Hubbry Logo
PachycormiformesPachycormiformesMain
Open search
Pachycormiformes
Community hub
Pachycormiformes
logo
8 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Contribute something
Pachycormiformes
Pachycormiformes
Pachycormiformes
View on Wikipedia
from Wikipedia

Pachycormiformes
Temporal range: Early Jurassic - Late Cretaceous, Toarcian–Maastrichtian
Skeleton of Pachycormus
Skeleton of Orthocormus
Scientific classification Edit this classification
Kingdom: Animalia
Phylum: Chordata
Class: Actinopterygii
Infraclass: Teleosteomorpha
Division: Aspidorhynchei
Order: Pachycormiformes
Berg 1937
Family: Pachycormidae
Woodward, 1895
Type genus
Pachycormus
Agassiz, 1833
Genera

See text

Synonyms[1]
  • Diphyodontidae Jordan, 1923
  • Erisichtheidae Cope, 1877b
  • Microlepidoti Zittel, 1887
  • Pelecopteridae Cope, 1875
  • Protosphyraenidae Lydekker, 1889
  • Sauropsidae Cope, 1877a
  • Saurotomini [Saurostomini] Bonaparte, 1846 corrig. Bonaparte 1850a

Pachycormiformes is an extinct order of marine ray-finned fish known from the Early Jurassic to the end of the Cretaceous. It only includes a single family, Pachycormidae. They were characterized by having serrated pectoral fins (though more recent studies demonstrated that fin shape diversity in this group was high[2]), reduced pelvic fins and a bony rostrum. Pachycormiformes are morphologically diverse, containing both tuna and swordfish-like carnivorous forms, as well as edentulous suspension-feeding forms.

Description

[edit]
Size comparison of various species of Pachycormiform fish

Pachycormiformes are united by "a compound bone (rostrodermethmoid) forming the anterodorsal border of the mouth; a reduced coronoid process of the mandible; absence of supraorbitals associated with a dermosphenotic defining the dorsal margin of the orbit; two large, plate-like suborbital bones posterior to the infraorbitals; long, slender pectoral fins; asymmetrical branching of pectoral fin lepidotrichia; considerable overlap of the hypurals by caudal fin rays (hypurostegy); and the presence of distinctive uroneural-like ossifications of the caudal fin endoskeleton".[3] Pachycormiformes varied substantially in size, from medium-sized fishes around 40–111 centimetres (1.31–3.64 ft) in length like the macropredator Pachycormus,[4] to the largest known ray-finned fish, the suspension feeding Leedsichthys, which is estimated to have reached a maximum length of around 16 metres (52 ft).[5]

Relationships

[edit]

Pachycormiformes are generally interpreted as basal members of Teleosteomorpha, the group that includes all fish more closely related to modern teleosts than to Holostei (the group containing bowfin and gars), often they have been considered to be the sister group of the Aspidorhynchiformes.[6][7]

[edit]

Taxonomy

[edit]

Taxonomy according to Cooper et al. (2022):[8]

Cladistics according to Friedman et al. (2010).[10]

Pachycormiformes

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Pachycormiformes

View on Grokipedia
from Grokipedia
Pachycormiformes is an extinct order of marine ray-finned fishes () within the subclass Teleosteomorpha, consisting of stem-group teleosts that thrived as a diverse during the era. Known from fossil deposits spanning the ( stage) to the ( stage), these fishes inhabited ancient oceans across , the , , , and the , with over 17 genera assigned to the single family Pachycormidae. Members of Pachycormiformes exhibited a wide range of body sizes and ecological roles, from small to large-bodied predators with toothed jaws to edentulous giants adapted for suspension-feeding, analogous to modern whales in their filter-feeding strategy. Diagnostic features include a compound rostrodermethmoid bone forming the anterodorsal border of the , reduced coronoid process on the , absence of supraorbital bones with the dermosphenotic defining the dorsal margin, two large plate-like suborbital bones, and elongate, slender with asymmetrical branching lepidotrichia. Many taxa also displayed reduced squamation, a deeply forked caudal , and often absent or reduced pelvic fins, reflecting adaptations for agile swimming in open marine environments. Phylogenetically, Pachycormiformes occupy a critical position in the transition from holostean to teleostean fishes, representing an early radiation of neopterygian actinopterygians with rapid trophic diversification in the Early Jurassic. The order is divided into subfamilies such as Hypsocorminae (predatory, toothed forms) and Asthenocorminae (suspension-feeders with elongated skulls and specialized gill rakers), with suspension-feeding evolving by the Middle Jurassic. Notable genera include Pachycormus (Early Jurassic predator from Europe), Leedsichthys (the largest known fish, up to 16 meters long, a Late Jurassic filter-feeder), and Bonnerichthys (Late Cretaceous giant from North America). Exceptional fossil preservation, such as three-dimensional specimens from sites like Strawberry Bank in the UK and the Posidonienschiefer Formation in Germany, has revealed details of their cranial osteology, gastrointestinal anatomy (including spiral valves), and pectoral fin diversity, underscoring their evolutionary success over more than 100 million years.

