Fact-checked by Grok 2 weeks ago

Acanthomorpha

Acanthomorpha is a major monophyletic of spiny-rayed fishes within the , characterized by the presence of strong, spinous rays in their , anal, and pelvic fins, encompassing over 18,000 extant that represent nearly one-third of all living vertebrates. This group exhibits extraordinary morphological and ecological diversity, including forms ranging from the elongated seahorses and pipefishes to the asymmetrical flatfishes and the fast-swimming tunas, and occupies a wide array of aquatic habitats from tropical reefs to deep-sea environments and polar waters. The originated in the , approximately 133–152 million years ago, with its diversification predating the Cretaceous-Paleogene and featuring a subsequent slowdown in rates around 50 million years ago. Phylogenetically, Acanthomorpha is nested within the Neoteleostei, with its robustly supported by both molecular and morphological data, including nine key synapomorphies such as specialized fin-ray structures and skeletal features. The internal is complex and still under refinement, but it is broadly divided into three primary subclades: Lampridomorpha (including and ribbonfishes), a polymixiiform-percopsiform-gadiform-zeiform assemblage, and the species-rich , which alone accounts for over 17,000 species across 14 major lineages such as the Gobiiformes, , and . Fossil evidence from the onward has significantly enhanced understanding of its early , revealing a rapid initial radiation that contributed to the dominance of acanthomorphs in modern marine ecosystems. Acanthomorphs play a pivotal ecological role, serving as key predators, prey, and engineers in webs, with many lineages showing adaptations for specialized feeding, , and that have driven their adaptive success. Their superradiation underscores broader patterns in evolution, highlighting how genomic, morphological, and environmental factors interplay to produce unparalleled within vertebrates.

Definition and characteristics

Etymology and definition

The name Acanthomorpha derives from the Greek words ákanthos (ἄκανθος), meaning "" or "," and morphḗ (μορφή), meaning "form" or "shape," in reference to the characteristic spiny-rayed fins that define its members. The clade was first formally named and recognized as monophyletic by Donald E. Rosen in 1973, who identified it as a grouping of higher euteleostean fishes sharing derived anatomical traits, including the presence of rigid, spine-like lepidotrichia in their fins. Acanthomorpha represents one of the most species-rich clades within the Neoteleostei, a subdivision of ray-finned fishes (), and is distinguished by its members' possession of spinous fin rays that provide and defensive capabilities. This group encompasses over 18,000 extant across more than 300 families, accounting for over 60% of all diversity and nearly one-third of living species worldwide. The scope of Acanthomorpha broadly includes percomorphs—such as the diverse assemblage of "perch-like" fishes—and related lineages like paracanthopterygians and zeomorphs, forming a paraphyletic grade in some early classifications but now firmly established as a clade. Its composition features well-known groups including perches (Perciformes), tunas and mackerels (Scombriformes), flatfishes (Pleuronectiformes), seahorses and pipefishes (Syngnathiformes), and pufferfishes (Tetraodontiformes), highlighting its ecological dominance in marine and freshwater habitats.

