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Carangiformes
Carangiformes
Carangiformes
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Carangiformes
Temporal range: Late Paleocene–present
Bluefin trevally (Caranx melampygus)
Remora remora
Scientific classification Edit this classification
Kingdom: Animalia
Phylum: Chordata
Class: Actinopterygii
Clade: Percomorpha
Order: Carangiformes
Jordan, 1923[1]
Type species
Caranx praeustus
Anonymous [Bennett], 1830

Carangiformes is a large, diverse order of ray-finned fishes within the clade Percomorpha. It is part of a sister clade to the Ovalentaria, alongside its sister group, the Anabantaria (including Anabantiformes and Synbranchiformes). The Carangiformes have been long regarded as a monotypic order with only the family Carangidae within it by some authorities, and the other current families within the order have been previously classified as part of the wider order Perciformes. The 5th edition of Fishes of the World classify six families within Carangiformes,[2] with more recent authorities expanding the order to include up to 30 families, based on phylogenetic evidence.[3]

The earliest known carangiforms are two fossil species of Mene, Mene purydi from Peru and Mene phosphatica from Tunisia, both of which are known from the Late Paleocene.[4]

Taxonomy

[edit]

This order has often been either subsumed within Perciformes or used exclusively to refer to families classified within the suborder Carangoidei. However, more recent studies using genetic data have found such a placement to be paraphyletic, and have incorporated many more groups into it, including the highly unusual flatfishes.

This classification is from Eschmeyer's Catalog of Fishes Classification.[5]

The Coryphaenidae, Rachycentridae, and Echeneidae have been suggested to comprise a monophyletic grouping, which has been recovered as a sister clade to the Carangidae.[2] A basal member of this clade is thought to be from the early Eocene.

The following fossil families are also known:[6]

Traditional classification

[edit]

In past classifications such as Fishes of the World 5, Carangiformes were restricted to these families. This placement is now known to be paraphyletic:[2]

Fossil of Mene oblonga

See also

[edit]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Carangiformes

View on Grokipedia
from Grokipedia
Carangiformes is a diverse order of ray-finned fishes (Actinopterygii) within the large clade Percomorpha, encompassing approximately 1,100 species distributed across 29–34 families. This order unites a broad array of primarily marine species that were historically classified in separate groups, including jacks and pompanos (Carangidae), barracudas (Sphyraenidae), dolphinfishes (Coryphaenidae), cobias (Rachycentridae), remoras (Echeneidae), moonfishes (Menidae), roosterfishes (Nematistiidae), and billfishes (Istiophoridae and Xiphiidae), as well as the traditional flatfishes of the Pleuronectiformes (such as Pleuronectidae, Bothidae, and Paralichthyidae). The phylogenetic recognition of Carangiformes stems from molecular and morphological analyses that recovered these families as a monophyletic clade nested within , supported by genomic data from ultraconserved elements and 201 morphological characters. Members of the order are predominantly found in tropical and temperate marine environments across the Atlantic, Indian, and Pacific Oceans, with some species venturing into brackish or coastal habitats; they range from pelagic predators like (Xiphias gladius) to benthic flatfishes adapted for on seafloors. Notable adaptations include modifications to the —such as detached spinous and soft-rayed portions in carangids—and specialized feeding structures, like the elongated rostra of billfishes or the suction-cup dorsal fins of remoras for attaching to hosts. These features, along with patterns of morphological convergence with sister clades like , highlight the evolutionary diversity within Carangiformes. Many carangiform species hold ecological and economic importance, serving as key predators in marine food webs or supporting commercial fisheries; for instance, dolphinfishes are prized for sport and , while flatfishes contribute significantly to global and wild capture. The order's composition continues to be refined through ongoing genomic studies, reflecting the challenges in resolving percomorph relationships.

