrowths (endites) from frontal appendages bearing auxiliary spines; and reduced anterior flaps or bands of lamellae (setal blades) and strong tapering of body from anterior to posterior.[3]

Description edit

 
Size estimation and comparison of radiodont species known by nearly complete specimens

Most radiodonts were significantly larger than the other Cambrian fauna, with typical body lengths varying from 30 to 50 centimeters.[2] The largest described radiodont is the Ordovician species Aegirocassis benmoulai, which may have grown up to two meters long.[10][2] A nearly complete specimen of a juvenile Lyrarapax unguispinus measured only 18 millimetres (0.71 in), making it among the smallest radiodont specimens known, though adults reached a length of 8 centimetres (3.1 in)[2][12] An isolated frontal appendage of a hurdiid with a length less than half that of the juvenile Lyrarapax is known, but it is not known whether this specimen pertains to an adult.[13] The largest known Cambrian radiodont was Amplectobelua, reaching lengths of up to 90 cm (35 in) based on an incomplete specimen.[14] Anomalocaris and Laminacaris are also large ones, reached 37.8 centimetres (14.9 in) and 78 centimetres (31 in) (there was an estimation that Houcaris saron (previously Anomalocaris saron) reached 56 centimetres (22 in), but specimen used for estimating the body length no longer belongs to that species[15]); the Cambrian hurdiid Titanokorys approached it in size, with an estimated body length of approximately 50 centimetres (20 in).[2][16]

The body of a radiodont could be divided into two regions: head and trunk. The head is composed of only one body segment[17] known as the ocular somite, covered by sclerites (head carapace complex), bore arthropodized frontal appendages, ventral mouthparts (oral cone), and stalked compound eyes. The tapering trunk is composed of multiple body segments, each associated with pairs of flaps and gill-like structures (setal blades).[3]

Frontal appendage edit

 
 
Frontal appendages morphology of the radiodont families Anomalocarididae/Amplectobeluidae and Hurdiidae

The anterior structures on the head are a pair of frontal appendages which have been referred to as 'claws', 'grasping appendages', 'feeding appendages', or 'great appendages' in previous studies (the last term is discouraged since the homology between frontal appendages and the original, morphologically distinct megacheiran great appendages is questionable.[17][18]). They are sclerotized (hardened) and arthropodized (segmented), bearing ventral endites (spines) on most of their podomeres (segmental units), and the endites may bear additional rows of auxiliary spines on their anterior and posterior margins.[19][3] The frontal appendage consists of two regions: the shaft ('peduncle',[2] 'base'[20] or 'promixal region'[2] in some studies) and the distal articulated region[19] (also referred to as 'claw'[20]). A triangular region covered by soft cuticle (arthrodial membrane) may occur on the ventral side between podomeres and provide flexibility.[21][11] Their purported pre-ocular and protocerebral origin suggest they are homologous to the primary antennae of Onychophora and the labrum of Euarthropoda (all arose from ocular somite),[17][9] while subsequent studies also suggest a deutocerebral origin and homologous with the chelicerae of Chelicerata and the antennae or 'great appendages' of other arthropods (all arose from post-ocular somite 1).[22] Since the morphology of the frontal appendages, especially those of the spines, always differs between species, it is one of the most important means of species identification.[19] In fact, many radiodonts are only known from a handful of fossilized frontal appendages.[21][19]

Oral cone edit

 
Oral cones of various radiodonts

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 ('jaws' in previous studies[6]). 3 or 4 tooth plates might be enlarged, giving the oral cone a triradial (e.g. Anomalocaris, Echidnacaris) or tetraradial (e.g. Hurdiidae, Lyrarapax) appearance.[23][12][24] 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.[8][3] Detail reconstruction of some amplectobeluid oral cones are speculative, but they possibly did not present a typical radial arrangement.[4][1]

Head sclerites, eyes and trunk edit

 
Head sclerite complexes of various radiodonts

Three head sclerite (carapace) complex formed by a central H-element (anterior sclerite or head shield) and a pair of P-elements (lateral sclerites) cover the dorsal and laterovental surface of the animal's head.[3] The P-elements may connect to each other as well as the H-element by a narrow anterior extension (P-element neck or 'beak').[8][3] The head sclerites are small and ovoid in Anomalocarididae and Amplectobeluidae,[4][3] but often enlarged in Hurdiidae, corresponded to their distinct body shapes (streamlined in Anomalocarididae/Amplectobeluidae but often compact in Hurdiidae).[3] The head bore two stalked compound eyes, which may have had mobility,[25] and are located between the gaps formed by the posterior regions of the H-element and P-elements.[8][3] The compound eyes of Echidnacaris are exceptionally unstalked.[13] Some species possess an additional median eye behind the H-element.[22]

 
 
Anterior region of two generized Anomalocaris and Hurdiid radiodont, showing distinct morphology A: Dorsal view, B: Ventral view, Fa: Frontal appendage, He: H-element, Pe: P-element, Ey: Eye, Oc: Oral cone, Af: Anterior (neck) flap, Bf/Vf:, Ventral flap, Sb: Setal blade

Contrary to the original diagnosis, the division of body segments (segmental boundaries) can be visible externally[10][5][3] and no known member of Radiodonta (except the putative radiodont Cucumericrus[10][26]) is known to have pediform trunk appendages (legs).[27] The trunk has numerous body segments (somites), tapering from anterior to posterior, with the anterior three or four segments significantly constricted into a neck region.[3]

  •  
    Variations of radiodont body flaps
  •  
    The movement of radiodont flapping appendages
  •  
    Ventral view of a generalized GLS-bearing radiodont, showing gnathobase‐like structures (GLSs) associated with reduced anterior flaps

The trunk appendages were fin-like body flaps ('lateral flaps' or 'lobes' in some studies), usually one pair of ventral flaps per body segment, each slightly overlapping the one more anterior to it, but additional, non-overlapping sets of small dorsal flaps may occur in some Hurdiid species.[10] The flaps may have numerous vein-like structures (referred to as 'strengthening rays',[5] 'flap rays',[3] 'tranverse rods',[10] 'transverse lines'[28] or 'veins'[29]). The flaps on the neck region (referred to as 'reduced flaps',[4] 'neck flaps',[5] 'head flaps',[27] 'anterior flaps'[30] or 'differentiated flaps'[18]) are significantly reduced. In some species, jaw-like feeding appendages called gnathobase-like structures (GLSs) arose from each of the bases of their reduced neck flaps.[4][1] Numerous elongated blade-like extensions (referred to as lanceolate blades or lamellae[3]) arranged in a row, forming bands of gill-like structures known as setal blades, covered the dorsal surface of each body segment.[10] At least in Aegirocassis, each of the lanceolate blades are covered in wrinkles.[10] The ventral flaps may be homologous to the endopod of the biramous limbs of euarthropods and lobopodous limbs (lobopods) of gilled lobopodians, and the dorsal flaps and setal blades may be homologous to the exite and gill-bearing dorsal flaps of the former taxa.[31][10] The trunk may end either with a tail fan compose of 1 to 3 pairs of blades,[29][27][3] a pair of long furcae,[29][12][3] an elongated terminal structure,[27] or a featureless blunt tip.[10]

Internal structures edit

 
digestive system of a radiodont
 
Various interpretations of radiodont brain. A: after Cong et al. 2014,[9] B: after Moysiuk & Caron 2022[22]

Traces of muscles, digestive system and nervous system were described from some radiodont fossils. Pairs of well-developed muscles were connected to the ventral flaps located at the lateral cavities of each body segment.[27][9] Between the lateral muscles is a sophisticated digestive system, formed by a widening of the foregut and hindgut, both connected by a narrow midgut associated with six pairs of gut divercula (digestive glands).[27][5][32]