Key morphological features

Acanthomorpha are distinguished by the presence of true fin spines, which are azygous, unsegmented lepidotrichia that are bilaterally paired and stiffened by their , occurring in the , anal, and pelvic fins. These , rigid spines contrast with the segmented soft rays typical of basal teleosts, providing enhanced defense against predators and improved maneuverability during locomotion. The spines' adaptive value lies in their role as a deterrent to gape-limited predators, allowing acanthomorphs to inhabit diverse niches including coral reefs and open oceans. The feeding apparatus features a highly protrusible upper , enabled by a retractable and connected via a single median chondrified that is strongly bound to the premaxillary ascending processes. This facilitates jaw protraction, generating powerful for capturing elusive prey and supporting a range of feeding strategies from planktivory to piscivory. Associated with this is the presence of uncinate processes on the epibranchials, which anchor muscles involved in function, contributing to efficient prey processing in the derived pharyngognathous condition. Skeletal traits include a reduced number of branchiostegal rays, typically 5–7 per side, compared to the higher counts in more basal teleosts, aiding in streamlined cover mechanics. The pectoral girdle is specialized, with the dorsal limb of the posttemporal bone firmly bound to the epioccipital via tight , enhancing structural integrity between the and shoulder region. Additionally, the first centrum bears distinct facets for with the exoccipital condyles, and median caudal cartilages between hypurals are absent, refining caudal fin support. Sensory systems feature advanced otoliths, particularly the , which are enlarged and aragonitic structures in the that improve hearing sensitivity and in varied environments. Acanthomorph body plans exhibit remarkable diversity, from fusiform shapes in fast-swimming tunas () to globose forms in puffers (), yet all share the unifying trait of spiny-rayed fins that underpin this morphological radiation. These features collectively enable adaptive success across marine and freshwater habitats, with jaw protraction diversifying trophic roles and spines bolstering antipredator defenses.

Classification and taxonomy

Historical development

In the early 19th century, the classification of spiny-rayed fishes was formalized by , who introduced the order Acanthopteri in his seminal work Le Règne Animal to encompass groups such as perches () and mackerels (Scombriformes), distinguished primarily by the presence of rigid, spiny fin rays in the dorsal, anal, and pelvic . This grouping emphasized external and represented one of the first systematic attempts to organize diversity based on shared anatomical features, though it included a broad array of taxa without rigorous phylogenetic testing. The 20th century brought refinements to classifications, with Greenwood et al. (1966) proposing a provisional higher-level framework that positioned the Acanthopterygii within the cohort Euteleostei (later termed Neoteleostei), highlighting shared advanced traits like the rostral and certain cranial modifications among higher s. Building on this, Rosen (1973) advanced the concept by erecting Acanthomorpha as a monophyletic , uniting Acanthopterygii and Paracanthopterygii with ctenothrissiform fossils under synapomorphies such as true lepidotrichial spines and modifications to the pectoral . Influential studies like Patterson and Rosen (1977) further supported these ideas through detailed anatomical reviews, including analyses of otophysic connections involving the gas bladder and exoccipital-prootic associations, which reinforced the unity of acanthomorphs relative to basal s. Pre-molecular taxonomy faced significant challenges regarding the of Acanthomorpha, with ongoing debates about whether it constituted a natural or a of advanced teleosts; for instance, traditional was often treated as a "catch-all" incorporating disparate forms without clear shared derived traits. Stiassny (1986) addressed these issues in her comprehensive survey of percomorph relationships, identifying additional synapomorphies such as the spina occipitalis and ceratohyal to bolster acanthomorph while critiquing paraphyletic assemblages. Similarly, and Patterson (1993) explored percomorph interrelationships, proposing a revised framework that excluded certain beryciforms and zeiforms from core percomorphs but emphasized morphological evidence for internal s, though they acknowledged persistent uncertainties in basal branching. These pre-molecular efforts were inherently limited by their reliance on comparative morphology, which often resulted in paraphyletic groups like the traditional , as subtle homoplasies in fin spines and skeletal features obscured true phylogenetic signals without molecular corroboration.

