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Teleost

Teleostei, commonly referred to as teleosts, is an infraclass of ray-finned fishes within the class Actinopterygii, representing the most speciose and diverse clade of vertebrates with approximately 34,000 described species (as of 2024) that account for roughly half of all living vertebrates and approximately 96% of extant fish species. These fishes first appeared in the Late Triassic period and became ecologically dominant by the end of the Cretaceous, radiating into nearly every aquatic habitat worldwide, from freshwater streams and lakes to marine environments including coral reefs, open oceans, and abyssal depths. Teleosts are distinguished by several defining anatomical innovations, such as a highly mobile upper jaw with protrusible premaxilla and maxilla enabling efficient prey capture, a symmetrical homocercal caudal fin for enhanced maneuverability, thin overlapping cycloid or ctenoid scales providing flexibility and protection, and a gas-filled swim bladder that aids in buoyancy control and, in some species, sound production or hearing. Classified into about 40 orders and over 450 families, teleosts encompass a vast array of forms and lifestyles, from elongate eels and deep-sea anglerfishes to disc-shaped flatfishes and fast-swimming tunas, with many species serving critical ecological roles as primary consumers, predators, or prey in food webs. Their evolutionary success stems from genomic innovations, including whole-genome duplications early in their lineage that facilitated adaptive radiations, as well as physiological adaptations like specialized osmoregulation and reproductive strategies ranging from broadcast spawning to live-bearing. Economically and culturally significant, teleosts form the basis of global fisheries, aquaculture, and ornamental trades, though many species face threats from overexploitation, habitat loss, and climate change.

Classification

Definition and Characteristics

Teleosts, formally known as the infraclass Teleostei, represent the largest within the ray-finned fishes (class ), encompassing over 30,000 extant that account for approximately 96% of all diversity. As of 2025, described number approximately 35,000. This vast group dominates modern aquatic ecosystems, ranging from freshwater rivers to deep ocean trenches, and includes economically vital such as , , and . Their success stems from a suite of morphological innovations that enhance feeding efficiency, , and sensory capabilities, distinguishing them from more primitive actinopterygians like sturgeons and paddlefishes. Key morphological traits of teleosts include or ctenoid scales, which are thin, flexible dermal structures covering the body and providing protection while allowing flexibility; scales are smooth-edged and typical of more basal forms, whereas ctenoid scales feature comb-like projections on their posterior margin for added traction in faster-swimming species. The tail is homocercal, symmetrically divided with equal upper and lower lobes supported by expanded uroneurals, enabling efficient propulsion and maneuverability compared to the heterocercal tails of earlier ray-finned fishes. Teleosts possess highly protrusible formed by a mobile and , allowing the mouth to extend forward to suction-capture prey, complemented by robust pharyngeal jaws—specialized tooth-bearing structures in the —that handle , grinding, and transport to the . A , derived embryonically from an anterior outpouching of the gut, functions primarily for regulation by adjusting gas volume to maintain neutral density in the , a critical for energy-efficient swimming. Certain teleost subgroups exhibit specialized adaptations, such as the in otophysans (e.g., carps and catfishes), a chain of connecting the to the that amplifies sound vibrations, enhancing hearing sensitivity across a broader range for predator detection and communication. The basic is often —streamlined and torpedo-shaped for hydrodynamic efficiency, as seen in and —but teleosts display remarkable morphological diversity, including elongated forms like eels adapted for burrowing and anguilliform swimming, and dorsoventrally flattened bodies in flatfishes for demersal life on the seafloor. This variability underscores their across habitats.