Taxonomy and classification

Historical development

The classification of carangiform fishes traces its origins to the early 19th century, when established the family in 1815 as a distinct group characterized by compressed bodies and specific fin structures, initially treating it within a narrow taxonomic framework that effectively rendered it monotypic in ordinal terms under the broader percoid-like fishes. By the late 19th and early 20th centuries, carangids were increasingly subsumed under the expansive order , with in 1893 classifying them as a subfamily within this order, emphasizing their perch-like traits alongside other percoidean families in his systematic arrangement of fish subfamilies. Similarly, Charles Tate Regan in 1913 reinforced this placement by integrating into the suborder Percoidei of , viewing them as a core family among diverse percoid groups defined by shared osteological and fin-ray features, without elevating them to a separate ordinal status. In the mid-20th century, Lev Semenovich Berg's 1940 classification introduced revisions by separating certain allied families, such as Coryphaenidae, from the core Carangidae while still embedding them within Perciformes, highlighting morphological distinctions like body elongation and scale patterns to refine percoid suborders. This approach was echoed in the influential 1966 revision by Peter H. Greenwood and colleagues, who maintained Carangidae and related families like Coryphaenidae within the suborder Percoidei of Perciformes, based on comparative anatomy that underscored their phylogenetic proximity but limited broader ordinal recognition. These morphological classifications persisted until the late , when molecular data began to challenge traditional boundaries and prompt the recognition of Carangiformes as a distinct order.

Modern phylogeny and suborders

The modern phylogenetic framework positions Carangiformes as a monophyletic order within the diverse clade, specifically as a to , based on comprehensive analyses of molecular data from hundreds of species across ray-finned fishes. This placement is supported by phylogenomic studies utilizing transcriptomic and genomic datasets, which resolve Carangaria (encompassing Carangiformes and related orders like Istiophoriformes) as a well-supported series within , with bootstrap values exceeding 99%. Carangiformes was formally recognized as a distinct order in the fifth edition of Fishes of the World, where it initially encompassed a narrower assemblage of about six families centered on carangid-like fishes, reflecting early molecular integrations into percomorph classifications. Subsequent taxonomic expansions, driven by broader genomic sampling, have incorporated additional lineages, resulting in 34 families documented in contemporary catalogs as of 2025, highlighting the order's expanded scope to include disparate groups like flatfishes and billfishes. The order is subdivided into six suborders based on resolved phylogenetic relationships: Centropomoidei (encompassing perch-like forms such as snooks and ), Pleuronectoidei (including flatfishes and soles), Toxotoidei ( allies), Nematistioidei (), Menoidei (moonfish and billfishes), and Carangoidei (jacks and remoras). These divisions stem from integrative evidence combining morphological traits with molecular markers, confirming the of Carangiformes through analyses of nuclear genes like rag1 and rhodopsin, alongside mitochondrial loci. Divergence time estimates, calibrated using fossil constraints and Bayesian methods, indicate that the crown group of Carangiformes originated approximately 60-70 million years ago during the , shortly after the Cretaceous-Paleogene boundary, aligning with the radiation of percomorph fishes into marine and coastal niches. This timeline underscores the order's evolutionary success, with key genomic studies providing robust support for these deep-time inferences without reliance on earlier morphology-only groupings.