The brain of radiodonts was simpler than the three-segmented (compose of pro-, deuto- and tritocerebrum) brains of euarthropods, but further interpretations differ between studies. Based on Cong et al. 2014, the brain composed of only one brain segment originating from the ocular somite, the protocerebrum. The nerves of the frontal appendages and compound eyes arose from the anterior and lateral regions of the brain.[9][17] Based on Moysiuk & Caron 2022, the frontal appendage nerves arose from the ventral deutocerebrum, the second brain segment. The previous "frontal appendage nerves" actually represent median eye nerve.[22] In both interpretations, posterior to the brain was a pair of apparently unfused ventral nerve cords which ran through the animal's neck region.[9][22]

Paleoecology edit

Physiology edit

 
Paleoecological reconstruction of a group of Cambroraster swimming over a brine seep

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.[33][34] Pairs of dorsal flaps, which make up a tail fan in some species, may have helped steering and/or stabilizing the animal during locomotion.[10][35] In Anomalocaris, morphology of the tail fan even suggests it could rapidly change its swimming direction efficiently.[36] On the other hand, some hurdiids have features significantly specialized for a nektobenthic lifestyle, such as Cambroraster with its dome-like H-element similar to the carapace of a horseshoe crab.[3] Bands of setal blades with wrinkling lanceolate blades may have increased the surface area, suggesting they were gills, providing the animal's respiratory function.[27][10] Abundance of the remains of scleritzed structures such as disarticulated frontal appendages and head sclerite complexes, suggest that mass moulting events may have occurred among radiodonts,[10][3] a behavior which also has been reported in some other Cambrian arthropods such as trilobites.[37]

Diet edit

 
Anomalocaris canadensis
 
Amplectobelua stephenensis
 
Caryosyntrips camurus
 
Tamisiocaris borealis
 
Peytoia nathorsti
 
Cambroraster falcatus
Suggested frontal appendage mobility and movement of various radiodonts[21][11]

Radiodonts had diverse feeding strategies, which could be categorized as raptorial predators, sediment sifters, or suspension, filter feeders.[2][38][11][39][40] 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.[26][21][4][11] With the smaller head carapace complex and large surface of arthrodial membranes, frontal appendages of these taxa had greater flexibility.[12] 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 passing food items towards the well-developed oral cone.[3][11] 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.[7][10] 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.[21][41]

Oral cones of radiodonts may have been used for suction and/or biting.[23][38][3] Together with the great variety of frontal appendages in different species of radiodonts, differentiation of oral cones between species suggests preferences of different diets as well.[38][11] For example, the triradial oral cone of Anomalocaris with irregular, tuberculated toothplates and a small opening may have been adapted to small and nektonic prey,[23][11] while the rigid tetraradial oral cones of Peytoia, Titanokorys, Hurdia, and one isolated oral cone attributed to Cambroraster with a larger opening and sometimes additional tooth plates may have been capable to consume larger food items relative to their body size and probably benthic or endobenthic prey.[23][38][3]

Classification edit

Taxonomic affinities edit

Ecdysozoa
Cycloneuralia

Priapulida   and relatives

Panarthropoda

Onychophora  

Tardigrada  

Lobopodian grade
(paraphyletic)  

Siberiid lobopodians  

Pambdelurion  

Kerygmachela  

Opabiniidae  

Radiodonta  

Euarthropoda  

Summarized phylogeny between Radiodonta and other Ecdysozoan taxa[42]

Most phylogenetic analyses suggest that radiodonts, alongside opabiniids (Opabinia and Utaurora[43]), are stem-group arthropods just basal to deuteropoda,[42] a clade including upper stem (e.g. fuxianhuiids and bivalved arthropods) and crown Euarthropoda (e.g. Artiopoda, Chelicerata and Mandibulata).[8][44][45][46][47][48][7][9][10][2][3][30][18][39][40][49][50][43] This interpretation is supported by numerous arthropod groundplan found on radiodonts and opabiniids, such as stalked compound eyes,[25] digestive glands,[32] trunk appendages forming by dorsal and ventral elements (precursor of arthropod biramous appendages).[10][50] Compared to opabiniids, which possess posterior mouth opening and fused frontalmost appendages (comparable to euarthropod posterior-facing labrum/hypostome complex),[17][43] radiodonts on the other hand featured euarthropod-like dorsal sclerite (H-element) and arthropodization (frontal appendages) on their head regions,[51][17][43] alongside cuticularized gut termini.[27] The fact that both radiodonts and opabiniids lack exoskeleton on their trunk region suggests that the origin of compound eyes and arthropodization (segmented appendages) precede arthrodization (full set of trunk exoskeleton) in the arthropod stem lineage.[42][52][53] The constricted neck region with feeding appendicular structures of some radiodont may also shed light on the origin of the sophisticated arthropod head, which was formed by the fusion of multiple anterior body segments.[4][17] Basal deuteropods that possess a mixture of radiodont/opabiniid characters like Kylinxia and Erratus, may represent intermediate forms between radiodonts, opabiniids and other euarthropods.[18][50]

Taxa just basal to the radiodont, opabiniid and euarthropod branch are 'gilled lobopodians' like Pambdelurion and Kerygmachela, which occasionally united under the class Dinocaridida with opabibiids and radiodonts.[54][46] They have body flaps, digestive glands, large (presumely compound) eyes and specialized frontal appendages like the former taxa, but their frontal appendages are not arthropodized nor fused, eyes sessile, gill-like structures less prominent, and certainlly bore lobopod underneath each of their flaps.[55][10][56][43] Taxa even basal to 'gilled lobopodians' are siberiids like Megadictyon and Jianshanopodia,[42] a group of lobopodians that 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.[57][42][17][58][52][53]

Previous studies may suggest radiodonts as a group other than stem-arthropods, such as a hitherto unknown phylum;[33] cycloneuralian worms undergone convergent with arthropods (based on the cycloneuralian-like radial mouthparts);[59][54] stem chelicerate euarthropods alongside megacheirans also known as great appendage arthropods (based on the similarity between radiodont frontal appendages, megacheiran great appendages and chelicerae);[60] or Schinderhannes bartelsi, which resolved as a hurdiid radiodont in recent analyses,[42][7][10][2][3][39][40] as a species more closely related to euarthropods than other radiodonts (based on some putative euarthropod-like features found on Schinderhannes).[35] 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;[61] radiodonts lacking definitive euarthropod features such as trunk tergites and multiple head appendages,[42] and the megacheiran great appendages were considered to be deutocerebral,[62][63] which could be non-homologous to the radiodont protocerebral frontal appendages;[9][17] putative euarthropod characters found on the single Schinderhannes fossil is questionable and may present other radiodont-like structures.[42]

Interrelationships edit

Caryosyntrips  

Tamisiocarididae

Houcaris saron  

"Anomalocaris" briggsi  

Tamisiocaris  

Anomalocarididae+
Amplectobeluidae

Laminacaris  

Houcaris magnabasis  

Anomalocaris  

"Anomalocaris" kunmingensis  

Ramskoeldia consimilis  

Ramskoeldia platyacantha  

Paranomalocaris  

Hurdiidae

Euarthropoda

Phylogeny of Radiodonta after Moysiuk & Caron 2021[39]

Traditionally, all radiodont species have been placed within one family, Anomalocarididae,[6] hence the previous common name 'anomalocaridid'[26][8] and it was still occasionally used to refer the whole order even after reclassification.[9][10] Since the reassignment done by Vinther et al. 2014, most of the radiodont species were reclassified within three new families: Amplectobeluidae, Tamisiocarididae[2][3] (formerly Cetiocaridae[7]), and Hurdiidae.[7][10][2][3] Including Anomalocarididae, the four recent radiodont families may form the clade Anomalocarida.[7]

The original description of the order Radiodonta included Anomalocaris, Laggania (later known as Peytoia), Hurdia, Proboscicaris, Amplectobelua, Cucumericrus, and Parapeytoia.[6] However, Proboscicaris is now regarded as a junior synonym of Hurdia, and Parapeytoia is considered to be a Megacheiran.[8][27][10] Due to the limited discovery, The position of Cucumericrus within Radiodonta is unclear, as it was either unselected by phylogenetic analysis[7][3][2][39][40] or resolved in a polytomy with Radiodonta and Euarthropoda.[10][12]

  •  
    One of the poorly-known body parts (trunk appendage) of Cucumericrus decoratus; this species may not represent a true radiodont.
  •  
    Frontal appendage of Echidnacaris briggsi, a tamisiocarid radiodont that was once suggested to belong to the Anomalocaris genus until its description in 2023.