Taxonomic Position

Teleosts, members of the infraclass Teleostei, are positioned within the class (ray-finned fishes), which falls under the superclass (bony fishes), Vertebrata, and Chordata. The taxonomic history of teleosts traces back to Linnaean systems in the , which grouped fishes primarily by morphological traits such as structure and scale types, often resulting in artificial classifications. By the mid-20th century, this evolved into more systematic approaches, culminating in the seminal 1966 work by Greenwood et al., which introduced a cladistic framework dividing Teleostei into four major subdivisions—Osteoglossomorpha, Elopomorpha, Otocephala, and Euteleostei—based on shared derived characters like mechanics and supports. Subsequent revisions in the late 20th and early 21st centuries incorporated molecular data, refining these groups; for instance, Otocephala was solidified as encompassing clupeomorphs and otophysans through analyses of , while Euteleostei emerged as the largest including advanced percomorphs. Among major orders, Salmoniformes represents a key group within the Protacanthopterygii subdivision of Euteleostei, comprising , , and allies characterized by primitive features like an . Historically, was treated as the largest teleost order, encompassing over 7,000 species in 160 families, but molecular phylogenies have revealed its , prompting its disassembly into at least 13 distinct orders such as , Gobiiformes, and Labriformes, with relationships resolved via multi-locus datasets including nuclear and mitochondrial genes. Recent phylogenomic classifications, integrating whole-genome and transcriptomic data from thousands of taxa, estimate Teleostei to include 72 orders and 514 families, reflecting ongoing refinements to monophyletic groupings. This framework accounts for over 30,000 extant , underscoring teleosts' dominance in diversity.

Diversity

Teleosts represent the most diverse group of , with over 30,000 described , accounting for about 96% of all extant species. is highest in tropical regions, where environmental stability and foster extensive adaptive radiations. Among the major clades, stands out with around 4,300 species, including familiar groups like carps, minnows, and , predominantly in freshwater ecosystems of and . , encompassing tetras and piranhas, comprises approximately 2,000 species, largely confined to Neotropical rivers and streams. The , though paraphyletic, is the largest order with over 10,000 species, featuring perches, groupers, and across and freshwater environments worldwide. Teleost diversity spans remarkable extremes in size and abundance. The (Mola mola), the heaviest bony , can reach lengths exceeding 3 meters and weights up to 2 tonnes. At the opposite end, paedomorphic species like mature at less than 8 mm in length, representing the smallest known vertebrates. In terms of biomass, the Atlantic herring (Clupea harengus) forms some of the largest schools, contributing to its status as one of the most abundant species globally, with populations supporting vast food webs.

Evolution

Origins and Early Evolution

Teleosts, the most diverse group of ray-finned fishes (), trace their origins to the period, with the earliest known stem-group representatives appearing around 240 million years ago (Ma) during the Late Ladinian stage in southern . These primitive forms, belonging to the Pholidophoriformes, were small-bodied (approximately 50 mm in standard length) or oblong fishes adapted as feeders, exhibiting a conservative typical of early neopterygians. Fossils from this time, such as those described from the Zhuganpo Formation, represent the oldest documented stem teleosts and indicate that the lineage had already begun to diverge from more basal ray-finned ancestors shortly after the Permian-Triassic mass extinction. Teleosts evolved from earlier ray-finned fishes within the , including perleidid forms like Perleidus from the (Dienerian stage, approximately 252–247 Ma), which possessed generalized neopterygian traits such as robust scales and a predatory morphology but lacked advanced teleostean specializations. By the to (approximately 210–200 Ma), stem teleosts had diversified modestly, with fossils conforming to a basic shape and ganoid scales, as seen in early leptolepid-grade taxa. A key early fossil genus, Pholidophorus, known primarily from Jurassic deposits (Toarcian stage, approximately 183 Ma) in , displays primitive teleost features including partial mobility of the bone, which enhanced jaw protrusion for capturing prey, and a with some ossified elements. These traits mark a transitional stage from holostean-like ancestors toward the more derived crown-group teleosts. The initial radiation of teleosts accelerated through the and periods, but a significant post- explosion in diversity occurred after the Cretaceous-Paleogene (K-Pg) boundary mass extinction around 66 Ma, which eliminated many non-teleostean marine fishes and opened ecological niches. This diversification was facilitated by environmental changes, including the rise of angiosperms during the , which altered freshwater habitats by providing new food sources and structural complexity, and widespread marine transgressions that expanded shallow coastal and epicontinental seas. Evolutionary innovations, such as enhanced jaw mechanics with a mobile and for improved gape and suction feeding, and the evolution of a physoclistous for precise regulation, allowed teleosts to exploit pelagic and benthic niches more effectively than their ancestors. These adaptations, combined with a whole-genome duplication event early on the teleost stem lineage (estimated at 300–250 Ma), contributed to their rapid morphological and ecological expansion.