Families overview

The order Carangiformes encompasses approximately 1,100 species across 34 families, with the suborder Pleuronectoidei accounting for the majority of this diversity due to its inclusion of numerous lineages. These families exhibit remarkable morphological variation, ranging from elongate predatory forms to highly asymmetric , reflecting adaptations to diverse marine, estuarine, and occasionally freshwater habitats. The into suborders highlights evolutionary branches within the order, as resolved by molecular and morphological phylogenies. In the suborder Centropomoidei, four families represent perch-like fishes often associated with coastal and inshore waters. The Latidae (giant perches) includes 13 species in 3 genera, characterized by robust bodies and strong spines suited for ambush predation in tropical Indo-Pacific and African fresh to brackish systems. The Centropomidae (snooks) comprises 13 species primarily in the genus Centropomus, known for their elongate forms and popularity in recreational fisheries across the Americas and western Atlantic. The monotypic Lactariidae (false trevallies), with 1 species (Lactarius lactarius), features a deep, silvery body adapted for schooling in Indo-Pacific reefs. The Sphyraenidae (barracudas) contains 29 species in the single genus Sphyraena, distinguished by their slender, pike-like bodies and voracious piscivory in open tropical waters worldwide. The suborder Pleuronectoidei dominates Carangiformes diversity, incorporating the Polynemidae (threadfins) with 42 species across 8 genera, notable for their pectoral fin filaments used in bottom-sensing within estuaries and coastal zones. families within this suborder include the Psettodidae (spiny turbots, 3 species), primitive both-eyed forms with spiny scales in Indo-Pacific shallows; Citharidae (largescale flounders, 7 species), small-eyed species on sandy substrates; Scophthalmidae (turbots, 6 species), migratory forms in temperate Atlantic and Mediterranean waters; and Cyclopsettidae (sand whiffs, 4 species), minute deep-sea dwellers. Recent updates as of have added families such as Grammatobothidae and Monolenidae. An additional 15 families further amplify diversity, such as Bothidae (172 species of lefteye flounders with cryptic patterns), Pleuronectidae (62 species of righteye flounders including halibuts), and Cynoglossidae (161 species of tonguefishes, elongate and sinistral for burrowing in sediments). Suborder Toxotoidei consists of two families: Leptobramidae (beachsalmons, 3 ), silvery coastal pelagics in Australasian waters with elongated fins for schooling; and Toxotidae (archerfishes, 7 ), renowned for water to capture above the surface in Indo-Australian mangroves. The suborder Nematistioidei is monofamilial, with Nematistiidae (roosterfishes, 1 : Nematistius pectoralis), featuring prominent dorsal spines for display in eastern Pacific reefs. Suborder Menoidei includes three families: Menidae (moonfishes, 1 species: Mene maculata), deep-bodied disc-like forms in pelagic zones; Xiphiidae (swordfishes, 1 species: Xiphias gladius), highly migratory apex predators with elongated bills; and Istiophoridae (billfishes, 21 species across 5 genera), including marlins and sailfishes prized in sport fisheries for their speed and osteodermal "swords." Finally, suborder Carangoidei features four families of active swimmers. The (jacks) is the most speciose with 147 in 39 genera across subfamilies Naucratinae (amberjacks), (trevallies), and others, encompassing fast-swimming schooling predators in global tropical seas. The Echeneidae (remoras, 10 ), with modified dorsal fins forming suckers for attachment to hosts like ; Rachycentridae (cobias, 2 ), elongate fishes following large marine vertebrates; and Coryphaenidae (dolphinfishes, 5 ), including the , known for iridescent colors and epipelagic migrations.

Physical characteristics

External morphology

Carangiformes exhibit a diverse array of body forms, ranging from shapes adapted for fast swimming in pelagic species like carangids and sphyraenids () to highly compressed and dorsoventrally flattened bodies in flatfishes of the suborder Pleuronectoidei. This variation reflects adaptations to different ecological niches, with bodies typically elongate and streamlined for open-water locomotion, while compressed forms in flatfishes facilitate benthic lifestyles through that develops during . Fin configurations in Carangiformes are characterized by pelvic fins that vary across suborders: in the suborder Carangoidei, pelvic fins typically bear one spine and five soft rays, distinguishing them from flatfishes in Pleuronectoidei (which lack a spine and usually have six rays) and some other percomorph fishes that have six soft rays. Dorsal and anal fins often feature detached anterior spines, with the first two anal-fin spines typically separated from the remainder in carangids. Pectoral fins vary widely, remaining short and rounded in many species but becoming elongated and falcate in remoras (Echeneidae), aiding in maneuverability and host attachment. Scales in Carangiformes are predominantly cycloid or ctenoid, with some taxa exhibiting spinoid or crenate varieties, and scutes—modified, spiny scales—along the lateral line in groups like carangids. In the suborder Carangoidei, an adipose eyelid, a transparent fatty tissue covering part or all of the eye, is common and well-developed in adults of families such as Carangidae. The lateral line is often prominently curved anteriorly in jacks and trevallies, transitioning to a straight posterior portion with 12 to 30 scutes, and pored scales may extend onto the caudal fin in certain species. Head and mouth morphology varies from terminal mouths in pelagic forms to inferior positions in benthic flatfishes, with some taxa like billfishes (Xiphioidei) featuring elongated formed by the protracted upper jaw. In flatfishes, eyes migrate during such that both become positioned on the dorsal side of the asymmetrically flattened head, enabling upward vision while resting on the seafloor. Coloration in Carangiformes ranges from metallic blues and greens in pelagic species, such as dolphinfishes (Coryphaenidae), which display iridescent hues on the dorsum fading to silvery ventrally, to cryptic browns and mottled patterns in benthic soles (Soleidae) that provide camouflage against substrates. Asymmetry in pigmentation often accompanies ocular migration in flatfishes, with the eyed side more vividly colored than the blind side.