Modern phylogenetic framework

The modern phylogenetic framework for Acanthomorpha has been shaped by the molecular revolution, which integrated and mitochondrial sequences to resolve longstanding uncertainties in . Early molecular studies using and protein-coding genes began to support the monophyly of Acanthomorpha, but denser taxon sampling through phylogenomics—employing hundreds of loci from transcriptomes and genomes—provided robust confirmation of this as a well-supported branch within Neoteleostei. For instance, analyses of over 1,000 orthologous exons across 305 ray-finned species affirmed Acanthomorpha's with high posterior probabilities, highlighting as a diverse subset within Acanthomorpha that encompasses more than 17,000 species. The current taxonomic hierarchy places as a major subclade of Acanthomorpha, organized into several series such as Berycida (including zeomorphs and beryciforms), Lampridiformes (opah-like fishes), Gasterosteiformes (sticklebacks and allies), (pipefishes and seahorses), and Acanthopterygii (the spiny-rayed perches and relatives, incorporating the traditional sensu lato). This structure reflects integrated evidence from molecular data, where Acanthopterygii emerges as the largest component within , comprising advanced percomorphs with specialized fin rays and diverse body plans. Within this framework, the traditional order has been extensively revised, fragmented into approximately 20 distinct orders based on phylogenomic congruence, including Anabantiformes ( fishes), Gobiiformes (gobies), and (a assemblage of former perciform groups); overall, Acanthomorpha now accommodates around 50 orders across approximately 18,000–19,000 in more than 300 families. Key advancements include Hughes et al.'s (2018) demonstration of Acanthomorpha's "superradiation," a rapid diversification event yielding exceptional morphological and ecological disparity shortly after its origin. A 2025 review further synthesizes these findings, emphasizing how acanthopterygian clades exhibit varied ecological adaptations and biogeographic patterns, such as reef-associated radiations in tropical and pelagic expansions in Lampridiformes. Taxonomic stability has increased with the recognition of approximately 300 families across Acanthomorpha, though debates persist regarding the precise boundaries of and the placement of certain "bush-like" lineages with weak support.

Phylogeny

Position within Teleostei

Acanthomorpha is a major clade within the infraclass Teleostei, specifically nested within the subdivision Neoteleostei in the broader actinopterygian phylogeny. It forms part of the superorder Acanthopterygii sensu lato, encompassing a diverse array of spiny-rayed fishes that represent over 16,000 extant species, comprising approximately one-third of all teleost diversity. The of Acanthomorpha is robustly supported by molecular phylogenetic analyses, including multi-locus datasets from nearly 2,000 species, with bootstrap support exceeding 95% in key nodes. This placement positions Acanthomorpha as a derived lineage within Teleostei, which itself is the to (gars and bowfins) among actinopterygians. Within Neoteleostei, Acanthomorpha is closely allied with orders such as Aulopiformes (lizardfishes and allies) and Myctophiformes (lanternfishes), which serve as immediate outgroups in phylogenetic reconstructions. Specifically, molecular evidence indicates that Acanthomorpha is sister to Myctophata (Myctophiformes), together forming the subsection Acanthomorphata, while Aulopiformes branches earlier within Neoteleostei. These relationships are corroborated by shared morphological traits, including a leptolepis-type caudal skeleton characterized by a diural configuration with fused hypurals and reduced ural centra, facilitating enhanced tail propulsion in advanced teleosts. Key synapomorphies distinguishing Acanthomorpha include the presence of rigid, unpaired, and unsegmented spines in the and anal fins, which provide structural support and defensive capabilities not as pronounced in outgroups. These spiny rays, along with refined jaw mechanics involving a protractile and associated ligaments, are shared to some extent with certain paracanthopterygian-like groups (now often nested within or near Acanthomorpha) but are more specialized here for diverse feeding strategies. Evolutionarily, Acanthomorpha exemplifies a major radiation within actinopterygians, originating around 133–152 million years ago and diversifying rapidly into and other subclades without a detectable shift at the Cretaceous-Paleogene boundary. This burst contributed to the dominance of spiny-rayed fishes in modern marine and freshwater ecosystems.