The first in-depth phylogenetic analysis of Radiodonta was conducted by Vinther et al. in 2014,[7] followed by a handful of subsequest studies with more or less modified results.[9][10][2][12][3][39][40][43] In most analysis, Caryosyntrips is the basal-most genus, but either resolved in a polytomy with other radiodonts and Euarthropoda (alongside Cucumericrus if included[10][12]) or outside of Radiodonta, casting doubt on its radiodont affinity.[64] With the exclusion of questionable Caryosyntrips and Cucumericrus, the monophyly of Radiodonta is widely supported,[7][9][10][2][12][3][39][40] with a few results suggest possible paraphyly (either the Anomalocarididae+Amplectobeluidae clade or Hurdiidae sister to Euarthropoda).[30][43] Putative synapomorphies of monophyletic Radiodonta including tripartite head sclerite complex and differentiated neck region.[3] The genus Anomalocaris in a broader sense always found to be polyphyletic, usually with "Anomalocaris" kunmingensis and "Anomalocaris" briggsi resolved as a member of Amplectobeluidae and Tamisiocarididae respectively.[7][9][10][2][3][39][40] Interrelationship of Amplectobeluidae is uncertain, as the amplectobeluid affinities of Lyrarapax and Ramskoeldia were occasionally questioned.[1][3][40] Monophyly of the speciose family Hurdiidae was recovered by most analysis and well-supported by several synapomorphies (e.g. distal articulated region of frontal appendage with proximal 5 podomeres bearing subequal endites[19][3]). Tamisiocarididae was often suggested to be sister group of Hurdiidae in 2010s,[7][10][2][3] but this position became questionable in subsequent studies.[22][24]

Described species of Radiodonta
Species Original description Year named Family Age Location Frontal appendage Head sclerite complex
Cucumericrus decoratus Hou, Bergström, & Ahlberg 1995[26] (unassigned) Cambrian Stage 3   China Unknown Unknown
Caryosyntrips serratus Daley & Budd 2010[21] (unassigned) WuliuanDrumian   Canada   United States   Unknown
Caryosyntrips camurus Pates & Daley 2017[41] (unassigned) Wuliuan   Canada   United States   Incomplete[74]
Caryosyntrips durus Pates & Daley 2017[41] (unassigned) Drumian   United States   Unknown
Paranomalocaris multisegmentalis Wang, Huang, & Hu 2013[66] Anomalocarididae? Cambrian Stage 4   China   Unknown
Paranomalocaris simplex Jiao, Pates, Lerosey-Aubril, Ortega-Hernandez, Yang, Lan, Zhang 2021[67] Anomalocarididae? Cambrian Stage 4   China   Unknown
Laminacaris chimera Guo, Pates, Cong, Daley, Edgecombe, Chen, & Hou 2018[68] (controversial) Cambrian Stage 3   China   Unknown
Innovatiocaris maotianshanensis Zeng, Zhao, Zhu 2022[69] (unassigned) Cambrian Stage 3   China   P-element unknown[69]
Innovatiocaris? multispiniformis Zeng, Zhao, Zhu 2022[69] (unassigned) Cambrian Stage 3   China   Unknown
Anomalocaris canadensis Whiteaves 1892[75] Anomalocarididae Wuliuan   United States    
Lenisicaris pennsylvanica (formerly Anomalocaris pennsylvanica)[20] Resser 1929 Anomalocarididae Cambrian Stage 3   United States   Unknown
Lenisicaris lupata Wu, Ma, Lin, Sun, Zhang, & Fu 2021[20] Anomalocarididae Cambrian Stage 3   China   Unknown
Anomalocaris daleyae Paterson, García-Bellidob & Edgecombe 2023 Anomalocarididae Cambrian Stage 4   Australia   Unknown
Houcaris magnabasis (formerly Anomalocaris magnabasis)[15] Pates, Daley, Edgecombe, Cong & Lieberman 2019 (controversial) Cambrian Stage 4   United States   Unknown
Houcaris saron (formerly Anomalocaris saron)[15] Hou, Bergström, & Ahlberg 1995 (controversial) Cambrian Stage 3   China   Unknown
Echidnacaris briggsi[24] Nedin 1995 Tamisiocarididae Cambrian Stage 4   Australia   Possible H-element and unique lateral sclerites associated with compound eyes[13][24]
Ramskoeldia platyacantha Cong, Edgecombe, Daley, Guo, Pates, & Hou 2018[1] Amplectobeluidae Cambrian Stage 3   China   Incomplete[1]
Ramskoeldia consimilis Cong, Edgecombe, Daley, Guo, Pates, & Hou 2018[1] Amplectobeluidae Cambrian Stage 3   China   Incomplete[1]
Lyrarapax unguispinus Cong, Ma, Hou, Edgecombe, & Strausfield 2014[9] Amplectobeluidae Cambrian Stage 3   China   P-element neck unknown
Lyrarapax trilobus Cong, Daley, Edgecombe, Hou, & Chen 2016[5] Amplectobeluidae Cambrian Stage 3   China   P-element unknown
Amplectobelua symbrachiata Hou, Bergström, & Ahlberg 1995[26] Amplectobeluidae Cambrian Stage 3   China    
Amplectobelua stephenensis Daley & Budd 2010[21] Amplectobeluidae Wuliuan   United States   Unknown
Guanshancaris kunmingensis Zhang et al. 2023[70] Amplectobeluidae Cambrian Stage 4   China   Unknown
Tamisiocaris borealis Daley & Peel 2010 Tamisiocarididae Cambrian Stage 3   Greenland   Incomplete[7]
Ursulinacaris grallae Pates, Daley & Butterfield 2019 Hurdiidae Wuliuan   Canada   Unknown
Schinderhannes bartelsi Kühl, Briggs, & Rust 2009[35] Hurdiidae Emsian   Germany Incomplete[3] Incomplete[3]
Stanleycaris hirpex Pates, Daley, & Ortega-Hernández 2018[72] Hurdiidae Wuliuan   Canada   P-element is unknown, possibly absent[22]
Peytoia nathorsti Walcott 1911[76] Hurdiidae WuliuanDrumian   Canada   United States   Incomplete[3]
Peytoia infercambriensis (formerly Cassubia infercambriensis)[77] Lendzion 1975 Hurdiidae Cambrian Stage 3   Poland   Unknown
Aegirocassis benmoulai Van Roy, Daley, & Briggs 2015[10] Hurdiidae (Aegirocassisinae) Tremadocian   Morocco    
Hurdia victoria Walcott 1912[78] Hurdiidae WuliuanDrumian   Canada   Czechia    
Hurdia triangulata Walcott 1912[78] Hurdiidae Wuliuan   Canada    
Cambroraster falcatus Moysiuk & Caron 2019[3] Hurdiidae Wuliuan   Canada    
Pahvantia hastata Robison & Richards 1981 Hurdiidae Drumian   United States    
Cordaticaris striatus Sun, Zeng, & Zhao 2020[73] Hurdiidae Drumian   China Incomplete[73]  
Zhenghecaris shankouensis Vanner, Chen, Huang, Charbonnier, & Wang 2006 Hurdiidae Cambrian Stage 3   China Unknown
 