Description

Morphology

Pachycormiformes display a distinctive characterized by a shape in predatory forms, resembling modern tunas, and more robust builds in suspension-feeding taxa, reflecting adaptations to diverse aquatic lifestyles. The order is united by several diagnostic skeletal features, including a compound rostrodermethmoid that forms a prominent bony rostrum at the anterodorsal margin of the mouth, often bearing teeth and separating the premaxillae. This rostrum is a shield-like structure, typically diamond-shaped or wide with a blunt dentigerous margin, contributing to the group's streamlined cranial profile. The pectoral fins are a key synapomorphy, featuring elongated, scythe-like or falciform shapes with serrated leading edges formed by fused lepidotrichia that create a stiffened, blade-like anterior margin. These fins exhibit morphological diversity, including falciform types with prominent posterior fillets and narrower, elongated variants, supporting rapid swimming in open water. Pelvic fins are characteristically reduced or entirely absent across the group, minimizing drag in fast-swimming . The dorsal and anal fins are often elongated and falciform, positioned with the anterior to the anal fin, and featuring segmented rays that narrow into trailing edges for enhanced maneuverability. Integumentary structures include cycloid scales of the amioid type, particularly evident in forms like Pachycormus, consisting of thin basal bony plates overlain by a ganoine layer and lacking complex peg-and-socket articulations. Histological analysis of Pachycormus scales reveals a transitional structure from lepisosteoid to amioid squamation, with reduced mineralization and a smooth external surface, marking an early step toward scale loss in derived pachycormids. Suspension-feeding genera, such as Asthenocormus and Martillichthys, possess specialized gill rakers that are elongate and club-shaped, with pointed projections or finer fimbriations increasing density to approximately 15 per arch or more, facilitating particle filtration. Cranial elements further define the order, with the preopercle displaying a semi-lunate outline, broad ventrally and tapering dorsally into a narrow splint, positioned posterior to the suborbitals. The opercle is triangular and elongate, typically twice as long as deep, with a sloping ventral that overlaps the suboperculum, contributing to an efficient opercular apparatus. These features collectively underscore the morphological coherence of Pachycormiformes while accommodating functional specializations.

Size and Diversity

Pachycormiformes displayed remarkable variation in body size, ranging from small to medium-sized forms approximately 40–111 cm in total length, such as the predatory Pachycormus macropterus, to colossal species like Leedsichthys problematicus that attained lengths of up to 16.5 m. These giants represent some of the largest known ray-finned fishes, with estimates derived from partial skeletons and comparative scaling of skeletal elements like the lepidotrichia and gill rakers. Growth patterns, reconstructed from scale and fin ray histology, reveal rapid initial somatic expansion in early ontogeny, enabling juveniles to reach substantial sizes quickly, followed by slower incremental growth over extended periods. In Leedsichthys, for instance, individuals grew to 1.6 m by age one, with overall growth coefficients of 0.01–0.05 indicating prolonged development, and annuli counts suggesting lifespans of 19–40 years. Similar histological features in Pachycormus scales, including circuli and accretion lines, support comparable early rapid growth phases transitioning to asymptotic rates, consistent with longevities exceeding 20 years. The order's morphological diversity encompassed streamlined, predatory taxa with robust and agile fins, contrasting with edentulous suspension-feeding forms featuring hypertrophied baskets for filter-feeding on . evidence from Pachycormus specimens indicates ontogenetic shifts in body proportions, such as increasing opercle length relative to total length, forming a size-related morphocline, alongside potential inferred from morphospace overlap in cranial metrics. Across geological periods, maximum sizes escalated notably in the , with Early representatives like Pachycormus limited to under 1.1 m, while Middle Leedsichthys exemplified the attainment of extreme .