Internal clades and relationships

Acanthomorpha encompasses three primary subclades: Lampripterygii, Paracanthopterygii, and Acanthopterygii, each characterized by distinct morphological and ecological traits. Lampripterygii includes pelagic forms such as opahs (Lampridae) and ribbonfishes (Trachipteridae), representing an early-diverging lineage with reduced spiny rays and unique body plans adapted to open ocean environments. Paracanthopterygii comprises deep-sea and benthic groups like codfishes (), unified by features such as a single and specialized sensory adaptations for low-light conditions. Acanthopterygii, the largest subclade, incorporates basal groups like beryciforms and the expansive , which dominates with over 18,000 species and exhibits high morphological diversity in fin structures and body shapes. Percomorpha forms the core of Acanthopterygii and is subdivided into several series, including (encompassing cichlids, blennies, and damselfishes), (jacks, remoras, and flatfishes), and other lineages such as Anabantaria and Syngnatharia. Within , key relationships highlight a superradiation during the , coinciding with the Cretaceous-Paleogene boundary, where multiple lineages diversified rapidly following ecological opportunities post-extinction. Gobioids ( and allies) emerge as a derived percomorph clade within Gobiaria, closely related to dragonets and sleeper gobies, reflecting adaptations to and estuarine habitats. Syngnathiforms (pipefishes and seahorses), previously of uncertain affinity, are now firmly placed within Syngnatharia as part of , with recent phylogenomic analyses confirming their nesting alongside flying gurnards and goatfishes. Phylogenetic analyses, such as the comprehensive in Betancur-R et al. (2017), position Pelagiaria (including tuna-like scombrids in Scombriformes) as a distinct series within , though the exact sister relationships of billfishes () remain debated, often aligning them nearer to Carangaria rather than directly with tunas. Recent 2025 studies further refine these affinities, resolving syngnathiform positions with high support using expanded molecular datasets and emphasizing their Tethyan origins within percomorph diversification. However, persistent challenges include unresolved polytomies across percomorph orders, exemplified by the "bush-like" in Eupercaria, where rapid obscures branching order among families like scombrids and their allies. Morphological , particularly in reef-associated forms with similar body streamlining and coloration, complicates inference from traditional traits alone. These relationships have profound taxonomic implications, embedding traditionally separate orders like (pufferfishes) deeply within , thereby reshaping higher-level classifications to reflect monophyletic groupings based on genomic .

Evolutionary history

Origins and early diversification

The origins of Acanthomorpha, the largest of spiny-rayed fishes, are inferred from both and molecular , pointing to an emergence in the . Definitive skeletal fossils appear in the Albian– stages of the (approximately 110–94 Ma), with early examples from deposits in and , marking the initial diversification of basal lineages in environments. Molecular clock analyses estimate the crown-group age at around 140 Ma (126–153 Ma), aligning with the mid-Cretaceous onset of major acanthomorph radiations. Early diversification accelerated during the mid-Cretaceous, coinciding with profound shifts in marine ecosystems, including the escalation of predator-prey interactions known as the and the proliferation of habitats. This period saw the radiation of initial acanthomorph subgroups, dominated by marine forms such as basal beryciforms, which exhibited key innovations like robust fin spines and ctenoid scales for enhanced defense and maneuverability. The whole-genome duplication event () early in evolution provided a genetic foundation for innovations, including expanded clusters that facilitated morphological flexibility and ecological opportunism in reefs and open oceans. These developments positioned acanthomorphs to exploit emerging niches, initially in marine settings, before broader habitat invasions. A pivotal event was the expansion following the Cretaceous-Paleogene (K-Pg) boundary mass extinction around 66 , where acanthomorphs demonstrated remarkable with minimal lineage losses, unlike many non-acanthomorph teleosts. This survival enabled a steady post-extinction accumulation of lineages, with morphological disparity increasing in the as clades colonized vacated ecospace and diversified into novel body forms. Recent analyses highlight this prolonged trajectory, with steady accumulation of disparate clades across global marine environments, underscoring acanthomorphs' adaptive success amid ecosystem recovery. Recent otolith records from the further indicate the presence of additional acanthomorph orders pre-K-Pg.