Buccaspinea cooperi Pates, Lerosey-Aubril, Daley, Kier, Bonino & Ortega-Hernández 2021[74] Hurdiidae Drumian   United States   Unknown
Titanokorys gainesi Caron & Moysiuk 2021[40] Hurdiidae Wuliuan   Canada    
Pseudoangustidontus duplospineus Van Roy & Tetlie 2006 Hurdiidae (Aegirocassisinae) Tremadocian   Morocco   Unknown
Pseudoangustidontus izdigua Potin, Gueriau & Daley 2023 Hurdiidae (Aegirocassisinae) Tremadocian   Morocco   Incomplete[71]

History edit

 
Body specimen of Peytoia nathorsti, the original "Laggania cambria"

The history of radiodonts is complex. Incomplete specimens pertaining to different body parts of the same species had historically been interpreted as belonging to different species and even different phyla.[6][8] Prior to their recognition as a group, radiodont specimens had been assigned to five different phyla: Porifera, Cnidaria, Echinodermata, Annelida, and Arthropoda.[6]

The first known radiodont specimens were collected from the trilobite beds of Mount Stephen by Richard G. McConnell of the Geological Survey of Canada in 1886[6] or 1888.[75] These specimens were named Anomalocaris canadensis in 1892 by GSC paleontologist Joseph Whiteaves.[75] Whiteaves interpreted the specimens, now known to be isolated frontal appendages, as the abdomen of a phyllocarid crustacean.[75] Additional radiodont specimens were described in 1911 by Charles Walcott.[76] He interpreted an isolated oral cone, which he named Peytoia nathorsti, as a jellyfish, and a poorly-preserved but relatively complete specimen, which he named Laggania cambria, as a holothurian.[76] In 1912 Walcott named Hurdia victoria and H. triangulata based on isolated H-elements, which he interpreted as the carapaces of crustaceans.[78] Isolated frontal appendages of Peytoia and Hurdia, collectively known as "Appendage F" in Briggs 1979, were all identified as those of Sidneyia at that time.[76] A Hurdia P-element was named Proboscicaris in 1962, and interpreted as the carapace of a bivalved arthropod.[79]

The Geological Survey of Canada initiated a revision of Burgess Shale fossils in 1966, overseen by Cambridge University paleontologist Harry B. Whittington.[6] This revision would ultimately lead to the discovery of the complete radiodont body plan. In 1978, Simon Conway Morris recognized that the mouthparts of Laggania were Peytoia-like, but he interpreted this as evidence that it was a composite fossil made up of a Peytoia jellyfish and a sponge.[80] In 1979, Derek Briggs recognized that the fossils of Anomalocaris were appendages, not abdomens, but interpreted them as walking legs alongside "Appendage F".[81] It was not until 1985 that the true nature of the fossils of Anomalocaris, Laggania, and Peytoia was recognized, and they were all assigned to a single genus, Anomalocaris.[33] Subsequently, it was recognized that Anomalocaris was a distinct form from the other two, resulting in a split into two genera, the latter of which was variously named Laggania and Peytoia until it was determined that both represent the same species and Peytoia had priority.[23] It was later recognized that some of the fossils assigned to these taxa belonged to another form, which was recognized as bearing a carapace made up of Hurdia and Proboscicaris elements. Finally, in 2009, these specimens were redescribed as Hurdia.[8] Even after these recognitions, partial misidentifications (e.g. oral cone and frontal appendages of Peytoia had been assigned to Anomalocaris[6] and Hurdia,[8] respectively) had been revealed by subsequent studies as well.[23][82]

The taxon Radiodonta itself was coined in 1996 by Desmond Collins, after it was established that Anomalocaris and its kin represented a distinctive lineage with arthropod affinities rather than a hitherto unknown phylum.[6] Collins also established the class Dinocarida to contain the order Radiodonta as well as the Opabiniidae, which he recognized as distinct due to its lacking the distinctive oral cone structure of radiodonts.[6] Radiodonta was first given a phylogenetic definition in 2014.[7] Radiodonta was originally viewed as containing a single family, Anomalocarididae, but it was divided into four families in 2014: Amplectobeluidae, Anomalocarididae, Cetiocaridae, and Hurdiidae.[7] The name Cetiocaridae did not conform to the International Code of Zoological Nomenclature and so was renamed Tamisiocarididae in 2019.[83]

Until the 2010s, radiodonts were typically considered to be uniformly large apex predators, but discoveries of new species over the course of that decade led to a considerable increase in the known ecological and morphological diversity of the group.[7][10][2][3][84][74][39][40]