Internal anatomy

The internal anatomy of Carangiformes exhibits several distinctive skeletal features adapted to their diverse lifestyles, ranging from pelagic predation to benthic habitation. The typically includes a prominent supraoccipital crest, which is extended anteriorly by the frontals across the length of the cranium in families like , providing robust attachment for epaxial musculature that supports powerful swimming motions. The is characterized by a posterior process that articulates with the , facilitating protractile jaw mechanics essential for capturing elusive prey in many . Vertebral counts vary across the order, but carangoid families commonly possess 10–11 precaudal and 14–17 caudal vertebrae, totaling 24–27, which contribute to the streamlined body form; in contrast, pleuronectoid flatfishes often have higher counts (up to 30–50 total) for flexibility on the seafloor. The in most Carangiformes is physoclistous, lacking a pneumatic duct to the and relying on vascular for control, a condition typical of advanced percomorph teleosts. In pelagic species such as dolphinfishes (Coryphaenidae) or jacks (), retia mirabilia—dense capillary networks associated with the gas gland—enable efficient oxygen secretion into the bladder, allowing rapid depth adjustments during high-speed pursuits. However, the is absent in flatfishes of the suborder Pleuronectoidei, where benthic adaptations prioritize negative over vertical migration. Sensory systems emphasize mechanoreception over electroreception, with electroreceptors entirely absent in Carangiformes, distinguishing them from electrosensory lineages like . The lateral line system is well-developed throughout the order, featuring branched canals in remoras (Echeneidae) that enhance sensitivity to host movements and aid in maintaining attachment via the modified dorsal disc. , specialized electroreceptors found in elasmobranchs, are not present in this order. Digestive adaptations reflect dietary specialization, with gut morphology varying by feeding . Predatory forms like (Sphyraenidae) possess short intestines (relative gut length <1), optimized for rapid digestion of protein-rich prey and minimizing weight during ambush hunting. In contrast, omnivorous threadfins (Polynemidae), which consume benthic , , and small , exhibit relatively longer guts to accommodate mixed diets and facilitate nutrient extraction from varied sources. Within the suborder Pleuronectoidei, internal undergoes profound reorganization during , transitioning from bilaterally larvae to asymmetrically eyed juveniles. This process involves the migration of one eye across the dorsal midline, driven by asymmetric proliferation in suborbital and remodeling of the ethmoid plate, which shifts larval to the characteristic ocular for bottom-dwelling .

Distribution and habitats

Geographic range

Carangiformes are predominantly marine fishes, with the highest species diversity concentrated in the region, particularly for families such as (jacks and pompanos) and Sphyraenidae (barracudas). The order also exhibits a notable presence in the , including species of snooks (Centropomidae) and jacks (Carangidae) that inhabit coastal and pelagic waters along both eastern and western margins. Pelagic families within Carangiformes, such as Coryphaenidae (dolphinfishes) and Istiophoridae (billfishes and sailfishes), display circumglobal distributions primarily in tropical and subtropical waters across the Atlantic, Indian, and Pacific Oceans. Temperate extensions occur in certain families, notably (righteye flounders), which reach high latitudes including the , as exemplified by species like the (Reinhardtius hippoglossoides). Benthic families like Cynoglossidae (tonguefishes) and (soles) are largely confined to coastal waters of the Indo-West Pacific, from to the western Pacific islands. Freshwater incursions are rare but occur in some threadfins (Polynemidae), which can enter riverine habitats in tropical regions. The order's latitudinal range spans from polar regions to the , with the majority of species concentrated between 30°N and 30°S. Suborder-specific concentrations, such as those of flatfishes in Pleuronectoidei, further emphasize this tropical bias.