Evolutionary History

Geological Range and Distribution

Pachycormiformes first appeared in the fossil record during the , specifically the stage approximately 183 million years ago, and persisted until the end of the in the stage around 66 million years ago. Their stratigraphic range spans roughly 117 million years, with the exhibiting its highest taxonomic diversity during the Middle to , particularly from the stage onward, when hypsocormine pachycormids underwent rapid radiation and achieved widespread distribution. This peak likely correlated with eustatic sea-level rises that expanded marine habitats conducive to their diversification. Fossils of Pachycormiformes are globally distributed in marine deposits associated with Laurasian and Gondwanan paleocontinents, reflecting their adaptation to epicontinental seas and open marine environments. Key localities include the Formation in the , which has yielded abundant remains of the giant filter-feeder , and the in , a preserving articulated specimens of predatory forms like Hypsocormus. In the , significant occurrences are documented from Upper strata in , such as the Oxfordian deposits of Cerritos Bayos in northern , which contain diverse pachycormiform elements complementing northern records. Phylogenetic analyses indicate ghost lineages extending back into the for certain subclades, such as hypsocormines, with recent discoveries closing a approximately 17-million-year gap and supporting an early diversification into predatory and suspension-feeding niches during the . The clade's evolutionary radiation during this period involved niche partitioning, with forms adapting to varied trophic levels in expanding seas. Pachycormiformes became extinct at the Cretaceous-Paleogene boundary, coinciding with the global mass that eliminated many large-bodied marine vertebrates. Their disappearance may have been exacerbated by environmental perturbations, including anoxic events in the and increasing competition from diversifying fishes, which filled similar ecological roles in the post-boundary recovery.

Recent Discoveries

In 2025, paleontologists described the first known hypsocormine pachycormid from the Posidonienschiefer Formation in Holzmaden, , represented by specimen SMNS 10014. This discovery, identified through synapomorphies such as specific vertebral and fin features, extends the clade's record back approximately 17 million years from previous occurrences, thereby closing a significant and indicating that hypsocormine origins likely predate the in the Southwestern Germanic Basin of the western Tethys. Also in 2025, researchers reported the first Eurasian record of the suspension-feeding pachycormid Bonnerichthys from deposits in , based on diagnostic fragments exhibiting a thickened anterior edge with a sharp keel and wedge-shaped ossification. These specimens confirm that Bonnerichthys, previously known only from , achieved a among large-bodied, filter-feeding pachycormiforms during the . A 2025 histological analysis of scales from the Pachycormus provided the first description of their scale in the literature, revealing a shift from lepisosteoid-type to amioid-type squamation and characterizing features of scale reduction in the . This study highlights convergent scale reductions in actinopterygians relative to teleosteomorphs and provides insights into evolutionary shifts toward streamlined forms in later pachycormiforms, with implications for biomechanical adaptations in marine environments. In the same year, new evidence from the Abrek Formation in the , Republic of , documented the first occurrences of the swordfish-like pachycormid Protosphyraena, including pectoral fins, a cleithrum, and a hypural plate assigned to P. gibberula comb. nov. These finds, combined with reassessments of material from Russia's Region, expand the genus's range into and underscore its global dispersal during the late . Findings from 2023, published in early 2024, provided direct evidence of predation among pachycormids through the examination of 70 specimens from the 'Schistes bitumineux' of southern , with six preserving octobrachian coleoid gladii in the oesophagus or stomach. Species such as Pachycormus macropterus and Saurostomus esocinus ingested prey like Teudopsis bollensis and Loligosepiidae head-first, suggesting a widespread teuthophagous feeding strategy that links to broader dietary evolution in suspension- and ram-feeding pachycormiforms across the and .

