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Percomorpha

Percomorpha is a hyperdiverse of spiny-rayed fishes (Acanthopterygii) within the ray-finned fishes (), defined as the minimum crown containing the (Perca fluviatilis) and at least 13 other exemplar species such as the (Scomber scombrus) and foureye butterflyfish (Chaetodon capistratus), but excluding outgroups like the ladyfish (Elops saurus). Comprising over 18,900 described species—approximately half of all living teleosts—this group represents one of the most species-rich vertebrate and dominates modern marine ecosystems while also occupying diverse freshwater and brackish habitats worldwide. The of Percomorpha is supported by several morphological synapomorphies, including 17 principal caudal-fin rays arranged in a distinctive 1:8:7:1 , ventral displacement of all epineurals with their tips embedded in the horizontal septum, loss of free pelvic radials, and absence of the orbitosphenoid bone. Taxonomically, it encompasses 16 lineages under a rank-free phylogenetic , 13 of which correspond to traditional orders such as (perches and allies), Gobiiformes (gobies), and (pufferfishes), reflecting extensive evolutionary radiations that began prominently during the Eocene epoch (56–33.9 million years ago). This clade's remarkable diversity spans a wide array of body forms, from the flattened bodies of flatfishes (Pleuronectiformes) to the streamlined shapes of tunas (Scombriformes), and includes ecologically pivotal that serve as key predators, prey, and models for biological , as well as many of commercial and recreational importance like groupers, snappers, and angelfishes. Ongoing phylogenomic studies continue to refine internal relationships, revealing patterns of and ancient divergences obscured by rapid evolution.

Description

General characteristics

Percomorpha is an unranked within , consisting of advanced spiny-rayed ray-finned fishes () that form a highly diverse group of teleosts. This represents the crown group of percomorphs, encompassing a wide array of forms adapted to various aquatic environments. As of March 2025, Percomorpha includes 18,904 known species distributed across 299 families and at least 22 orders, making it one of the most speciose vertebrate clades. These figures are drawn from ongoing updates in systematic databases, reflecting the rapid accumulation of taxonomic discoveries in this group. Percomorpha displays broad ecological diversity, with species occupying roles as dominant marine predators, such as tunas (Scombridae), reef inhabitants including seahorses (Syngnathidae) and gobies (Gobiidae), and freshwater dwellers like perches (Percidae). This clade accounts for approximately half of all teleost diversity, underscoring its pivotal influence on aquatic ecosystems worldwide.

Anatomical features

Percomorpha exhibit several defining morphological traits as advanced acanthomorphs, including the presence of transforming ctenoid scales, where the ctenii develop as separate ossifications in rows, distinguishing them from scales in more basal teleosts. These scales provide enhanced flexibility and protection, covering the body and often extending onto the head and fins. Additionally, most species possess a well-developed , typically physoclistous with a closed duct, aiding in control across diverse environments. A hallmark of Percomorpha is the "spiny-rayed" condition, characterized by spinous dorsal s supported by stiff, unsegmented spines that articulate via a unique chain-link mechanism, enabling rapid fin erection and retraction for and maneuvering. This synapomorphy extends to the anal and pelvic s, with pelvic s typically featuring one strong spine and five or fewer soft rays, reflecting reductions in radial elements. The caudal skeleton further unifies the , with an absence of the second ural centrum, five or fewer hypurals, and seventeen principal caudal- rays arranged in a 1,8,7,1 pattern. The and suspensorium structures in Percomorpha are highly advanced, featuring a mobile and modified hyoid apparatus that facilitate upper jaw protrusion, allowing precise prey capture in many lineages such as labrids and scarids among reef dwellers. This protrusible mechanism, supported by robust adductor mandibulae muscles, enables diverse feeding modes from suction feeding to biting. Variations in body forms are pronounced within the , ranging from elongated, shapes in barracudas (Sphyraenidae) suited for fast swimming to laterally compressed bodies in angelfishes () for agile navigation in coral environments, yet all share acanthomorph synapomorphies like the ventral displacement of epineurals originating from parapophyses or ribs. Sensory adaptations in Percomorpha include a well-developed system, consisting of neuromasts along the body and head that detect water movements and pressure changes, enhancing spatial awareness and predator avoidance. This system is innervated by and varies in canal morphology across families, with some species exhibiting accessory lines for finer resolution in complex habitats.

Systematics

Taxonomy

In traditional , Percomorphi was recognized as a subseries within the series Acanthopterygii, grouping a diverse array of spiny-rayed fishes including the orders and , among others. This classification was proposed in a seminal phyletic study that reorganized teleostean fishes based on morphological , emphasizing shared derived characters such as the of the caudal and fin supports. The term Percomorpha was first introduced by Rosen in 1973 to denote the monophyletic group encompassing Perciformes in the broad sense (sensu lato), providing nomenclatural stability for this assemblage while highlighting its internal diversity and unresolved relationships at the time. This naming convention has endured, avoiding the need for frequent revisions despite subsequent taxonomic upheavals. In modern taxonomy, Percomorpha is treated as an unranked clade within Acanthomorphata, reflecting its status as a large, diverse radiation rather than a Linnaean rank; this framework rejects the traditional Perciformes as paraphyletic and instead distributes its contents across multiple lineages. Key challenges include the historical "wastebasket" nature of Perciformes, which accumulated disparate taxa without strong synapomorphies, leading to its disassembly into over 14 new orders such as Gobiiformes, Kurtiformes, and Spariformes in recent revisions. Updates in Eschmeyer's Catalog of Fishes as of 2025 continue to recognize Percomorpha as this unranked taxon, incorporating ongoing refinements to align with phylogenetic evidence.