Phylogenetic Relationships

The phylogenetic relationships within Teleostei have been reconstructed using integrated fossil and molecular datasets, revealing a structured evolutionary tree with distinct basal divisions. The earliest divergence separates the clade Eloposteoglossocephala—comprising Elopomorpha (e.g., eels and tarpons) and Osteoglossomorpha (e.g., and elephantfish)—as sister to Clupeocephala, which encompasses the majority of teleost diversity. Within Clupeocephala, Otocephala forms a basal group that includes Clupomorpha (e.g., herrings) and (e.g., carps and catfishes), followed by Protacanthopterygii (e.g., salmons and trouts), and culminating in the highly diverse (e.g., perches and tunas). This topology integrates morphological characters with genomic evidence, highlighting teleosts' radiation from a common ancestor in the . Molecular phylogenetics has profoundly shaped this understanding, with studies from the 2000s to 2020s leveraging increasing genomic resources to resolve historical polytomies at the teleost base. Initial efforts using and multi-locus nuclear markers in the early 2000s provided preliminary support for major clades but struggled with incomplete sampling and conflicting signals. The advent of large-scale phylogenomics in the 2010s, exemplified by the Genome 10K Community of Scientists' efforts to sequence over genomes including hundreds of teleosts, enabled analyses of thousands of orthologous genes across diverse taxa, confirming relationships like the monophyly of Otocephala and the deep split between Elopomorpha and other teleosts. By the 2020s, chromosome-level assemblies and methods like chromatin mapping further clarified branching patterns, reducing uncertainty in polytomous regions near the root. Recent phylogenomic analyses from 2023 onward have introduced refinements to this framework, particularly in basal clades such as Anotophysi within , where improved sampling and synteny-based approaches have clarified interordinal relationships previously obscured by rapid diversification. These clades are bolstered by key synapomorphies; for instance, advanced teleosts in Euteleosteomorpha (including Protacanthopterygii and ) exhibit the loss of the intercalar bone, a derived cranial feature absent in more basal groups like Elopomorpha. Similarly, Otocephala is defined by innovations in the otophysic system, such as modified anterior vertebrae forming sound-transmission pathways, distinguishing it from adjacent clades. Such morphological markers, when corroborated by molecular data, underscore the robustness of the integrated phylogeny.

External Relationships

Teleostei, the largest clade within , is positioned as the to (comprising gars and bowfins) within the subclass , with (sturgeons and paddlefishes) serving as the immediate outgroup to this neopterygian clade. This phylogenetic arrangement reflects a basal divergence in ray-finned fishes, where (bichirs) represents the most primitive actinopterygian lineage outside these groups. Shared ancestral traits among non-teleost actinopterygians include robust, rhomboidal ganoid scales covered by a shiny ganoine layer, which provide heavy dermal armor but limit flexibility, in contrast to the thinner, more pliable leptoid scales ( or ctenoid) that characterize teleosts and enable greater body maneuverability. Within the broader superclass , teleosts as actinopterygians contrast sharply with sarcopterygians (lobe-finned fishes, including coelacanths, lungfishes, and the lineage leading to tetrapods) in fin structure and ; actinopterygian fins are supported by lepidotrichia (rays) for precise and speed, whereas sarcopterygian fins fleshy lobes with internal bones akin to limb . This dichotomy underscores the adaptive divergence in , where ray-finned fishes like teleosts colonized diverse aquatic niches through fin ray innovations, while lobe-finned forms emphasized terrestrial transitions. The evolutionary success of teleosts, encompassing over 30,000 and comprising approximately 96% of extant , surpasses that of their holostean relatives (fewer than 10 ) due to specialized innovations such as protractile upper for versatile feeding and enhanced function for buoyancy control, which facilitated rapid and ecological dominance in and freshwater environments. Although early teleosts did not exhibit markedly accelerated phenotypic compared to holosteans, their cumulative adaptations in sensory systems and reproductive strategies outpaced the more conservative holostean lineage, leading to teleost radiation during the era.