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January 01, 1970
radiodonta, extinct, order, stem, group, arthropods, that, successful, worldwide, during, cambrian, period, they, referred, radiodonts, radiodontans, radiodontids, anomalocarids, anomalocaridids, although, last, originally, refer, family, anomalocarididae, whi. Radiodonta is an extinct order of stem group arthropods that was successful worldwide during the Cambrian period They may be referred to as radiodonts 1 2 3 radiodontans 4 5 radiodontids 6 anomalocarids 7 or anomalocaridids 8 9 10 although the last two originally refer to the family Anomalocarididae which previously included all species of this order but is now restricted to only a few species 7 Radiodonts are distinguished by their distinctive frontal appendages which are morphologically diverse and used for a variety of functions Radiodonts included the earliest large predators known but they also included sediment sifters and filter feeders 11 Some of the most famous species of radiodonts are the Cambrian taxa Anomalocaris canadensis Hurdia victoria Peytoia nathorsti Titanokorys gainessii Cambroraster falcatus and Amplectobelua symbrachiata the Ordovician Aegirocassis benmoulai and the Devonian Schinderhannes bartelsi RadiodontaTemporal range Cambrian Stage 3 Early Devonian 521 400 Ma PreꞒ Ꞓ O S D C P T J K Pg N Left to right top to bottom Amplectobelua symbrachiata Anomalocaris canadensis Aegirocassis benmoulai Peytoia nathorsti Lyrarapax unguispinus Cambroraster falcatus and Hurdia victoria Scientific classification Kingdom Animalia Phylum Arthropoda Class Dinocaridida Order RadiodontaCollins 1996 Families Anomalocarididae Amplectobeluidae Tamisiocarididae Hurdiidae Genera with uncertain classification Caryosyntrips Cucumericrus Houcaris Innovatiocaris Laminacaris Paranomalocaris Contents 1 Etymology 2 Definition 3 Description 3 1 Frontal appendage 3 2 Oral cone 3 3 Head sclerites eyes and trunk 3 4 Internal structures 4 Paleoecology 4 1 Physiology 4 2 Diet 5 Classification 5 1 Taxonomic affinities 5 2 Interrelationships 6 History 7 ReferencesEtymology editThe name Radiodonta Latin for radius spoke of a wheel and Greek for odous tooth refers to the radial arrangement of tooth plates oral cone surrounding the mouth 6 although these features are suggested to be absent in some radiodont species 4 1 Definition editThe original diagnosis of order Radiodonta in 1996 is as follows 6 Radiodontids are bilaterally symmetrical elongate arthropods with a nonmineralized cuticle typically most robust in the jaws and claws The body is subdivided into two tagmata much like the prosoma and opisthosoma of chelicerate arthropods Typically the front part shows no external segmentation bears one pair of preoral claws a pair of prominent eyes and ventral jaws with radiating teeth Some forms have additional rows of teeth and three or four postoral gnathobasic limb pairs The trunk is metameric typically with about 13 segments laterally developing imbricating lobes for swimming and gills for respiration and may end in a prominent three part tail Some forms have gnathobasic trunk limbs In 2014 the clade Radiodonta was defined phylogenetically as a clade including any taxa closer to Anomalocaris canadensis than Paralithodes camtschaticus 7 In 2019 it was redefined morphologically as animal bearing head carapace complex with central H and lateral P elements outgrowths endites from frontal appendages bearing auxiliary spines and reduced anterior flaps or bands of lamellae setal blades and strong tapering of body from anterior to posterior 3 Description edit nbsp Size estimation and comparison of radiodont species known by nearly complete specimens Most radiodonts were significantly larger than the other Cambrian fauna with typical body lengths varying from 30 to 50 centimeters 2 The largest described radiodont is the Ordovician species Aegirocassis benmoulai which may have grown up to two meters long 10 2 A nearly complete specimen of a juvenile Lyrarapax unguispinus measured only 18 millimetres 0 71 in making it among the smallest radiodont specimens known though adults reached a length of 8 centimetres 3 1 in 2 12 An isolated frontal appendage of a hurdiid with a length less than half that of the juvenile Lyrarapax is known but it is not known whether this specimen pertains to an adult 13 The largest known Cambrian radiodont was Amplectobelua reaching lengths of up to 90 cm 35 in based on an incomplete specimen 14 Anomalocaris and Laminacaris are also large ones reached 37 8 centimetres 14 9 in and 78 centimetres 31 in there was an estimation that Houcaris saron previously Anomalocaris saron reached 56 centimetres 22 in but specimen used for estimating the body length no longer belongs to that species 15 the Cambrian hurdiid Titanokorys approached it in size with an estimated body length of approximately 50 centimetres 20 in 2 16 The body of a radiodont could be divided into two regions head and trunk The head is composed of only one body segment 17 known as the ocular somite covered by sclerites head carapace complex bore arthropodized frontal appendages ventral mouthparts oral cone and stalked compound eyes The tapering trunk is composed of multiple body segments each associated with pairs of flaps and gill like structures setal blades 3 Frontal appendage edit nbsp nbsp Frontal appendages morphology of the radiodont families Anomalocarididae Amplectobeluidae and Hurdiidae The anterior structures on the head are a pair of frontal appendages which have been referred to as claws grasping appendages feeding appendages or great appendages in previous studies the last term is discouraged since the homology between frontal appendages and the original morphologically distinct megacheiran great appendages is questionable 17 18 They are sclerotized hardened and arthropodized segmented bearing ventral endites spines on most of their podomeres segmental units and the endites may bear additional rows of auxiliary spines on their anterior and posterior margins 19 3 The frontal appendage consists of two regions the shaft peduncle 2 base 20 or promixal region 2 in some studies and the distal articulated region 19 also referred to as claw 20 A triangular region covered by soft cuticle arthrodial membrane may occur on the ventral side between podomeres and provide flexibility 21 11 Their purported pre ocular and protocerebral origin suggest they are homologous to the primary antennae of Onychophora and the labrum of Euarthropoda all arose from ocular somite 17 9 while subsequent studies also suggest a deutocerebral origin and homologous with the chelicerae of Chelicerata and the antennae or great appendages of other arthropods all arose from post ocular somite 1 22 Since the morphology of the frontal appendages especially those of the spines always differs between species it is one of the most important means of species identification 19 In fact many radiodonts are only known from a handful of fossilized frontal appendages 21 19 nbsp Frontal appendages of Anomalocarididae Amplectobeluidae and possibly related species nbsp Frontal appendages of Tamisiocarididae nbsp Frontal appendages of Hurdiidae Oral cone edit nbsp Oral cones of various radiodonts 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 jaws in previous studies 6 3 or 4 tooth plates might be enlarged giving the oral cone a triradial e g Anomalocaris Echidnacaris or tetraradial e g Hurdiidae Lyrarapax appearance 23 12 24 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 8 3 Detail reconstruction of some amplectobeluid oral cones are speculative but they possibly did not present a typical radial arrangement 4 1 Head sclerites eyes and trunk edit nbsp Head sclerite complexes of various radiodonts Three head sclerite carapace complex formed by a central H element anterior sclerite or head shield and a pair of P elements lateral sclerites cover the dorsal and laterovental surface of the animal s head 3 The P elements may connect to each other as well as the H element by a narrow anterior extension P element neck or beak 8 3 The head sclerites are small and ovoid in Anomalocarididae and Amplectobeluidae 4 3 but often enlarged in Hurdiidae corresponded to their distinct body shapes streamlined in Anomalocarididae Amplectobeluidae but often compact in Hurdiidae 3 The head bore two stalked compound eyes which may have had mobility 25 and are located between the gaps formed by the posterior regions of the H element and P elements 8 3 The compound eyes of Echidnacaris are exceptionally unstalked 13 Some species possess an additional median eye behind the H