Environmental preferences

Members of the order Carangiformes exhibit a wide array of environmental preferences, reflecting their diverse suborders and ecological adaptations within marine and adjacent ecosystems. Predominantly marine, most taxa thrive in salinities ranging from 30 to 35 ppt, though some demonstrate capabilities to tolerate brackish conditions down to near-freshwater levels. Typical temperatures span 10 to 30°C, with optimal ranges varying by suborder and often aligning with tropical to subtropical conditions. The suborders Carangoidei and Menoidei are primarily adapted to pelagic zones, favoring epipelagic to mesopelagic depths of 0 to 200 m in open oceanic waters. Carangoidei species, such as those in the family , often occupy coastal and offshore pelagic habitats influenced by surface temperatures of 25 to 27°C and salinities around 35 ppt. Menoidei, represented by the moonfish ( maculata), prefer deeper coastal waters near the bottom at 50 to 200 m on continental shelves, occasionally entering river estuaries. In contrast, Centropomoidei taxa, including snooks (Centropomidae), are reef-associated and show strong affinity for estuarine and coastal environments such as mangroves, beds, and reefs. These species exhibit high tolerance to low salinities, frequently inhabiting brackish estuaries and even migrating into freshwater habitats. Pleuronectoidei, encompassing flatfishes like flounders and soles, are predominantly benthic and demersal, occupying shelf depths of 10 to 500 m over sandy or muddy substrates. They favor soft-bottom sediments in coastal to areas, with many species concentrated between 40 and 100 m where temperatures range from 10 to 25°C. Soles, in particular, prefer sandy and muddy bottoms for and . Toxotidae, the archerfish family, are surface-oriented and inhabit mangrove-lined coastal areas, freshwater interfaces, and brackish wetlands, tolerating salinities from 0 to approximately 10 ppt. Within Carangiformes, euryhaline adaptations are notable in families like Polynemidae (threadfins), which span marine, brackish, and freshwater realms, often in estuarine settings with salinities as low as 5 ppt. Billfishes, such as those in Istiophoridae, prefer open-water pelagic environments across vast oceanic expanses, typically in epipelagic zones above 200 m. These preferences overlap with the global tropical oceanic range of Carangiformes, underscoring their adaptability to varied aquatic niches.

Biology and ecology

Feeding and diet

Carangiformes exhibit predominantly carnivorous feeding strategies, with most species preying on other fish, , and to meet their energetic demands. In the family Sphyraenidae (), individuals are strictly piscivorous throughout their lives, targeting small schooling fishes such as , herrings, and anchovies, with occasional prey like supplementing the diet during opportunistic encounters. Similarly, members of the () are voracious predators that consume a diverse array of small fishes, including clupeids and exocoetids, alongside planktonic and minor contributions, reflecting their adaptation to pelagic environments. The Coryphaenidae (dolphinfishes) demonstrate a strong preference for teuthophagy, with comprising a significant portion of their diet—up to 30-50% in some populations—complemented by flyingfishes and , which supports their high metabolic rates during long migrations. Flatfishes in families such as , Bothidae, and Paralichthyidae are benthic ambush predators, primarily consuming polychaete worms, crustaceans (e.g., amphipods, mysids), mollusks, and small bottom-dwelling fishes, with ontogenetic shifts from meiofauna in juveniles to larger prey in adults. Billfishes in Istiophoridae and Xiphiidae are apex pelagic predators that slash schools of large fishes (e.g., tunas, mackerels) and cephalopods using their elongated rostra, followed by opportunistic engulfment, with diets dominated by teleosts (50-80%) and . Many Carangiformes species undergo ontogenetic shifts in diet, transitioning from planktivory in larval stages to active predation as adults, which allows for efficient resource partitioning and growth optimization. For instance, in Carangidae such as the Atlantic horse mackerel (Trachurus trachurus), juveniles primarily ingest and small crustaceans, while adults shift to larger prey, correlating with increased body size and gape limitation. In Coryphaenidae, early juveniles favor smaller and crustaceans, progressing to more diverse piscivory with size, as evidenced by stomach content analyses in the . These shifts are facilitated by morphological changes, including the development of larger mouths and teeth suited for capturing elusive prey. Schooling behavior in carangids enhances efficiency by increasing encounter rates with prey schools and reducing individual search costs through coordinated attacks. Observations of like the bluefin trevally (Caranx melampygus) reveal that groups spawning fishes, with synchronized movements confusing prey and improving capture success rates by up to 20-30% compared to solitary . This collective strategy is particularly effective in open-water environments, where visual cues from conspecifics amplify detection of patchy food resources. Specialized feeding adaptations are evident in certain families, diverging from the typical predatory norms. Archerfishes (Toxotidae) employ a unique projectile mechanism, spitting jets of water to dislodge insects and small arthropods from overhanging vegetation, achieving accuracies of over 80% at distances up to 1.5 meters through precise mouth positioning and grooved tongue structures. Remoras (Echeneidae) exhibit kleptoparasitic , attaching to larger marine hosts like and feeding on food scraps, external parasites, and entrained in the host's , which provides a low-energy diet without direct hunting. In the Polynemidae (threadfins), juveniles often engage in ram-filtering of using elongated pectoral rays to herd prey, while adults target benthic crustaceans and small fishes, illustrating a partial reliance on filter-feeding early in life.