Internal Relationships

Teleostei, the dominant of ray-finned fishes, comprises two main branches based on molecular phylogenies: Eloposteoglossocephala (Elopomorpha and Osteoglossomorpha) and Clupeocephala (Otocephala and Euteleostei). Elopomorpha and Osteoglossomorpha represent the earliest diverging sister s, with Elopomorpha encompassing elongate-bodied forms such as eels and tarpons, which exhibit unique larval stages and a . This is supported as monophyletic in comprehensive phylogenomic analyses, with the Elopomorpha-Osteoglossomorpha split near the base of Teleostei approximately 280 million years ago. Osteoglossomorpha, sister to Elopomorpha, includes species such as the arapaima (Arapaima gigas) and elephantnose fish (Gnathonemus petersii), characterized by a basihyal tooth plate and other adaptations for specialized feeding. This clade also originated near the base of Teleostei approximately 280 million years ago. Otocephala forms a basal group within Clupeocephala, comprising Clupeomorpha (herrings and allies) and the derived subgroup Otophysi. Otophysi, a hearing-specialized clade, is characterized by the evolution of the Weberian apparatus, a series of modified vertebrae that connect the swim bladder to the inner ear for improved sound detection; this innovation underlies the success of groups like carps, catfishes, and tetras. The monophyly of Otocephala is robustly supported by nuclear and mitochondrial DNA datasets, with divergence estimates placing its origin around 260 million years ago. Euteleostei constitutes the most species-rich division within Clupeocephala, accounting for over 90% of teleost diversity and including advanced lineages such as Protacanthopterygii ( and ), Paracanthopterygii (cod-like fishes and anglerfishes), and (spiny-rayed teleosts). Paracanthopterygii is defined by features like a forward-displaced and specialized light organs in some members, while Acanthomorphs are distinguished by strong spines in the dorsal and anal fins, enabling diverse ecological adaptations. Within , emerges as a hyperdiverse encompassing perches, tunas, and flatfishes. Recent genomic studies in the have profoundly revised the internal structure of , elevating many former perciform families to distinct orders based on phylogenomic evidence from thousands of loci. These analyses have delineated over 40 orders within , resolving long-standing ambiguities in relationships among tropical reef fishes, deep-sea anglers, and pelagic predators. Additionally, emerging data on deep-sea clades, such as (dragonfishes, viperfishes, and bristlemouths), have refined their placement within Euteleostei, revealing novel interrelationships through whole-genome phylogenies that highlight rapid radiations in abyssal environments.

Evolutionary Trends

Teleosts exhibit remarkable evolutionary trends in morphological diversification, including extensive variation in , enhanced jaw complexity to accommodate diverse feeding strategies, and specialization of rays for improved maneuverability. size in teleosts spans an extraordinary , from the minute 7.9 mm to the elongate Regalecus glesne reaching over 10 m in length or the massive Mola mola weighing up to 2.3 tonnes, reflecting adaptive radiations that have enabled exploitation of varied ecological niches across aquatic environments. Jaw structures have evolved increasing complexity, particularly through innovations like protrusible jaws and decoupled oral-pharyngeal systems, allowing for specialized diets from suction-feeding on to biting herbivory or durophagy on hard prey, which has driven trophic diversification in reef and lacustrine habitats. Fin ray specializations, such as segmented lepidotrichia in pectoral and caudal , have facilitated precise control of hydrodynamic forces, enhancing agility in maneuvers like burst swimming or station-holding in currents, as seen in the flexible ray arrangements of families like . A prominent key shift in teleost involves repeated invasions from marine to freshwater habitats, with approximately 43% of all extant species—and a similar proportion of teleosts—now occupying freshwater systems despite oceans covering 71% of Earth's surface. This transition, occurring multiple times across lineages like and Siluriformes, has been facilitated by physiological adaptations in and has led to accelerated rates in isolated riverine and lacustrine environments. Convergent ecomorphologies have also arisen repeatedly, exemplified by anglerfishes (Lophiiformes), where independent evolutions of bioluminescent lures and extreme in deep-sea clades have enabled predatory success in nutrient-poor abyssal zones through synergistic morphological innovations.00576-1) Genomic evolution in teleosts has been marked by lineage-specific whole-genome duplications (WGDs), such as the salmonid-specific fourth (Ss4R) approximately 80 million years ago, which provided raw genetic material for adaptations like anadromous life cycles and enhanced immune responses in lineages including . This WGD, distinct from the three basal teleost duplications, has resulted in retained paralogs that underpin physiological plasticity, such as in and growth regulation, contributing to the ecological success of salmonids in variable salinity environments. Recent climate models from 2024 and project intensifying evolutionary pressures on teleosts due to , forecasting reduced sensory acuity and behavioral disruptions in species like pomacentrids, potentially driving shifts toward acidification-tolerant genotypes or local extinctions in vulnerable reefs. These projections, based on coupled ocean-biogeochemical simulations, indicate that aragonite saturation declines could exacerbate synergies, selectively favoring teleosts with robust ionoregulatory mechanisms over the coming decades.