element 22 nbsp nbsp Anterior region of two generized Anomalocaris and Hurdiid radiodont showing distinct morphology A Dorsal view B Ventral view Fa Frontal appendage He H element Pe P element Ey Eye Oc Oral cone Af Anterior neck flap Bf Vf Ventral flap Sb Setal blade Contrary to the original diagnosis the division of body segments segmental boundaries can be visible externally 10 5 3 and no known member of Radiodonta except the putative radiodont Cucumericrus 10 26 is known to have pediform trunk appendages legs 27 The trunk has numerous body segments somites tapering from anterior to posterior with the anterior three or four segments significantly constricted into a neck region 3 nbsp Variations of radiodont body flaps nbsp The movement of radiodont flapping appendages nbsp Ventral view of a generalized GLS bearing radiodont showing gnathobase like structures GLSs associated with reduced anterior flaps The trunk appendages were fin like body flaps lateral flaps or lobes in some studies usually one pair of ventral flaps per body segment each slightly overlapping the one more anterior to it but additional non overlapping sets of small dorsal flaps may occur in some Hurdiid species 10 The flaps may have numerous vein like structures referred to as strengthening rays 5 flap rays 3 tranverse rods 10 transverse lines 28 or veins 29 The flaps on the neck region referred to as reduced flaps 4 neck flaps 5 head flaps 27 anterior flaps 30 or differentiated flaps 18 are significantly reduced In some species jaw like feeding appendages called gnathobase like structures GLSs arose from each of the bases of their reduced neck flaps 4 1 Numerous elongated blade like extensions referred to as lanceolate blades or lamellae 3 arranged in a row forming bands of gill like structures known as setal blades covered the dorsal surface of each body segment 10 At least in Aegirocassis each of the lanceolate blades are covered in wrinkles 10 The ventral flaps may be homologous to the endopod of the biramous limbs of euarthropods and lobopodous limbs lobopods of gilled lobopodians and the dorsal flaps and setal blades may be homologous to the exite and gill bearing dorsal flaps of the former taxa 31 10 The trunk may end either with a tail fan compose of 1 to 3 pairs of blades 29 27 3 a pair of long furcae 29 12 3 an elongated terminal structure 27 or a featureless blunt tip 10 nbsp Stanleycaris Hurdia Aegirocassis Peytoia and Cambroraster are all examples of hurdiid radiodonts These were the most diverse and long lasting of the radiodont families surviving from the Cambrian up until the Devonian nbsp Anomalocaris is a member of the anomalocarididae family which at one point included all radiodonts but now only includes a few genera such as Lenisicaris nbsp Amplectobelua and Lyrarapax are representatives of the amplectobeluidae which is a very inclusive family of mainly Chinese radiodonts nbsp Echidnacaris and Tamisiocaris are examples of the family tamisiocarididae which were exclusively suspension feeding radiodonts from the Cambrian Internal structures edit nbsp digestive system of a radiodont nbsp Various interpretations of radiodont brain A after Cong et al 2014 9 B after Moysiuk amp Caron 2022 22 Traces of muscles digestive system and nervous system were described from some radiodont fossils Pairs of well developed muscles were connected to the ventral flaps located at the lateral cavities of each body segment 27 9 Between the lateral muscles is a sophisticated digestive system formed by a widening of the foregut and hindgut both connected by a narrow midgut associated with six pairs of gut divercula digestive glands 27 5 32 The brain of radiodonts was simpler than the three segmented compose of pro deuto and tritocerebrum brains of euarthropods but further interpretations differ between studies Based on Cong et al 2014 the brain composed of only one brain segment originating from the ocular somite the protocerebrum The nerves of the frontal appendages and compound eyes arose from the anterior and lateral regions of the brain 9 17 Based on Moysiuk amp Caron 2022 the frontal appendage nerves arose from the ventral deutocerebrum the second brain segment The previous frontal appendage nerves actually represent median eye nerve 22 In both interpretations posterior to the brain was a pair of apparently unfused ventral nerve cords which ran through the animal s neck region 9 22 Paleoecology editPhysiology edit nbsp Paleoecological reconstruction of a group of Cambroraster swimming over a brine seep 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 33 34 Pairs of dorsal flaps which make up a tail fan in some species may have helped steering and or stabilizing the animal during locomotion 10 35 In Anomalocaris morphology of the tail fan even suggests it could rapidly change its swimming direction efficiently 36 On the other hand some hurdiids have features significantly specialized for a nektobenthic lifestyle such as Cambroraster with its dome like H element similar to the carapace of a horseshoe crab 3 Bands of setal blades with wrinkling lanceolate blades may have increased the surface area suggesting they were gills providing the animal s respiratory function 27 10 Abundance of the remains of scleritzed structures such as disarticulated frontal appendages and head sclerite complexes suggest that mass moulting events may have occurred among radiodonts 10 3 a behavior which also has been reported in some other Cambrian arthropods such as trilobites 37 Diet edit nbsp Anomalocaris canadensis nbsp Amplectobelua stephenensis nbsp Caryosyntrips camurus nbsp Tamisiocaris borealis nbsp Peytoia nathorsti nbsp Cambroraster falcatusSuggested frontal appendage mobility and movement of various radiodonts 21 11 Radiodonts had diverse feeding strategies which could be categorized as raptorial predators sediment sifters or suspension filter feeders 2 38 11 39 40 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 26 21 4 11 With the smaller head carapace complex and large surface of arthrodial membranes frontal appendages of these taxa had greater flexibility 12 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 passing food items towards the well developed oral cone 3 11 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 7 10 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 21 41 Oral cones of radiodonts may have been used for suction and or biting 23 38 3 Together with the great variety of frontal appendages in different species of radiodonts differentiation of oral cones between species suggests preferences of different diets as well 38 11 For example the triradial oral cone of Anomalocaris with irregular tuberculated toothplates and a small opening may have been adapted to small and nektonic prey 23 11 while the rigid tetraradial oral cones of Peytoia Titanokorys Hurdia and one isolated oral cone attributed to Cambroraster with a larger opening and sometimes additional tooth plates may have been capable to consume larger food items relative to their body size and probably benthic or endobenthic prey 23 38 3 Classification editTaxonomic affinities edit Ecdysozoa Cycloneuralia Priapulida nbsp and relatives Panarthropoda Onychophora nbsp Tardigrada nbsp Lobopodian grade paraphyletic nbsp Siberiid lobopodians nbsp Pambdelurion nbsp Kerygmachela nbsp Opabiniidae nbsp Radiodonta nbsp Euarthropoda nbsp Summarized phylogeny between Radiodonta and other Ecdysozoan taxa 42 nbsp The opabiniids Opabinia top and Utaurora bottom were close relatives of the radiodonts nbsp The radiodont opabiniid euarthropod intermediate Kylinxia shares many of the characteristics found in both dinocaridids and euarthropods nbsp A life reconstruction of the basal deuteropod Erratus which helped reveal the evolution of arthropod trunk appendages nbsp Mieridduryn is a dinocaridid panarthropod from the Middle Ordovician that shares traits with both opabiniids and radiodonts Most phylogenetic analyses suggest that radiodonts alongside opabiniids Opabinia and Utaurora 43 are stem group arthropods just basal to deuteropoda 42 a clade including upper stem e g fuxianhuiids and bivalved arthropods and crown Euarthropoda e g Artiopoda Chelicerata and Mandibulata 8 44 45 46 47 48 7 9 10 2 3 30 18 39 40 49 50 43 This interpretation is supported by numerous arthropod groundplan found on radiodonts and opabiniids such as stalked compound eyes 25 digestive glands 32 trunk appendages forming by dorsal and ventral elements precursor of arthropod biramous appendages 10 50 Compared to opabiniids which possess posterior mouth opening and fused frontalmost appendages comparable to