Reproduction and life cycle

Carangiformes species are gonochoristic, with separate sexes and no hermaphroditism reported across major families such as , Coryphaenidae, and Istiophoridae. Reproduction involves , where females release buoyant, pelagic eggs into the water column that are simultaneously fertilized by males without any or internal . Post-fertilization, there is no , and eggs develop independently in the open ocean. Most species are multiple batch spawners, releasing successive clutches of eggs over extended spawning periods that align with seasonal environmental cues, often peaking in warmer months. In , such as mediterraneus, females may produce up to 20 batches during a 3-4 month season, spawning every 6-7 days. Coryphaenidae and Istiophoridae exhibit similar iteroparity, with spawning capable of occurring year-round in tropical regions but concentrated in summer periods in temperate zones. Fecundity is notably high in pelagic members, supporting their r-selected life histories. For instance, female dolphinfish ( hippurus) in Coryphaenidae can produce 0.2–3 million eggs annually, based on multiple spawns per year and scaled to body size. In Istiophoridae, such as (Istiophorus platypterus), individual females release up to 20 million eggs per season from ovaries weighing up to several kilograms. These high outputs compensate for high larval mortality in open-water environments. Eggs hatch within 1-3 days into planktonic -sac larvae, which absorb the yolk reserve over 2-5 days before transitioning to active feeding on . Larval development includes distinct phases: preflexion (body straight, yolk absorption), flexion ( bending for caudal formation), and postflexion (full development and settlement toward juvenile morphology), typically spanning 20-40 days before . In billfishes, larvae feature elongated bodies adapted for fast swimming, while carangid larvae often display early schooling behavior. Growth is rapid, enabling early maturity and high reproductive turnover, particularly in tropical taxa. Many Carangidae reach sexual maturity at 1-2 years, such as Trachurus species at around 2 years and 16 cm length. Coryphaenidae like dolphinfish mature even faster, at 4-5 months. Longevity varies from 5-11 years in smaller carangids to over 20 years in larger species like the giant trevally (Caranx ignobilis), which can exceed 25 years. Spawning grounds are often influenced by productive oceanic fronts and warm currents, enhancing larval survival.