Phylogenetic relationships

Percomorpha represents one of the most diverse clades within Acanthomorpha, comprising approximately 18,904 species across 299 families and lineages. Phylogenomic studies have positioned Percomorpha with sequential sister taxa Trachichthyiformes and Beryciformes, resolving longstanding uncertainties in its external relationships to other acanthomorph lineages. This placement is supported by analyses using anchored hybrid enrichment datasets with over 130 loci and more than 99,000 base pairs, which filter out fast-evolving sites to mitigate biases like GC content variation. Earlier morphology-based phylogenies often left these relationships polytomous, but the shift to multi-locus phylogenomics has clarified the "bush at the top" of the actinopterygian tree by resolving deep polytomies through increased genomic sampling. Internally, Percomorpha exhibits a complex branching pattern indicative of rapid early diversification, with key clades such as (including jacks and trevallies), (encompassing gobies and blennies), and Pelagiaria (featuring tunas and billfishes) emerging as major lineages. Multi-locus analyses reveal early divergences including and , followed by groupings like Gobiiformes and larger assemblages containing , , and , alongside Eupercaria (which includes and related orders). The percomorph bush, characterized by short internal branches and high species diversity, has been progressively resolved using ultraconserved elements and Bayesian time-calibrated phylogenies, highlighting mosaic radiations within open-ocean and reef habitats. Recent classifications incorporating genomic data, such as the 2024 unranked phylogenetic framework for ray-finned fishes, recognize 16 major clades within Percomorpha, 13 of which align with traditional orders, underscoring its dominance within . Updates through 2025, including those from ongoing taxonomic revisions, maintain Percomorpha as the largest acanthomorph subgroup, with ongoing phylogenomic efforts continuing to refine these relationships using expanded datasets.

Evolution

Origins and fossil record

The origins of Percomorpha are estimated to date back to the early , approximately 110 million years ago (109–120 Ma), based on analyses calibrated with data. These estimates indicate that major percomorph subclades began diverging around 93 million years ago (95% highest posterior density interval: 84–102 Ma), aligning with the emergence of key lineages within the group during this period. Earliest evidence supports this timeline, with isolated percomorph remains reported from Upper Cretaceous freshwater deposits in , representing the first such records from eastern , and from Late Cretaceous– freshwater sediments in , suggesting an early radiation of perciform-like taxa. The fossil record of Percomorpha prior to the is notably sparse, with percomorphs remaining rare components of marine assemblages relative to other groups. Postdating the Cretaceous– (K/Pg) boundary, there is a marked increase in percomorph diversity, often described as an explosive morphological diversification beginning in the and accelerating through the Eocene. Notable early examples include percoid fishes from Eocene lagerstätten such as Monte Bolca in , where well-preserved skeletons reveal advanced percomorph features like spinous dorsal fins in taxa such as Hendrixella grandei. This post-K/Pg surge reflects the rapid filling of ecological niches vacated by extinct lineages, with percomorphs comprising around 60% of identified acanthomorph fossils in and deposits from Europe and . The K/Pg mass extinction event profoundly influenced percomorph evolution, resulting in moderate taxonomic losses among teleosts but enabling survivor lineages to undergo rapid diversification in the ensuing . Percomorphs, already established in the , benefited from reduced competition, leading to their dominance in early marine ecosystems. Paleontological gaps in the pre-Cenozoic percomorph record are attributed to taphonomic biases, particularly the poor preservation of articulated skeletons in shallow marine deposits where early percomorphs likely thrived. This "Patterson's Gap"—a span of limited articulated acanthomorph fossils around the K/Pg transition—further obscures the precise tempo of their initial radiation, though and disarticulated remains occasionally bridge these intervals.