Fossil record

The fossil record of Acanthomorpha is sparse, particularly in the , with the earliest evidence consisting primarily of otoliths rather than complete skeletons. The oldest reported acanthomorph otoliths date to the early stage of the (approximately 124–122 Ma), recovered from deposits in the Maestrazgo region of Castellón Province, , and assigned to the informal Acanthomorphorum. These otoliths represent tentative early members of the group, though their exact phylogenetic placement remains uncertain due to the limitations of isolated ear stones in identifying higher-level relationships. Skeletal remains appear later, with the first unequivocal examples emerging in the stages (approximately 113–94 Ma), including taxa from the of , such as elements from Muhi Quarry in , and articulated specimens from Lebanese lagerstätten like Hajula and Hakel. Other early percomorph relatives, such as Zoqueichthys carolinae, characterize these initial skeletal records, highlighting a predominantly origin. The record remains limited, reflecting taphonomic biases that favor preservation in exceptional lagerstätten but overlook broader diversity. (Cenomanian–Maastrichtian) marine forms include early acanthomorph experimentation in body form and fin structure. By the (approximately 72–66 Ma), evidence of freshwater invasions appears, as seen in isolated elements from Madagascan deposits in the Maevarano Formation, indicating percomorph fishes had begun colonizing continental interiors, potentially via coastal river systems. Stem-group berycoids from North American sites further illustrate the group's initial diversification among deeper-water lineages. Exceptional preservation in some specimens, such as a acanthomorph intestine from revealing dietary insights into early ecological roles, underscores the group's rapid adaptation to varied niches even in this fragmentary record. A major diversification surge occurred in the , following the end-Cretaceous extinction, with the Eocene Monte Bolca in (Ypresian, approximately 50 Ma) preserving over 75 acanthomorph families, including early percomorphs, and showcasing near-modern levels of morphological and ecological variety in marine settings. This Eocene radiation contrasts sharply with "Patterson's Gap," a notable paucity of records from the to (approximately 72–56 Ma), during which few acanthomorph lineages survived the K-Pg boundary, likely due to selective pressures on marine ecosystems. Recent discoveries, such as () ctenoid scales from Krasiejów, , suggest possible earlier origins for acanthopterygian traits, though their assignment to Acanthomorpha is tentative and based on scale morphology alone. Overall, around 200 fossil species have been described, but the record's incompleteness—exacerbated by poor preservation outside exceptional sites—continues to hinder full reconstruction of the group's evolutionary timeline.

Diversity and distribution

Major subgroups and species richness

Acanthomorpha encompasses approximately 30 orders, more than 300 families, and over 18,000 extant (as of 2024 estimates), representing over 60% of all diversity and about one-third of living vertebrates. This exhibits uneven , with the majority concentrated in the percomorph lineages, while basal groups like beryciforms and zeiforms are far less speciose. Key orders illustrate this disparity. Beryciformes includes 7 families and roughly 161 species, primarily deep-sea forms such as alfonsinos and squirrelfishes. comprises 7 families and about 20 species, featuring pelagic species like opahs and ribbonfishes. Gasterosteiformes (now often classified under in modern schemes) has 11 families and around 374 species, including sticklebacks and . In contrast, the traditional broad (sensu lato, now splintered into multiple lineages within by recent phylogenies) formerly encompassed over 160 families and more than 10,000 species, including diverse groups like perches, tunas, and mackerels; the restricted core (primarily Percoidei) retains about 70 families and around 3,000 species. contains 10 families and approximately 430 species, including pufferfishes and filefishes, many of which are reef-associated. At the family level, acanthomorph diversity is dominated by a few highly speciose groups within . The alone accounts for over 2,000 species, making it the largest vertebrate family and a key contributor to marine and freshwater gobioid richness exceeding 5,000 species across related families. The Labridae includes more than 600 species of , noted for their ecological roles in coral reefs. Similarly, the encompasses about 500 species of sea basses and groupers, many of which are important fisheries targets. Species richness is highest in , which harbors the bulk of acanthomorph diversity, including endemics in systems and freshwater habitats. Historical over-lumping in orders like has led to recent taxonomic splits, increasing the recognized order count from fewer than 20 to around 30 based on molecular phylogenies. Despite this vast diversity, many -associated acanthomorphs face threats from habitat loss and , underscoring the need for targeted .