Predation and symbiosis

Carangiformes species, particularly juveniles, face predation from larger piscivorous fishes such as and tunas, which target smaller individuals in open waters. Surface-schooling behaviors in many carangids, like the (Caranx bartholomaei), expose them to avian predators including terns and noddies, as well as marine mammals such as dolphins that herd and consume schools. Adult (Sphyraena spp.) are occasionally preyed upon by apex predators like killer whales, large , and groupers, though their size and agility reduce vulnerability. To counter these threats, carangiform fishes exhibit several anti-predator adaptations. Schooling is prevalent among jacks (Carangidae), where coordinated group movements confuse predators and dilute individual risk during attacks on dense formations. In barracudas, exceptional burst swimming speeds of up to 58 km/h enable rapid evasion or counterattacks against pursuing threats. Countershading—darker dorsal surfaces blending with ocean depths and lighter ventral sides matching the water's brightness—provides visual camouflage for pelagic species like blue runner (Caranx crysos) against overhead or underwater predators. Symbiotic relationships play a key role in the ecology of Carangiformes. Remoras (Echeneidae), a family within the order, form commensal associations with sharks and whales, attaching via specialized suction discs on their heads to hitch rides and access food scraps while minimally impacting the host. This attachment allows remoras to feed on parasites and debris from the host's skin, facilitating dispersal across vast oceanic ranges. Additionally, some carangids benefit from cleaning symbioses, where smaller fish like juvenile leatherjackets (Oligoplites saurus) remove ectoparasites from the bodies and gills of larger carangids, reducing infection loads in exchange for access to mucus and scales. Parasitic interactions are common, particularly among pelagic carangids, with ectoparasitic s infesting gills and body surfaces, leading to tissue damage and reduced swimming efficiency. Eight have been documented on Indian Ocean carangids like Carangoides spp., with prevalence up to 100% in some hosts, impairing respiration and host condition. These parasites indirectly affect fisheries by lowering catch quality and , as heavy infestations correlate with decreased flesh quality in commercially important like the green jack (Caranx caballus), exacerbating pressures from that disrupts natural parasite-host dynamics.

Evolution and fossil record

Origins and diversification

The order Carangiformes originated in the , with a stem age estimated at approximately 98.87 million years ago (95% : 87.37–110.69 Ma), within the diverse of spiny-rayed fishes (). This early divergence aligns with the broader radiation of percomorph lineages around 84–93 Ma, positioning Carangiformes as part of Clade L (Carangimorpha) that emerged amid the diversification of fishes. Following the Cretaceous-Paleogene (K-Pg) at ~66 Ma, surviving carangiform ancestors—particularly within the sub-clade Carangoidei—underwent a significant post-extinction radiation, capitalizing on vacated marine niches in the Early . Diversification within Carangiformes accelerated during the Eocene epoch (56–33.9 Ma), marking a peak for the evolution of key morphological innovations, such as the cranial asymmetry in flatfishes (Pleuronectoidei), which facilitated their benthic adaptations. A second major pulse occurred in the (23–5.3 Ma), particularly among tropical marine families like , coinciding with the progressive closure of the Tethys Sea and the resultant reconfiguration of ocean basins. analyses, calibrated with fossil constraints, indicate that splits among major sub-clades (e.g., between Centropomoidei and Carangoidei) occurred between 50–40 Ma, while family-level radiations, including those of jacks and pompanos, intensified from 30–10 Ma. Key drivers of this diversification included major tectonic events that reshaped marine habitats and promoted isolation. The closure of the Tethys Sea during the Eocene to facilitated vicariance and eastward faunal shifts toward the , enhancing in reef-associated lineages. Similarly, the gradual uplift of the around 10–3 Ma isolated Atlantic and populations, driving divergence in coastal carangiforms such as snooks (Centropomidae), though with limited transisthmian pairs indicating additional ecological factors at play. Ecological opportunism further propelled diversification, as carangiforms exploited expanding coral reefs, continental shelves, and pelagic zones, with adaptations in locomotion and feeding enabling colonization of diverse marine environments post-K-Pg.