Systematics

Taxonomy

Pachycormiformes is an extinct order of actinopterygian fishes, comprising a single family, Pachycormidae, which was established by Woodward in 1895 based on shared cranial and postcranial features such as a specialized hyomandibula and elongate body form. The family encompasses a range of morphologies from small piscivores to gigantic filter-feeders, with all known taxa assigned to Pachycormidae due to the monotypic nature of the order. Alpha taxonomy within Pachycormiformes is challenging owing to the predominantly fragmentary nature of fossils, which often consist of isolated bones or partial skeletons, leading to historical misidentifications and synonymies. For instance, Cooper et al. (2022) revised the Saurostomus, designating a neotype for the S. esocinus (Agassiz, 1844) and synonymizing it with earlier names such as Pachycormus esocinus and Eugnathus giganteus, highlighting how incomplete preservation has obscured species boundaries. Similarly, the of Leedsichthys, L. problematicus (Woodward, 1889), remains poorly defined due to disarticulated remains, complicating generic assignments across deposits. The order is subdivided into two main subfamilies: Asthenocorminae, which includes basal predatory and early suspension-feeding forms, and Hypsocorminae, representing more derived, advanced taxa with specialized adaptations. Key genera in Asthenocorminae include Pachycormus (, small-bodied predator with needle-like teeth, P. macropterus Agassiz, 1833) and (Middle to , giant filter-feeder reaching up to 16 m, known primarily from L. problematicus). Bonnerichthys (, suspension-feeder with edentulous jaws, B. gladius (Cope, 1873)) also belongs here, extending the lineage into the . Hypsocorminae encompasses diverse predatory forms, such as Orthocormus (, elongate piscivore with robust dentition, type species O. buccatus Egerton, 1858), Hypsocormus (, varied body plans from slender to deep-bodied, including type species H. leedsi Woodward, 1889), and Protosphyraena (, swordfish-like with elongated rostrum and scythe-shaped pectoral fins, type species P. nitida Leidy, 1857). A recent addition is Kaykay (Upper Jurassic of , small hypsocormine with unique scale patterns, type species K. lafken Gouiric-Cavalli et al., 2022), the first endemic genus from the . In November 2025, the oldest known hypsocormine specimen (Hypsocorminae gen. et sp. indet.) was reported from the () Posidonienschiefer Formation in , extending the temporal range of the subfamily by approximately 17 million years and confirming the early divergence of Asthenocorminae and Hypsocorminae. These subdivisions reflect increasing morphological specialization through the , though ongoing revisions continue to refine generic limits.

Phylogenetic Position

Pachycormiformes are consistently resolved as basal members of Teleosteomorpha, the encompassing crown-group Teleostei and its stem relatives, positioning them as stem-group teleosts within ray-finned fishes (). Phylogenetic analyses frequently recover Pachycormiformes as the to Aspidorhynchiformes, together forming a monophyletic of early diverging teleosteomorphs that branched off prior to the diversification of more derived holosteans and crown teleosts. This placement highlights their role in the evolutionary transition from non-teleost actinopterygians to modern teleosts, with cladistic studies emphasizing their position outside the crown-group Teleostei. Several synapomorphies support this phylogenetic position, including a modified pectoral girdle characterized by an elongate cleithrum and that contribute to the distinctive scythe-like pectoral fins, as well as a compound rostral bone termed the rostrodermethmoid, which fuses elements of the and dermethmoid. These features, along with additional traits such as two supramaxillae and a specialized hyomandibula, unite Pachycormiformes and underpin their recovery as a cohesive in matrix-based analyses. Studies by Friedman et al. (2010) and Cooper et al. (2022) have reinforced these synapomorphies through detailed morphological character scoring, demonstrating robust support for their basal teleosteomorph affinities. Relative to crown s, Pachycormiformes represent an extinct lineage of early actinopterygians that underwent significant diversification during the , predating the major radiation of extant groups in the and . This positioning is corroborated by parsimony-based phylogenies that place them as successive outgroups to holostean- clades, underscoring their importance in understanding the stepwise assembly of teleostean innovations. Although the of Pachycormiformes is strongly supported by morphological data across multiple analyses, some early studies debated the inclusion of certain taxa, such as potential with respect to aspidorhynchiforms; however, recent cladistic frameworks affirm their unity. Evidence from estimates for actinopterygian divergences, which calibrate the teleosteomorph split around the , aligns well with the oldest records of Pachycormiformes in the , providing temporal congruence for their basal position.