Global distribution and habitats

Acanthomorph fishes exhibit a across virtually all aquatic environments, with over 85% of actinopterygian belonging to this and inhabiting diverse settings from shallow reefs and temperate rocky shores to the open ocean's surface waters, polar seas, and deep-sea realms. While predominantly —accounting for approximately 92% of modern reef fish diversity—they include significant freshwater and brackish-water representatives, such as cichlids that dominate many tropical inland habitats worldwide and gobies adapted to estuarine zones. Biogeographic hotspots occur in the , particularly the Coral Triangle, where hyper-diverse reefs support the majority of acanthomorph richness due to favorable conditions for reef-associated lineages. Polar regions feature specialized groups like notothenioids, which dominate the Southern Ocean's fish fauna, while deep-sea habitats host bioluminescent forms such as anglerfishes. Ecologically, acanthomorphs play pivotal roles across trophic levels, functioning as apex predators in pelagic ecosystems (e.g., tunas and marlins that undertake extensive vertical migrations to exploit prey layers), herbivores maintaining algal balance on (e.g., surgeonfishes turf algae to prevent overgrowth), and mutualistic symbionts like cleaner that remove parasites from other species, thereby enhancing reef community health. These interactions position them as foundational components of food webs, supporting in high-productivity systems like reefs and contributing substantially to global fisheries through commercially vital species such as tunas and groupers. Notable adaptations enable their broad habitat occupancy, including euryhaline capabilities in mudskippers that tolerate brackish intertidal zones and even venture onto land, endothermy in pelagic forms like tunas for sustained activity in cooler waters, and antifreeze proteins in notothenioids for survival in subzero conditions. However, contemporary threats include climate-driven shifts, such as ocean warming and that disrupt reef habitats critical for over 90% of coral-associated acanthomorphs, leading to range contractions and community restructuring. , exemplified by in the western Atlantic, further exacerbate pressures by preying on native juveniles and altering local dynamics.