Anatomy

External Morphology

Teleost fishes display remarkable diversity in external morphology, reflecting adaptations to varied aquatic environments. The body shape is a key feature, with (spindle-like) forms predominant in pelagic species such as tunas (family ), where the streamlined profile minimizes drag for sustained high-speed swimming. Depressed (dorsoventrally flattened) bodies occur in benthic dwellers like soles (family ), facilitating close contact with the for ambush predation and evasion. Laterally compressed shapes are common in reef-associated fishes, such as (family Labridae), enabling rapid maneuvers through complex structures. These variations in body form, quantified by metrics like depth relative to standard length (often 20-30% in types), underscore the group's . Scales form a protective integument over the body, with teleosts primarily bearing cycloid or ctenoid types. Cycloid scales are smooth, rounded, and overlapping, typical of basal teleosts like herrings (family Clupeidae), providing flexibility and low friction during movement. Ctenoid scales, featuring posterior comb-like denticles (cteni), are diagnostic of advanced percomorphs such as perches (family Percidae), where the rough texture aids in predator deterrence and enhances hydrodynamic properties. The underlying skin includes multicellular mucous glands that secrete a slime layer, reducing parasite attachment and osmotic stress while contributing to coloration via melanophores, iridophores, and xanthophores for crypsis or aposematism in species like the clownfish (genus Amphiprion). Fins represent another hallmark of teleost design, composed of lepidotrichia (fin rays) that allow precise control. Paired fins—pectoral (positioned high on the sides) and pelvic (ventral)—primarily function in braking, turning, and hovering, with pectorals often enlarged in flyingfishes (family Exocoetidae) for aerial leaps. Unpaired fins include one or more dorsals, an anal, and the caudal, which drives propulsion; the caudal is typically homocercal (symmetrical lobes) in derived teleosts for efficient thrust. Acanthomorphs, comprising about half of teleost species (over 16,000 species), feature spinous anterior rays in dorsal and anal fins (e.g., sharp, locking spines in scorpionfishes, family ) for defense, contrasting with the flexible soft posterior rays that enable undulatory motion. Head morphology is highly specialized, often with a highly protrusible upper jaw formed by the and , permitting significant extension—up to about 65% of head length in some predators—to engulf elusive prey. Terminal or inferior mouths predominate, but superior positions occur in surface feeders such as halfbeaks (family Hemiramphidae). Sensory barbels, fleshy filaments innervated by the , adorn the chin or nostrils in catfishes (order Siluriformes), serving chemosensory roles in turbid habitats; these can extend beyond the body length in some species like the goonch (). Eye placement varies, from dorsal in flatfishes for upward vigilance to lateral in open-water forms.