euarthropod posterior facing labrum hypostome complex 17 43 radiodonts on the other hand featured euarthropod like dorsal sclerite H element and arthropodization frontal appendages on their head regions 51 17 43 alongside cuticularized gut termini 27 The fact that both radiodonts and opabiniids lack exoskeleton on their trunk region suggests that the origin of compound eyes and arthropodization segmented appendages precede arthrodization full set of trunk exoskeleton in the arthropod stem lineage 42 52 53 The constricted neck region with feeding appendicular structures of some radiodont may also shed light on the origin of the sophisticated arthropod head which was formed by the fusion of multiple anterior body segments 4 17 Basal deuteropods that possess a mixture of radiodont opabiniid characters like Kylinxia and Erratus may represent intermediate forms between radiodonts opabiniids and other euarthropods 18 50 nbsp The siberiid lobopodians Siberion upper left Megadictyon bottom center and Jianshanopodia upper right nbsp The gilled lobopodians Pambdelurion left and Kerygmachela right nbsp Megacheira or great appendage arthropods a class of possible stem chelicerate previously thought to be radiodont s close relative Taxa just basal to the radiodont opabiniid and euarthropod branch are gilled lobopodians like Pambdelurion and Kerygmachela which occasionally united under the class Dinocaridida with opabibiids and radiodonts 54 46 They have body flaps digestive glands large presumely compound eyes and specialized frontal appendages like the former taxa but their frontal appendages are not arthropodized nor fused eyes sessile gill like structures less prominent and certainlly bore lobopod underneath each of their flaps 55 10 56 43 Taxa even basal to gilled lobopodians are siberiids like Megadictyon and Jianshanopodia 42 a group of lobopodians that 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 57 42 17 58 52 53 Previous studies may suggest radiodonts as a group other than stem arthropods such as a hitherto unknown phylum 33 cycloneuralian worms undergone convergent with arthropods based on the cycloneuralian like radial mouthparts 59 54 stem chelicerate euarthropods alongside megacheirans also known as great appendage arthropods based on the similarity between radiodont frontal appendages megacheiran great appendages and chelicerae 60 or Schinderhannes bartelsi which resolved as a hurdiid radiodont in recent analyses 42 7 10 2 3 39 40 as a species more closely related to euarthropods than other radiodonts based on some putative euarthropod like features found on Schinderhannes 35 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 61 radiodonts lacking definitive euarthropod features such as trunk tergites and multiple head appendages 42 and the megacheiran great appendages were considered to be deutocerebral 62 63 which could be non homologous to the radiodont protocerebral frontal appendages 9 17 putative euarthropod characters found on the single Schinderhannes fossil is questionable and may present other radiodont like structures 42 Interrelationships edit Caryosyntrips nbsp Tamisiocarididae Houcaris saron nbsp Anomalocaris briggsi nbsp Tamisiocaris nbsp Anomalocarididae Amplectobeluidae Laminacaris nbsp Houcaris magnabasis nbsp Anomalocaris nbsp Lyrarapax nbsp Amplectobelua nbsp Anomalocaris kunmingensis nbsp Ramskoeldia consimilis nbsp Ramskoeldia platyacantha nbsp Paranomalocaris nbsp Hurdiidae Peytoia nbsp cf Peytoia nbsp Stanleycaris nbsp Schinderhannes nbsp Aegirocassis nbsp Hurdia nbsp Pahvantia nbsp Cambroraster nbsp Titanokorys nbsp Cordaticaris nbsp Euarthropoda Phylogeny of Radiodonta after Moysiuk amp Caron 2021 39 Traditionally all radiodont species have been placed within one family Anomalocarididae 6 hence the previous common name anomalocaridid 26 8 and it was still occasionally used to refer the whole order even after reclassification 9 10 Since the reassignment done by Vinther et al 2014 most of the radiodont species were reclassified within three new families Amplectobeluidae Tamisiocarididae 2 3 formerly Cetiocaridae 7 and Hurdiidae 7 10 2 3 Including Anomalocarididae the four recent radiodont families may form the clade Anomalocarida 7 The original description of the order Radiodonta included Anomalocaris Laggania later known as Peytoia Hurdia Proboscicaris Amplectobelua Cucumericrus and Parapeytoia 6 However Proboscicaris is now regarded as a junior synonym of Hurdia and Parapeytoia is considered to be a Megacheiran 8 27 10 Due to the limited discovery The position of Cucumericrus within Radiodonta is unclear as it was either unselected by phylogenetic analysis 7 3 2 39 40 or resolved in a polytomy with Radiodonta and Euarthropoda 10 12 nbsp One of the poorly known body parts trunk appendage of Cucumericrus decoratus this species may not represent a true radiodont nbsp Frontal appendage of Echidnacaris briggsi a tamisiocarid radiodont that was once suggested to belong to the Anomalocaris genus until its description in 2023 The first in depth phylogenetic analysis of Radiodonta was conducted by Vinther et al in 2014 7 followed by a handful of subsequest studies with more or less modified results 9 10 2 12 3 39 40 43 In most analysis Caryosyntrips is the basal most genus but either resolved in a polytomy with other radiodonts and Euarthropoda alongside Cucumericrus if included 10 12 or outside of Radiodonta casting doubt on its radiodont affinity 64 With the exclusion of questionable Caryosyntrips and Cucumericrus the monophyly of Radiodonta is widely supported 7 9 10 2 12 3 39 40 with a few results suggest possible paraphyly either the Anomalocarididae Amplectobeluidae clade or Hurdiidae sister to Euarthropoda 30 43 Putative synapomorphies of monophyletic Radiodonta including tripartite head sclerite complex and differentiated neck region 3 The genus Anomalocaris in a broader sense always found to be polyphyletic usually with Anomalocaris kunmingensis and Anomalocaris briggsi resolved as a member of Amplectobeluidae and Tamisiocarididae respectively 7 9 10 2 3 39 40 Interrelationship of Amplectobeluidae is uncertain as the amplectobeluid affinities of Lyrarapax and Ramskoeldia were occasionally questioned 1 3 40 Monophyly of the speciose family Hurdiidae was recovered by most analysis and well supported by several synapomorphies e g distal articulated region of frontal appendage with proximal 5 podomeres bearing subequal endites 19 3 Tamisiocarididae was often suggested to be sister group of Hurdiidae in 2010s 7 10 2 3 but this position became questionable in subsequent studies 22 24 Radiodonta Cucumericrus 26 radiodont affinity questionable 65 64 Caryosyntrips 21 radiodont affinity questionable 64 Anomalocarida Paranomalocaris 66 placed within Anomalocarididae by some studies 12 67 Laminacaris 68 placed within Amplectobeluidae by some studies 2 Houcaris either placed within Anomalocarididae 10 12 43 Amplectobeluidae 7 2 or Tamisiocarididae 15 39 Innovatiocaris 69 Anomalocarididae Anomalocaris in a broader sense some species may placed within the other families 7 10 Lenisicaris 20 Amplectobeluidae Lyrarapax 9 position questioned by some studies 1 Amplectobelua 26 Ramskoeldia 1 position questioned by some studies 3 Guanshancaris 67 70 Tamisiocarididae Tamisiocaris Echidnacaris Houcaris Hurdiidae Peytoiidae 64 Aegirocassisinae 71 Aegirocassis 10 Pseudoangustidontus Peytoia Schinderhannes Hurdia Stanleycaris 72 Pahvantia 2 Ursulinacaris 19 Cambroraster 3 Zhenghecaris putative hurdiid radiodont 65 Cordaticaris 73 Buccaspinea 74 Titanokorys 40 Described species of Radiodonta Species Original description Year named Family Age Location Frontal appendage Head sclerite complex Cucumericrus decoratus Hou Bergstrom amp Ahlberg 1995 26 unassigned Cambrian Stage 3 nbsp China Unknown Unknown Caryosyntrips serratus Daley amp Budd 2010 21 unassigned Wuliuan Drumian nbsp Canada nbsp United States nbsp Unknown Caryosyntrips camurus Pates amp Daley 2017 41 unassigned Wuliuan nbsp Canada nbsp United States nbsp Incomplete 74 Caryosyntrips durus Pates amp Daley 2017 41 unassigned Drumian nbsp United States nbsp Unknown Paranomalocaris multisegmentalis Wang Huang amp Hu 2013 66 Anomalocarididae Cambrian Stage 4 nbsp China nbsp Unknown Paranomalocaris simplex Jiao Pates Lerosey Aubril Ortega Hernandez Yang Lan Zhang 2021 67 Anomalocarididae Cambrian Stage 4 nbsp China nbsp Unknown Laminacaris chimera Guo Pates Cong Daley Edgecombe Chen amp Hou 2018 68 controversial Cambrian Stage 3 nbsp China nbsp Unknown Innovatiocaris maotianshanensis Zeng Zhao Zhu 2022 69 unassigned Cambrian Stage 3 nbsp China