Paleobiology

Diet and Feeding Mechanisms

Pachycormiformes exhibited a range of feeding strategies, including both predatory and suspension-feeding modes, reflecting adaptations to diverse prey types within Mesozoic marine ecosystems. Predatory forms, such as Pachycormus macropterus and Saurostomus esocinus from the Early Jurassic, possessed sharp teeth and elongated rostra suited for piercing and capturing soft-bodied prey like octobrachian cephalopods. Evidence from stomach contents in these species includes gladii (internal shells) of cephalopods such as Teudopsis bollensis and indeterminate Loligosepiidae, ingested head-first, confirming a teuthophagous diet. Later predatory taxa, like the swordfish-like Protosphyraena from the Late Cretaceous, similarly targeted smaller fish and cephalopods through active pursuit, facilitated by streamlined bodies and falciform pectoral fins that enhanced maneuverability and speed. In contrast, suspension-feeding pachycormiforms, particularly the giants Leedsichthys problematicus and Bonnerichthys gladius, evolved specialized structures for filtering and small crustaceans from seawater. These species lacked oral teeth but featured edentulous jaws and elaborate arrays, with Leedsichthys specimens preserving up to 89 raker elements in a single block, indicative of hundreds overall for sieving minute particles. The , equipped with fine needle-like fanunculi, formed a mesh-like structure for , allowing continuous processing of water volumes while swimming. Feeding mechanisms varied correspondingly: predatory species employed and biting during high-speed chases, with biomechanical analyses of morphology suggesting powerful from heterocercal tails and pectoral fins for prey interception. Suspension-feeders, however, relied on ram ventilation, where forward motion drove water through the oral cavity and over the gill rakers for passive filtration, akin to modern paddlefishes, with elongated hyomandibulae enabling wide gape for efficient capture. This mode supported sustained cruising in open waters, minimizing energy expenditure on . Dietary habits in Pachycormiformes shifted temporally, with representatives predominantly predatory and targeting larger prey like cephalopods, as seen in basal taxa such as Pachycormus. By the , specialized suspension-feeding had emerged, exemplified by , marking the divergence into planktivorous giants. This trend persisted into the , where Bonnerichthys and Rhinconichthys dominated as global filter-feeders, reflecting evolutionary convergence with other pelagic giants and adaptation to increasing abundance in epicontinental seas.

Ecology and Habitat

Pachycormiformes inhabited pelagic marine environments throughout the Era, from the () to the (), with fossil evidence primarily from open-ocean deposits such as the Posidonienschiefer Formation in southwestern , an anoxic black shale indicative of epipelagic to mesopelagic zones. These fishes were distributed globally across and , occurring in formations like the in and the Ameghino Formation in , suggesting adaptation to diverse marine basins influenced by sea-level changes and paleoclimate. Ecologically, Pachycormiformes occupied varied roles within Mesozoic food webs, ranging from active predators to suspension-feeding primary consumers. Predatory forms, such as Pachycormus macropterus and Germanostomus pectopteri, targeted soft-bodied prey including coleoid cephalopods (e.g., Clarkeiteuthis) and small actinopterygians (e.g., Pholidophorus), with gut contents revealing teuthophagy and occasional piscivory or even cannibalism on juveniles. Suspension-feeding taxa like Leedsichthys and Bonnerichthys filtered mesoplanktonic organisms such as copepods and ammonitellae (0.5–2 mm in size), using specialized gill rakers to control plankton populations and fill a niche absent among modern large-bodied planktivores. Pectoral fin diversity—ranging from falcataform (high aspect ratio ~14.4 for agile pursuit) to gladiform (aspect ratio ~4.35 for stable slow cruising)—reflected these behavioral adaptations, enabling maneuverable hunting in predatory species and sustained gliding in filter-feeders. Taphonomic evidence from lagerstätten like the , characterized by rapid burial in oxygen-depleted "soupe" substrates, indicates that Pachycormiformes often died in open-water assemblages, supporting inferences of schooling behavior in predatory forms and possible diel vertical migrations in suspension-feeders to access layers. Interactions with contemporaneous included predation on ammonoids, as evidenced by fatal events in species, and coexistence with larger reptiles, though direct competition details remain limited. The group's extinction at the Cretaceous-Paleogene boundary coincided with a crash triggered by the Chicxulub impact, severely impacting suspension-feeders dependent on stable and creating ecological opportunities for post-extinction radiations of fishes.