Internal Anatomy

The digestive tract of teleosts varies significantly with , reflecting adaptations to different feeding strategies. Carnivorous typically possess a short gut, optimized for rapid of protein-rich prey, while herbivorous teleosts exhibit a longer intestinal tract to facilitate the breakdown of material through extended and processes. The presence of a also differs among teleosts; many carnivores and omnivores have a well-developed stomach for initial acid digestion, but numerous , particularly herbivores and some detritivores, lack a distinct stomach, relying instead on a straight or coiled intestine for enzymatic processing. For example, in cyprinid fishes like carps, the absence of a stomach correlates with their , where the intestine serves as the primary site for both mechanical and chemical . The in teleosts features a linear, single-circuit arrangement that efficiently delivers oxygenated throughout the body. The heart consists of four sequential chambers: the , which receives deoxygenated ; the atrium, which contracts to pass to the ventricle; the thick-walled ventricle, the primary pumping chamber; and the bulbus arteriosus, which smooths pulsatile flow into the ventral . From the ventral , flows to the four pairs of gill arches, where it is oxygenated before entering the dorsal for systemic distribution. This setup ensures that deoxygenated is fully oxygenated at the gills prior to circulation, supporting the high metabolic demands of active species like tunas. The of teleosts is centralized in the and , with brain regions particularly adapted to sensory inputs for and predation. The telencephalon processes olfactory , crucial for detecting chemical cues in water, while the optic tectum in the mesencephalon integrates visual signals, enabling precise responses to movement in turbid environments. The coordinates motor functions and balance, often enlarged in species relying on fast swimming, and the rhombencephalon handles inputs for detecting vibrations and pressure changes. These adaptations enhance survival in diverse habitats, as seen in electrosensory-specialized teleosts where the medulla processes electric field data for prey location. Gills in teleosts are intricate respiratory structures supported by four pairs of gill arches, each bearing numerous filaments lined with secondary lamellae that maximize surface area for . The operculum, a protective bony flap, covers and seals the gill chamber, facilitating unidirectional : enters the mouth, passes over the s during , and exits via the opercular slit, preventing backflow and optimizing oxygenation efficiency. In ram-ventilating species like sharks (though analogous in teleosts such as mackerels), constant forward motion aids this , but most teleosts use opercular movements to alternate and for effective .

Skeletal and Muscular Systems

The teleost exhibits a highly kinetic , featuring numerous mobile bones that facilitate complex movements during feeding. Key elements include the and of the upper , which can protrude anteriorly through a system involving the palatoquadrate and hyoid apparatus, enabling rapid extension of the mouth to engulf prey. This protrusibility, a derived trait in teleosts, enhances feeding efficiency by positioning the closer to the target without requiring excessive head movement. The of teleosts comprises a with typically more numerous vertebrae than in basal actinopterygians, often totaling 30 to over 60 elements, which accommodates diverse body elongations and flexibilities. Precaudal vertebrae bear that extend ventrolaterally to shield abdominal viscera and anchor epaxial and hypaxial muscles, while caudal vertebrae feature haemal spines and arches supporting the tail fin. Intermuscular bones may also form within myosepta, further reinforcing the axial framework. In the , teleost fins are supported by radial elements from the pectoral and pelvic girdles, with lepidotrichial rays forming the flexible, branched structures of most fins for maneuverability and . Many acanthomorph teleosts possess rigid, unbranched spines in the , anal, and pelvic fins, derived from modified rays, which provide defensive and structural rigidity during locomotion. These supports articulate via pterygiophores with the , allowing fin undulation. Teleost musculature is segmented into myomeres—chevron-shaped units arranged along the body axis—that contract in waves to generate undulatory propulsion for . Each myomere contains distinct fiber types: superficial red fibers, rich in mitochondria and for aerobic endurance during sustained cruising, and deeper white fibers, specialized for bursts of speed via . This zonal organization optimizes energy use for varied locomotor demands.

Distribution and Ecology

Global Distribution

Teleosts are distributed worldwide, occupying diverse environments from freshwater systems like and lakes to habitats ranging from shallow coastal zones to the abyssal depths exceeding 4,000 meters. Approximately 58% of teleost are , dominating oceanic ecosystems, while 41% inhabit freshwater, a disproportionate representation given that freshwater constitutes less than 0.01% of global volume. Freshwater teleost diversity peaks in tropical river basins, with the hosting over 2,400 and the supporting nearly 1,150, many of which are endemic to these regions. Biogeographic patterns highlight the as a premier hotspot for fishes, with over 3,900 , many concentrated in areas like the Coral Triangle, where reef and coastal assemblages drive exceptional richness. is pronounced in ancient lakes, such as , which harbors diverse radiations of sculpins (family Cottidae) comprising over 30 endemic adapted to its unique conditions. Climate-driven warming has facilitated teleost expansions into polar regions, with subtropical and temperate species shifting northward in the and southward in the , altering high-latitude assemblages.