nbsp P element unknown 69 Innovatiocaris multispiniformis Zeng Zhao Zhu 2022 69 unassigned Cambrian Stage 3 nbsp China nbsp Unknown Anomalocaris canadensis Whiteaves 1892 75 Anomalocarididae Wuliuan nbsp United States nbsp nbsp Lenisicaris pennsylvanica formerly Anomalocaris pennsylvanica 20 Resser 1929 Anomalocarididae Cambrian Stage 3 nbsp United States nbsp Unknown Lenisicaris lupata Wu Ma Lin Sun Zhang amp Fu 2021 20 Anomalocarididae Cambrian Stage 3 nbsp China nbsp Unknown Anomalocaris daleyae Paterson Garcia Bellidob amp Edgecombe 2023 Anomalocarididae Cambrian Stage 4 nbsp Australia nbsp Unknown Houcaris magnabasis formerly Anomalocaris magnabasis 15 Pates Daley Edgecombe Cong amp Lieberman 2019 controversial Cambrian Stage 4 nbsp United States nbsp Unknown Houcaris saron formerly Anomalocaris saron 15 Hou Bergstrom amp Ahlberg 1995 controversial Cambrian Stage 3 nbsp China nbsp Unknown Echidnacaris briggsi 24 Nedin 1995 Tamisiocarididae Cambrian Stage 4 nbsp Australia nbsp Possible H element and unique lateral sclerites associated with compound eyes 13 24 Ramskoeldia platyacantha Cong Edgecombe Daley Guo Pates amp Hou 2018 1 Amplectobeluidae Cambrian Stage 3 nbsp China nbsp Incomplete 1 Ramskoeldia consimilis Cong Edgecombe Daley Guo Pates amp Hou 2018 1 Amplectobeluidae Cambrian Stage 3 nbsp China nbsp Incomplete 1 Lyrarapax unguispinus Cong Ma Hou Edgecombe amp Strausfield 2014 9 Amplectobeluidae Cambrian Stage 3 nbsp China nbsp P element neck unknown Lyrarapax trilobus Cong Daley Edgecombe Hou amp Chen 2016 5 Amplectobeluidae Cambrian Stage 3 nbsp China nbsp P element unknown Amplectobelua symbrachiata Hou Bergstrom amp Ahlberg 1995 26 Amplectobeluidae Cambrian Stage 3 nbsp China nbsp nbsp Amplectobelua stephenensis Daley amp Budd 2010 21 Amplectobeluidae Wuliuan nbsp United States nbsp Unknown Guanshancaris kunmingensis Zhang et al 2023 70 Amplectobeluidae Cambrian Stage 4 nbsp China nbsp Unknown Tamisiocaris borealis Daley amp Peel 2010 Tamisiocarididae Cambrian Stage 3 nbsp Greenland nbsp Incomplete 7 Ursulinacaris grallae Pates Daley amp Butterfield 2019 Hurdiidae Wuliuan nbsp Canada nbsp Unknown Schinderhannes bartelsi Kuhl Briggs amp Rust 2009 35 Hurdiidae Emsian nbsp Germany Incomplete 3 Incomplete 3 Stanleycaris hirpex Pates Daley amp Ortega Hernandez 2018 72 Hurdiidae Wuliuan nbsp Canada nbsp P element is unknown possibly absent 22 Peytoia nathorsti Walcott 1911 76 Hurdiidae Wuliuan Drumian nbsp Canada nbsp United States nbsp Incomplete 3 Peytoia infercambriensis formerly Cassubia infercambriensis 77 Lendzion 1975 Hurdiidae Cambrian Stage 3 nbsp Poland nbsp Unknown Aegirocassis benmoulai Van Roy Daley amp Briggs 2015 10 Hurdiidae Aegirocassisinae Tremadocian nbsp Morocco nbsp nbsp Hurdia victoria Walcott 1912 78 Hurdiidae Wuliuan Drumian nbsp Canada nbsp Czechia nbsp nbsp Hurdia triangulata Walcott 1912 78 Hurdiidae Wuliuan nbsp Canada nbsp nbsp Cambroraster falcatus Moysiuk amp Caron 2019 3 Hurdiidae Wuliuan nbsp Canada nbsp nbsp Pahvantia hastata Robison amp Richards 1981 Hurdiidae Drumian nbsp United States nbsp nbsp Cordaticaris striatus Sun Zeng amp Zhao 2020 73 Hurdiidae Drumian nbsp China Incomplete 73 nbsp Zhenghecaris shankouensis Vanner Chen Huang Charbonnier amp Wang 2006 Hurdiidae Cambrian Stage 3 nbsp China Unknown nbsp Buccaspinea cooperi Pates Lerosey Aubril Daley Kier Bonino amp Ortega Hernandez 2021 74 Hurdiidae Drumian nbsp United States nbsp Unknown Titanokorys gainesi Caron amp Moysiuk 2021 40 Hurdiidae Wuliuan nbsp Canada nbsp nbsp Pseudoangustidontus duplospineus Van Roy amp Tetlie 2006 Hurdiidae Aegirocassisinae Tremadocian nbsp Morocco nbsp Unknown Pseudoangustidontus izdigua Potin Gueriau amp Daley 2023 Hurdiidae Aegirocassisinae Tremadocian nbsp Morocco nbsp Incomplete 71 History edit nbsp Body specimen of Peytoia nathorsti the original Laggania cambria nbsp Frontal appendage of Anomalocaris canadensis nbsp Oral cone of Peytoia nathorsti nbsp H element of Hurdia victoria nbsp Paired frontal appendages from an unnamed hurdiid radiodont 39 The history of radiodonts is complex Incomplete specimens pertaining to different body parts of the same species had historically been interpreted as belonging to different species and even different phyla 6 8 Prior to their recognition as a group radiodont specimens had been assigned to five different phyla Porifera Cnidaria Echinodermata Annelida and Arthropoda 6 The first known radiodont specimens were collected from the trilobite beds of Mount Stephen by Richard G McConnell of the Geological Survey of Canada in 1886 6 or 1888 75 These specimens were named Anomalocaris canadensis in 1892 by GSC paleontologist Joseph Whiteaves 75 Whiteaves interpreted the specimens now known to be isolated frontal appendages as the abdomen of a phyllocarid crustacean 75 Additional radiodont specimens were described in 1911 by Charles Walcott 76 He interpreted an isolated oral cone which he named Peytoia nathorsti as a jellyfish and a poorly preserved but relatively complete specimen which he named Laggania cambria as a holothurian 76 In 1912 Walcott named Hurdia victoria and H triangulata based on isolated H elements which he interpreted as the carapaces of crustaceans 78 Isolated frontal appendages of Peytoia and Hurdia collectively known as Appendage F in Briggs 1979 were all identified as those of Sidneyia at that time 76 A Hurdia P element was named Proboscicaris in 1962 and interpreted as the carapace of a bivalved arthropod 79 The Geological Survey of Canada initiated a revision of Burgess Shale fossils in 1966 overseen by Cambridge University paleontologist Harry B Whittington 6 This revision would ultimately lead to the discovery of the complete radiodont body plan In 1978 Simon Conway Morris recognized that the mouthparts of Laggania were Peytoia like but he interpreted this as evidence that it was a composite fossil made up of a Peytoia jellyfish and a sponge 80 In 1979 Derek Briggs recognized that the fossils of Anomalocaris were appendages not abdomens but interpreted them as walking legs alongside Appendage F 81 It was not until 1985 that the true nature of the fossils of Anomalocaris Laggania and Peytoia was recognized and they were all assigned to a single genus Anomalocaris 33 Subsequently it was recognized that Anomalocaris was a distinct form from the other two resulting in a split into two genera the latter of which was variously named Laggania and Peytoia until it was determined that both represent the same species and Peytoia had priority 23 It was later recognized that some of the fossils assigned to these taxa belonged to another form which was recognized as bearing a carapace made up of Hurdia and Proboscicaris elements Finally in 2009 these specimens were redescribed as Hurdia 8 Even after these recognitions partial misidentifications e g oral cone and frontal appendages of Peytoia had been assigned to Anomalocaris 6 and Hurdia 8 respectively had been revealed by subsequent studies as well 23 82 The taxon Radiodonta itself was coined in 1996 by Desmond Collins after it was established that Anomalocaris and its kin represented a distinctive lineage with arthropod affinities rather than a hitherto unknown phylum 6 Collins also established the class Dinocarida to contain the order Radiodonta as well as the Opabiniidae which he recognized as distinct due to its lacking the distinctive oral cone structure of radiodonts 6 Radiodonta was first given a phylogenetic definition in 2014 7 Radiodonta was originally viewed as containing a single family Anomalocarididae but it was divided into four families in 2014 Amplectobeluidae Anomalocarididae Cetiocaridae and Hurdiidae 7 The name Cetiocaridae did not conform to the International Code of Zoological Nomenclature and so was renamed Tamisiocarididae in 2019 83 Until the 2010s radiodonts were typically considered to be uniformly large apex predators but discoveries of new species over the course of that decade led to a considerable increase in the known ecological and morphological diversity of the group 7 10 2 3 84 74 39 40 References edit a b c d e f g h i j k Cong Pei Yun Edgecombe Gregory D Daley Allison C Guo Jin Pates Stephen Hou Xian Guang 2018 New radiodonts with gnathobase like structures from the Cambrian Chengjiang biota and implications for the systematics of Radiodonta Papers in Palaeontology 4 4 605 621 doi 10 1002 spp2 1219 ISSN 2056 2802 S2CID 90258934 a b c d e f g h i j k l m n o p q r s t u Lerosey Aubril Rudy Pates Stephen 2018 09 14 New suspension feeding radiodont suggests evolution of microplanktivory in 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