References

  1. https://www.mdpi.com/1424-2818/14/12/1026
  2. https://deepblue.lib.umich.edu/bitstream/handle/2027.42/167090/spp21276_am.pdf?sequence=1
  3. https://link.springer.com/article/10.1007/s12542-018-0431-7
  4. https://onlinelibrary.wiley.com/doi/full/10.1002/spp2.1467
  5. https://deepblue.lib.umich.edu/bitstream/handle/2027.42/167090/spp21276.pdf?sequence=2
  6. https://pmc.ncbi.nlm.nih.gov/articles/PMC6842561/
  7. https://www.tandfonline.com/doi/full/10.1080/02724634.2025.2493164
  8. https://onlinelibrary.wiley.com/doi/10.1002/spp2.1276
  9. https://www.researchgate.net/publication/242329266_Growth_age_and_size_of_the_Jurassic_pachycormid_Leedsichthys_problematicus_Osteichthyes_Actinopterygii
  10. https://ui.adsabs.harvard.edu/abs/2024JVPal..4493164M/abstract
  11. https://www.researchgate.net/publication/327779641_The_stem_group_teleost_Pachycormus_Pachycormiformes_Pachycormidae_from_the_Upper_Lias_Lower_Jurassic_of_Strawberry_Bank_UK
  12. https://www.tandfonline.com/doi/abs/10.1080/02724634.2016.1206022
  13. https://sjpp.springeropen.com/articles/10.1186/s13358-023-00295-1
  14. https://link.springer.com/article/10.1007/s12542-025-00749-6
  15. https://hohpublica.uni-hohenheim.de/items/15174c0d-cfdc-4168-9363-bf4a30b24e71/full
  16. https://www.researchgate.net/publication/41486421_100-Million-Year_Dynasty_of_Giant_Planktivorous_Bony_Fishes_in_the_Mesozoic_Seas
  17. https://pmc.ncbi.nlm.nih.gov/articles/PMC9354740/
  18. https://palaeo-electronica.org/content/2025/5566-teleost-fishes-across-the-cretaceous-paleogene-boundary
  19. https://pmc.ncbi.nlm.nih.gov/articles/PMC5765809/
  20. https://www.sciencedirect.com/science/article/pii/S2095383625000616
  21. https://www.sciencedirect.com/science/article/pii/S0195667124001927
  22. https://www.tandfonline.com/doi/full/10.1080/14772019.2022.2049382
  23. https://www.pnas.org/doi/10.1073/pnas.1607237113
  24. https://www.tandfonline.com/doi/abs/10.1080/02724634.2018.1524384
  25. https://www.tandfonline.com/doi/abs/10.1080/02724634.2012.713059
  26. http://www.pfeil-verlag.de/wp-content/uploads/2015/05/4_59d05.pdf
  27. https://link.springer.com/article/10.1007/s12542-024-00700-1
  28. https://www.researchgate.net/publication/292209106_Highly_specialized_suspension-feeding_bony_fish_Rhinconichthys_Actinopterygii_Pachycormiformes_from_the_mid-Cretaceous_of_the_United_States_England_and_Japan
  29. https://royalsocietypublishing.org/doi/abs/10.1098/rspb.2011.1381
  30. https://doi.org/10.3390/d14121026
  31. https://www.researchgate.net/publication/259528515_An_overview_of_the_pachycormiform_Leedsichthys
  32. https://www.researchgate.net/publication/377473435_Cannibalism_in_the_Early_Jurassic_bony_fish_Pachycormus_macropterus_Teleosteomorpha_Pachycormiformes_and_its_paleoecological_significance
  33. https://doi.org/10.7717/peerj.7675
Add your contribution
Related Hubs
Contribute something
User Avatar
No comments yet.