Habitat Preferences

Teleosts, comprising over 96% of all living species, demonstrate remarkable adaptability to a variety of habitats, ranging from shallow coastal zones to extreme deep-sea environments and inland freshwater systems worldwide. This versatility allows them to exploit diverse ecological niches, from oxygen-rich currents to low-light abyssal plains, influencing their across biomes. Coral reefs support one of the highest diversities of teleost species, with over 2,000 species recorded in some systems, where families like Pomacentridae (damselfishes) dominate through their abundance and territorial defense of patches that promote coral health. These fishes engage in symbiotic roles, such as grazing on to prevent overgrowth on corals, thereby enhancing and structural complexity. In the open ocean, pelagic teleosts like tunas (family ) prefer the epipelagic zone, where they inhabit mixed-layer waters above the , often associating with seamounts that concentrate prey and elevate local . Deeper pelagic and bathypelagic realms feature teleosts such as lanternfishes (Myctophidae), which employ bioluminescent photophores for , prey attraction, and species recognition in the perpetual below 200 meters. Freshwater teleosts exhibit habitat specialization, with salmonids like favoring fast-flowing and riffles in cold, oxygenated streams that provide cover and foraging opportunities during spawning and rearing. In contrast, many catfishes (Siluriformes), such as bullheads, thrive in stagnant or slow-moving waters with muddy substrates, such as ponds and lowland rivers, where they scavenge in low-oxygen conditions. Many teleost species, including anadromous forms like certain and , undertake seasonal migrations from marine to freshwater habitats for reproduction, linking oceanic and riverine ecosystems. Teleosts play pivotal ecological roles as keystone species in aquatic food webs, facilitating energy transfer from planktonic producers to top predators and maintaining trophic stability through their high biomass and predatory pressures. Additionally, various teleost species serve as bioindicators, accumulating trace elements like mercury to signal pollution levels in both marine and freshwater systems, aiding in the assessment of environmental health.

Physiology

Respiration

Teleosts, the most diverse group of vertebrates, primarily accomplish through highly specialized that facilitate the of oxygen (O₂) and (CO₂) across a thin epithelial barrier. The apparatus consists of four pairs of arches, each bearing numerous primary filaments that branch into secondary lamellae—flat, sheet-like structures that vastly increase the surface area for , generally 0.1–0.4 m² per kg of body mass but up to 1.3 m²/kg in highly active . Water flows over the in a unidirectional path created by the buccal-opercular pump, while circulates through the lamellae in the opposite direction, establishing a system that maintains a steep and achieves up to 90% efficiency in O₂ extraction from . This arrangement ensures that leaving the can become more oxygenated than the incoming , optimizing respiratory performance even in normoxic environments. The process of gas across the epithelium follows Fick's first law of , which describes the J of a gas as proportional to the concentration gradient: J = -D \frac{dC}{dx} where D is the diffusion coefficient of the gas in the , and \frac{dC}{dx} is the concentration difference per unit distance across the lamellar barrier, typically just 0.5–1 μm thick. In teleosts, this gradient is enhanced by the countercurrent flow, preventing equilibration and allowing sustained O₂ uptake and CO₂ elimination. Many teleost species, particularly those in oxygen-poor habitats, have evolved accessory respiratory structures to supplement -based aquatic breathing. In air-breathing teleosts of the suborder , such as the climbing perch (), a labyrinth organ—a highly vascularized, maze-like structure derived from modified elements—enables aerial O₂ uptake by allowing air to be gulped at the surface and diffused across its extensive internal folds. This organ can contribute up to 50–90% of total O₂ needs in severe , reducing reliance on water-breathing and permitting survival in stagnant, low-oxygen waters. Adaptations to hypoxia are prominent in freshwater teleosts inhabiting tropical or seasonally deoxygenated environments, where bimodal respiration—combining aquatic gill ventilation with aerial breathing—allows flexible responses to fluctuating O₂ levels. For instance, species like the armored catfish (Corydoras spp.) or certain catfishes increase air-breathing frequency when dissolved O₂ drops below 2–3 mg/L, partitioning up to 70% of O₂ acquisition to aerial sources while reducing gill ventilation to conserve energy and minimize ion loss. These adjustments are mediated by chemoreceptors detecting environmental and blood O₂ levels, enabling survival in habitats where purely aquatic breathers would suffocate.