References

  1. [1]
    Phylogeny and tempo of diversification in the superradiation of spiny ...
    Jul 15, 2013 · Spiny-rayed fishes, or acanthomorphs, comprise nearly one-third of all living vertebrates. Despite their dominant role in aquatic ecosystems ...
  2. [2]
    The Phylogenetic Intrarelationships of Spiny-Rayed Fishes ...
    Acanthomorpha (spiny-rayed fishes) is a clade of teleosts that includes more than 15, 000 extant species. Their deep phylogenetic intrarelationships, first ...
  3. [3]
    acanth- - Wiktionary, the free dictionary
    Etymology. From international scientific vocabulary, reflecting a New Latin combining form, from New Latin, from Ancient Greek ἄκανθος (ákanthos, “thorn plant” ...Missing: Acanthomorpha | Show results with:Acanthomorpha
  4. [4]
    [PDF] PERCOMORPH PHYLOGENY: A SURVEY OF ACANTHOMORPHS ...
    When Rosen (1973) named Percomorpha, it included beryciforms, perciforms, and the groups placed between and beyond those in Greenwood et al.'s (1966).
  5. [5]
    New insights on early evolution of spiny-rayed fishes (Teleostei
    The Acanthomorpha, or spiny-rayed fishes, represent the largest group of teleost fishes, with estimates of diversity reaching close to 19,000 species (Nelson, ...Missing: etymology | Show results with:etymology
  6. [6]
    Diversity of the Acanthomorpha - SICB
    The spiny-rayed fishes, Acanthomorpha, are the crown group of the Teleostei. With over 300 families and 16,000 species, they comprise more than 60% of extant ...Missing: etymology | Show results with:etymology
  7. [7]
    https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0212954
  8. [8]
    Phylogenetic relationships within the primitive acanthomorph fish ...
    Mar 1, 2019 · There is a reduction of branchiostegal rays to seven pairs; however, the first three pairs are uniquely modified to form the skeletal ...
  9. [9]
    (PDF) New insights on early evolution of spiny-rayed fishes (Teleostei
    Aug 6, 2025 · The Acanthomorpha is the largest group of teleost fishes with about one third of extant vertebrate species. In the course of its evolution ...
  10. [10]
    The Project Gutenberg eBook of Guide to the Study of Fishes, by ...
    As for the most part these are spiny-rayed fishes, Cuvier's name Acanthopterygii, or Acanthopteri, will serve us as well as any. The Physoclysti of Müller ...
  11. [11]
    Phyletic studies of teleostean fishes, with a provisional classification ...
    Phyletic studies of teleostean fishes, with a provisional classification of living forms. ... Date. 1966. item.page.datecreated. Authors. Greenwood, Peter Humphry ...Missing: teleost Acanthomorpha
  12. [12]
    Review of ichthyodectiform and other Mesozoic teleost fishes, and ...
    The ichthyodectiform fishes are a nominal order of Mesozoic teleosts that have been assigned to three of the four extant teleostean cohorts in one or another ...
  13. [13]
    The limits and relationships of the acanthomorph teleosts - 1986
    The phylogenetic integrity of the sistergroup of the entire Acanthomorpha, the Myctophiformes (sensu Rosen, 1973), is attested by the presence of four derived ...Missing: original | Show results with:original
  14. [14]
    Phylogenetic classification of bony fishes | BMC Ecology and Evolution
    Jul 6, 2017 · Morphological synapomorphies: Morphological characters supporting Otomorpha (but excluding Alepocephalidae) can be found in G Arratia [45] ...
  15. [15]
    Comprehensive phylogeny of ray-finned fishes (Actinopterygii ...
    May 14, 2018 · We compiled the largest comparative genomic database of fishes that provides genome-scale support for previous phylogenetic results.
  16. [16]
    Phylogeny, biology, and evolution of acanthopterygian fish clades
    Mar 13, 2025 · In this review, we highlight the patterns of morphology, ecology, biology, and biogeography within and among the major clades of Acanthopterygii ...
  17. [17]
    [PDF] The caudal skeleton of basal teleosts, its conventions, and some of ...
    The present study represents an evaluation of the current knowledge of the caudal endoskeleton of basal fossil.
  18. [18]
    https://doi.org/10.3389/fmars.2014.00053
  19. [19]
    https://doi.org/10.1038/s41559-022-01801-3
  20. [20]
    https://pdfs.semanticscholar.org/88da/4a08943929641a21c45e0d41e54603365e9c.pdf
  21. [21]
    [PDF] The Cretaceous–Paleogene transition in spiny ... - Semantic Scholar