Notable fossils

The earliest known fossil record of Carangiformes dates to the , represented by Mene purdyi, a primitive moonfish-like species from northwestern estimated at approximately 55 million years ago (late Thanetian stage). This species, belonging to the family Menidae, exhibits disk-shaped morphology typical of early carangiforms and provides evidence of the order's post-Cretaceous-Paleogene diversification in tropical marine environments. Eocene deposits yield several notable carangiform fossils, including Ductor vestenae from the Monte Bolca in , a small (up to 17 cm) carangid-like from the early Eocene (Ypresian stage). This taxon features a slender body and structure suggestive of basal percomorph affinities within Carangiformes, highlighting early adaptations in the order's . From the , Oligoremora rhenana stands out as a key fossil, discovered in the Frauenweiler clay pit of ( stage), representing an early echeneid (remora) ancestor in the superfamily Echeneoidea. This species, approximately 10 cm long, shows primitive traits of the adhesion disc and sucking mouth, indicating the evolutionary assembly of remora morphology during the late . and strata document further diversity, including fossils such as species of Eobothus from Eocene deposits in , and other early pleuronectoid forms from and sites in , including otolith records from deposits near , . These small (under 10 cm), asymmetrical-bodied taxa from the suborder Pleuronectoidei illustrate the order's adaptation to benthic lifestyles in shallow marine settings. Additionally, ancestors in the genus Sphyraena appear in - assemblages from the , such as the Palmetto and Torreya faunas in , where isolated teeth and skeletal elements reveal piscivorous predators up to 1 m in length. Extinct families and genera within Carangiformes include potential basal forms allied to Percoidei, such as early carangids and sphyraenids, contributing to a record exceeding 50 described across the order. These s, spanning to deposits, have been instrumental in calibrating molecular phylogenies and tracing the temporal diversification of carangiform lineages.

Diversity and conservation

Species richness

The order Carangiformes comprises approximately 1,100 valid distributed across 29–34 families, reflecting its broad phylogenetic scope that includes both pelagic and benthic lineages. Within this diversity, the suborder Pleuronectoidei stands out as the most , encompassing around 800 of flatfishes and soles across 14 families, which account for the majority of the order's . Patterns of species richness vary geographically, with notable hotspots in the Coral Triangle region, where (jacks and pompanos) and Polynemidae (threadfins) achieve peak diversity due to the area's extensive systems and tropical marine habitats. In contrast, the Tropical Eastern Pacific serves as a diversity center for certain flounder species within and related families, driven by upwelling-driven productivity and coastal complexity. Endemism is pronounced in isolated oceanic basins, particularly around islands, where restricted fosters unique assemblages; for instance, the Cynoglossidae (tongue soles) exhibits genus-level radiations, with over 130 showing adaptive diversification in shallow to deep-water niches. Recent taxonomic trends indicate ongoing discoveries in under-explored habitats, such as new deep-sea sole like Symphurus multimaculatus from Taiwanese waters, contributing to incremental increases in Cynoglossidae counts. Conversely, well-studied groups like show stable tallies, with 147 valid reflecting comprehensive historical sampling in coastal and environments.

Threats and status

Overfishing represents the primary threat to many within Carangiformes, particularly in commercially important families such as and Sphyraenidae, where intense harvesting has led to stock depletions in various regions. For instance, pelagic like those in Istiophoridae (billfishes) face significant pressure from longline fisheries, resulting in population declines and contributing to their vulnerable status. in industrial fisheries targeting other groups, such as tunas, also incidentally captures Carangiformes , exacerbating mortality rates. Habitat degradation from coastal development poses a severe risk to inshore species, including snooks in Centropomidae and threadfins in Polynemidae, which rely on estuarine and nurseries for juvenile stages. and hydrologic alterations have reduced these critical habitats, limiting and increasing vulnerability to other stressors. Additionally, affects larval development across marine fishes, potentially impairing sensory functions and growth in Carangiformes larvae, though species-specific responses vary. According to the , the majority of assessed Carangiformes species are categorized as Least Concern, reflecting localized declines from anthropogenic pressures in some cases. Notable examples include the blue marlin (Makaira nigricans) in Istiophoridae, listed as Vulnerable primarily from and targeted . The fat snook (Centropomus parallelus) in Centropomidae is listed as Least Concern globally, though it faces regional pressures from and loss. The royal threadfin (Polydactylus plebeius) in Polynemidae and the fourfinger (Eleutheronema tetradactylum) are currently Not Evaluated by IUCN, but both experience threats from and degradation in parts of their ranges. Conservation efforts for Carangiformes emphasize through quotas in exclusive economic zones (EEZs), particularly for high-value species like (Rachycentron canadum) in Rachycentridae, where allocations help control harvest levels. Marine protected areas safeguard reef-associated habitats for families like , reducing fishing impacts and supporting population recovery. initiatives show promise for , with cage culture in regions like alleviating pressure on wild stocks while providing economic alternatives.

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