Diversification patterns

The diversification of Percomorpha during the epoch (approximately 66–23 million years ago) represents one of the most explosive radiations in history, with the clade's major crown groups emerging near the (K–Pg) boundary and subsequent divergences occurring rapidly within the first 10 million years of the era. This burst in lineage formation, affecting key subclades such as Syngnatharia, Pelagiaria, Eupercaria, , Carangaria, and Gobiaria, resulted in the establishment of over 18,900 extant species across approximately 300 families, filling ecological niches vacated by the K–Pg mass extinction. The radiation coincided with periods of , elevated sea levels, and the expansion of habitats, which provided novel opportunities for habitat specialization in shallow marine environments. Key adaptive radiations within Percomorpha involved ecological shifts enabled by morphological innovations, such as the of specialized that facilitated diverse feeding strategies. For instance, transitions to freshwater habitats are exemplified by cichlids (Cichlidae), where modifications supported rapid trophic diversification in lacustrine systems. In deep-sea environments, lineages like dragonfishes () adapted through bioluminescent lures and expansive jaws for predatory lifestyles in the . Symbiotic associations, such as those in clingfishes (), involved adhesive disc innovations for attachment to hosts or substrates, promoting diversification in intertidal and cryptic niches. These adaptations underscore a mosaic pattern of radiation, with ecological opportunity driving phenotypic disparity across habitats. Biogeographic processes significantly influenced Percomorph diversity, particularly through Gondwanan vicariance following continental fragmentation around 135–84 million years ago, which isolated lineages and fostered endemic radiations in regions. Connections via the Tethys Sea, a tropical seaway linking and Indian Oceans until its closure 12–18 million years ago, enabled widespread dispersal and shaped high tropical , as evidenced by Eocene assemblages at Monte Bolca containing modern families. These historical pathways contributed to the clade's global distribution and concentration of diversity in Indo-Pacific hotspots. Phylogenomic timetrees reveal heterogeneous rates across Percomorpha, generally higher in lineages compared to freshwater ones due to broader connectivity and ecological opportunities in oceanic realms. Notable bursts occurred in (encompassing blennies and cardinalfishes) and Gobiiformes (including gobies), where elevated net diversification rates produced thousands of , contrasting with more constrained freshwater dynamics in groups like cichlids. Overall, these patterns reflect episodic shifts rather than constant rates, aligning with environmental perturbations during the .

Diversity

Major clades

Percomorpha encompasses a diverse array of ray-finned fishes, subdivided into major clades according to recent phylogenetic classifications. These clades reflect the monophyletic groupings supported by molecular and morphological data, with aligning closely with traditional higher taxa such as orders and suborders. Among these, several core clades stand out for their distinct morphological and systematic features. Carangaria represents one of the primary subclades, across families like (jacks and trevallies), which are characterized by streamlined bodies adapted for agile swimming. Gobiaria, another key group, includes primarily (gobies) and related families, noted for their small size and often demersal lifestyles, though diversification varies widely within the . Other prominent clades include Anabantaria, with labyrinth fishes such as gouramis and bettas, distinguished by their accessory air-breathing organs. Atherinaria encompasses silversides and allies, featuring silvery scales and often schooling behaviors. Pelagiaria includes pelagic forms like tunas in , with adaptations for open-water life. Recent taxonomic revisions from 2025 analyses have refined the basal positions within Percomorpha, confirming as the earliest diverging major clade, with ongoing uncertainties in deep branches of groups like Eupercaria. stands as the largest subclade, harboring approximately 5,500 species across diverse families including cichlids and blennies, underscoring the uneven diversification patterns in Percomorpha. This structure highlights the clade's evolutionary complexity, with phylogenetic support from genomic datasets confirming these groupings.

Distribution and habitats

Percomorpha display a cosmopolitan geographic distribution, inhabiting marine waters across all major ocean basins from the Arctic to the Antarctic regions. This broad range encompasses polar, temperate, and tropical environments, reflecting the clade's adaptability to diverse thermal regimes and salinity levels. The highest species diversity is concentrated in the Indo-Pacific tropics, where approximately 17,000 percomorph species contribute to over 90% of reef-associated fish richness in these biodiversity hotspots. Freshwater invasions by percomorph lineages have independently occurred multiple times, notably in Africa (e.g., cichlids), South America (e.g., rivulines), and Asia (e.g., snakeheads), enabling colonization of riverine and lacustrine systems derived from marine ancestors. Habitat preferences within Percomorpha span , freshwater, and brackish environments, showcasing remarkable ecological versatility. In settings, species occupy coral reefs, where families like Pomacentridae (damselfishes) dominate benthic communities through territorial behaviors and algal grazing, and pelagic zones, exemplified by Istiophoridae (billfishes) that undertake long migrations across open oceans. Freshwater habitats include rivers and lakes, often supporting endemic radiations, while brackish estuaries serve as transitional zones for taxa such as certain gobies. This habitat diversity underscores the clade's success in exploiting varied niches, from shallow coastal areas to deep-sea realms. Ecologically, percomorphs fulfill critical roles that structure aquatic communities. Keystone predators, such as groupers (Serranidae), regulate prey populations on reefs, preventing overgrazing by herbivores and maintaining through top-down control. Herbivores like parrotfishes (Scaridae) promote reef health by grazing macroalgae, facilitating coral recruitment and producing sediment via , which supports . engineers, including burrowing gobies (), aerate sediments through excavation, enhancing and oxygenation in soft-bottom habitats, thereby influencing microbial and assemblages. Major threats to percomorph populations include of commercially valuable species, such as tunas (), which has led to stock declines exceeding 90% in some cases due to intense industrial harvesting. Habitat loss, particularly degradation of coral from bleaching and , has resulted in a 60% drop in abundance globally since 1950, severely impacting reef-dependent percomorphs that comprise about one-third of marine diversity. Conservation efforts focus on sustainable and reef restoration to mitigate these pressures on this ecologically vital .