    In contrast to the rich collections of articulated spiny-rayed fishes from early Late Cretaceous and Eocene Lagerstätten, similar skeletal remains are ...
  22. [22]
    a case study for molecular phylogeny of Acanthomorpha (Teleostei ...
    Our knowledge of high-level acanthomorph phylogeny is very poor considering their sizeable species diversity, especially within the major clade Percomorpha.
  23. [23]
    Sawbellies and squirrelfishes (Order Beryciformes) - iNaturalist
    The Beryciformes are a poorly-understood order of carnivorous ray-finned fishes consisting of 7 families, 30 genera, and 161 species.
  24. [24]
    https://www.marinespecies.org/aphia.php?p=taxdetails&id=154069
  25. [25]
    Gasterosteiform | Definition, Characteristics, & Facts - Britannica
    Length from about 2 to 200 cm (0.8 to 79 inches). 11 families, 374 species. Marine, brackish, and freshwater; widely distributed.
  26. [26]
    Phylogeny of Gobioidei and Placement within Acanthomorpha, with ...
    Feb 23, 2009 · These groups share characteristics of the skeleton, soft tissues, and reproductive ecology. A new six-family clade-based classification of ...Missing: definition | Show results with:definition
  27. [27]
    Order Summary for Tetraodontiformes - FishBase
    Families. : ( n = 10 ) Aracanidae Balistidae Diodontidae Molidae Monacanthidae Ostraciidae Tetraodontidae Triacanthidae Triacanthodidae Triodontidae ...
  28. [28]
    https://www.fishbase.se/Summary/FamilySummary.cfm?ID=405
  29. [29]
    Wrasse - Wikipedia
    The wrasses are a family, Labridae, of marine ray-finned fish, many of which are brightly colored. The family is large and diverse, with over 600 species in 81 ...Humphead wrasse · Mediterranean rainbow wrasse · Labriformes · Tautog
  30. [30]
    FAMILY Details for Serranidae - Sea basses: groupers and fairy ...
    Nov 29, 2012 · Order, : Perciformes/Serranoidei ; Class, : Teleostei ; No. in FishBase, : Genera : 12 | Species : 102 Eschmeyer's Catalog of Fishes ; Environment ...
  31. [31]
    https://media.fisheries.noaa.gov/dam-migration/general_status_assessment_indo-pacific_reef_corals_2019.pdf
  32. [32]
    [PDF] Oceans by Acanthomorph Fishes - Wainwright Lab
    Jun 5, 2017 · Fin spines, the trait that gives spiny-rayed fishes their name, are also a shared-derived trait for acanthomorph fishes, but, as with jaw ...
  33. [33]
    [PDF] Indo-Pacific Reef-building Corals: General Status Assessment - NOAA
    Feb 4, 2010 · Biodiversity of Indo-Pacific reef-building corals is highest in the “Coral Triangle” area of eastern Indonesia and the southern Philippines (> ...
  34. [34]
    Phylogenetics of notothenioid fishes (Teleostei: Acanthomorpha)
    Notothenioids represent an adaptive radiation of teleost fishes in the frigid and ice-laden waters of the Southern Ocean surrounding Antarctica.
  35. [35]
    The Rise of Jaw Protrusion in Spiny-Rayed Fishes Closes the Gap ...
    Oct 19, 2015 · The initial driver of changing protrusion abilities was an increase in the proportion of spiny-rayed (acanthomorph) fishes (from 38% in the ...<|separator|>
  36. [36]
    Meet the Surgeonfish - Ocean Conservancy
    Apr 19, 2024 · Surgeonfish are primarily herbivores and act as a cleanup crew for their coral reef homes. These fish feed on the green and brown algae that ...Missing: Acanthomorpha | Show results with:Acanthomorpha
  37. [37]
    Presence of cleaner wrasse increases the recruitment of ... - NIH
    The cleaner wrasse, Labroides dimidiatus, removes ectoparasites and reduces stress hormones for multiple reef fish species, and their presence on coral reefs ...Missing: Acanthomorpha | Show results with:Acanthomorpha
  38. [38]
    The Amphibious Mudskipper: A Unique Model Bridging the Gap of ...
    In addition to aquatic teleosts, the amphibious and euryhaline mudskipper, which invades land in its lifecycle, is used for the study of osmoregulation. (B) ...Missing: Acanthomorpha | Show results with:Acanthomorpha
  39. [39]
    [PDF] SPREP - Climate change and the future for coral reef fishes
    The most immediate impacts will be a loss of diversity and changes to fish community composition as a result of coral bleaching.
  40. [40]
    Impacts of Invasive Lionfish | NOAA Fisheries
    May 22, 2025 · This is an invasive species that threatens the well-being of coral reefs and other marine ecosystems, including the commercially and recreationally important ...Missing: Acanthomorpha | Show results with:Acanthomorpha