Product Code Database
Hibbertopteridae (the name deriving from the type genus Hibbertopterus, meaning "Hibbert's wing") is a family of Eurypterid, an extinct group of aquatic Arthropod. They were members of the superfamily Mycteropoidea. Hibbertopterids were large, broad and heavy animals unlike virtually every other group of eurypterids, which are commonly streamlined and lightweight. Their bizarre morphology is so unusual that they in the past have been thought to represent an entirely distinct order of Chelicerata. Fossils of the family first appear in deposits of Middle Devonian age and the last known fossils representing hibbertopterids are known from deposits of Late Permian age. The hibbertopterids represent the last known living eurypterids, going extinct during the Permian–Triassic extinction event or shortly before.
Although eurypterids are commonly known as "sea scorpions", hibbertopterids inhabited freshwater swamps and rivers and were unable to swim since they lacked swimming paddles, a feature they shared with their entire suborder, the Stylonurina. Hibbertopterids fed using a method referred to as sweep-feeding, in which the animal would rake through the soft sediment of their substrate with specialised blades on their forward-facing appendages to capture small invertebrates. Though this method of feeding was present in other mycteropoids and in Stylonuroidea, it was at its most advanced stage within the derived Hibbertopteridae.
The hibbertopterids were the largest of all stylonurine eurypterids, with both Hibbertopterus at 180–200 centimetres (5.9–6.6 ft) and Campylocephalus at 140 centimetres (4.6 feet) representing giant eurypterids in their own right. Though longer eurypterids are known from the Eurypterina suborder, notably the largest known arthropod of all time, Jaekelopterus, at 230–260 centimetres (7.5–8.5 ft), hibbertopterids were far bulkier than any of the largest eurypterine eurypterids and as such likely represent the overall heaviest animals in the order.
Although Vernonopterus has been estimated to have reached lengths of "just" 50 centimetres (19.7 inches), both Campylocephalus and Hibbertopterus represent true giant eurypterids. The largest specimens of Campylocephalus suggests a size of 140 centimetres (4.6 feet) and at 180–200 centimetres (5.9–6.6 ft), Hibbertopterus scouleri was the largest eurypterid in the entire Stylonurina suborder. That hibbertopterids were so broad and compact probably means they were the overall heaviest eurypterids, surpassing longer forms, such as the light-weight Pterygotidae, in weight.
Compared to other eurypterids, hibbertopterids were highly unusual. Their broad and heavy bodies go against the general eurypterid trend of being streamlined and lightweight and like all other Stylonurina eurypterids, they lack swimming paddles. Out of their six pairs of limbs, the second, third and fourth pairs were forward-facing and specialised for gathering food. The leg segments of these limbs were covered with long spines and their ends were covered with sensory organs. The fourth pair of limbs, although also used in feeding, was also used for locomotion, as were pairs five and six. As such, hibbertopterids would have been hexapods (walking on six legs).Jeram, Andrew J.; Selden, Paul A. (1993). "Eurypterids from the Viséan of East Kirkton, West Lothian, Scotland". Earth and Environmental Science Transactions of the Royal Society of Edinburgh. 84 (3-4): 301–308. doi:. ISSN .
Due to the fragmentary nature of both Campylocephalus and Vernonopterus, confidently establishing distinguishing features between the three genera is difficult. Distinguishing Campylocephalus from Hibbertopterus is primarily the fact that the carapace (exoskeleton covering the head) of Campylocephalus is slightly narrower and is broadest at its midsection, rather than at the part which connects to the rest of the body (as it is in Hibbertopterus). The fragmentary Vernonopterus can be distinguished from the others by its distinctive and unique ornamentation.Hughes, Emily Samantha (2019), " Discerning the Diets of Sweep-Feeding Eurypterids Through Analyses of Mesh-Modified Appendage Armature". Graduate Theses, Dissertations, and Problem Reports. 3890.
Preserved cuticle of hibbertopterids is thinner than what is expected of arthropods of their size, though this might be explained by the possibility that only an outer exocuticular region has been preserved in their fossils.
The morphology of the hibbertopterids was so unusual that they have been thought to be an order separate to Eurypterida. Recent work however confirms them to be derived members of the suborder Stylonurina, closely related to Drepanopterus and the Mycteroptidae.
The features of genera Campylocephalus and Vernonopterus makes it clear that both genera represent hibbertopterid eurypterids, but the incomplete nature of all fossil specimens referred to them make any further study of the precise Phylogenetics relationships within the Hibbertopteridae difficult. Both genera could even represent further synonyms of Hibbertopterus itself, which would make the family Monotypic taxon (containing only one immediately subordinate taxon), though the highly incomplete nature of their remains again makes that hypothesis impossible to confirm.
The cladogram below is adapted from Lamsdell (2012), collapsed to only show the superfamily Mycteropoidea.
Sweep-feeding strategies evolved independently in two of the four stylonurine superfamilies, the Stylonuroidea and the Mycteropoidea. In both superfamilies, the adaptations to this lifestyle involves modifications to the spines on their anterior prosomal appendages for raking through the substrate of their habitats. Stylonuroidea have fixed spines on appendages II-IV which could have been used as dragnets to rake through the sediments and thus entangling anything in their way. Mycteropoidea show even more extreme adaptations towards a sweep-feeding lifestyle. These adaptations are taken to an even further extreme within the Hibbertopteridae, with appendage IV possessing a blade alongside the appendages II-III (which also have blades in other hibbertopteroids).
The coxae in Hibbertopterus are reduced, leading to part of the food masticatory process being assumed by the laden (plates overlaying the coxae). Some of its species have even further adaptations towards sweep-feeding than other mycteropoids, with its blades modified into comb-like rachis that could entrap smaller prey or other organic food particles. With its coxae being large, it is likely that some species of Hibbertopterus would also feed on relatively large invertebrates when able to.
|
|