Sensory Systems

Teleosts possess a of sensory adaptations optimized for perceiving their environments, enabling detection of prey, predators, mates, and navigational cues in diverse habitats from freshwater streams to deep oceans. These systems include , mechanoreception via the , olfaction, and electrosensation in specialized lineages, each evolved to exploit the physical such as light attenuation, pressure waves, and chemical . Vision in teleosts is highly specialized, with eyes often positioned dorsally or laterally to provide a broad for detecting movement above and around the body. Many species exhibit tetrachromatic , incorporating ultraviolet-sensitive cones alongside red-, green-, and blue-sensitive ones, which enhances discrimination of environmental cues like food or conspecifics in clear waters. In low-light conditions, such as in deep-sea or nocturnal habitats, adaptations include enlarged eyes, a reflective layer behind the to amplify faint light, and rod-dominated retinas for improved sensitivity. Deep-sea teleosts, for instance, often display tubular eyes directed upward to capture bioluminescent signals from above, illustrating evolutionary in visual . The system provides mechanosensory input by detecting water movements and pressure gradients through neuromasts—clusters of hair cells embedded in gelatinous cups—distributed along the body and head canals. This system is crucial for rheotaxis (orientation to currents), schooling synchronization, and predator evasion, as can sense vibrations from conspecifics or prey at distances up to several body lengths in still water. In turbulent flows, canal neuromasts filter noise to detect relevant signals, while superficial neuromasts respond to local flows, allowing fine-tuned spatial awareness. Evolutionary analyses reveal accelerated gene evolution in components among teleosts, supporting diversification in aquatic niches. Olfaction in teleosts relies on paired nasal pits housing olfactory rosettes, folds of rich in receptor neurons that detect , pheromones, and environmental chemicals with high sensitivity, often at concentrations below 10^{-9} . Unlike tetrapods, teleosts lack a , integrating all chemosensory processing through a single that projects to the for behaviors like and . This system is particularly acute in species like , aiding long-distance homing via imprinted odors. Electrosensation occurs in certain teleost lineages, such as mormyrids (elephantfish), which possess electroreceptive organs analogous to the in elasmobranchs but adapted for active electrolocation. These generate weak electric organ discharges and sense distortions in the via tuberous and mormyromast electroreceptors, facilitating prey detection in murky waters and communication through pulse patterns. The exterolateral nucleus processes these signals, enabling species-specific recognition and navigation in low-visibility environments. Hearing in teleosts is enhanced in otophysan groups by the Weberian ossicles, which transmit vibrations from the swimbladder to the , extending sensitivity to higher frequencies up to 10 kHz for detecting distant sounds.

Osmoregulation

Teleosts maintain osmotic balance through coordinated physiological mechanisms that differ markedly between freshwater and marine environments, primarily involving the gills, intestine, and . In freshwater habitats, teleost body fluids are hyperosmotic to the surrounding medium, resulting in passive influx across permeable surfaces and diffusive loss of ions. To counteract this, freshwater teleosts actively uptake ions such as sodium and from the dilute via specialized ocytes (formerly known as chloride cells) in the gills, utilizing basolateral Na+/K+-ATPase and apical ion channels/transporters. The produces copious dilute to eliminate excess , with glomerular rates often exceeding those in teleosts to facilitate water excretion. In marine environments, teleosts are hypoosmotic to seawater, leading to osmotic water loss and passive ion influx. Marine teleosts compensate by drinking large volumes of seawater, absorbing water in the intestine following active uptake of sodium and chloride, and excreting excess monovalent ions (primarily Na+ and Cl-) through specialized seawater-type ionocytes in the gills that feature apical cystic fibrosis transmembrane conductance regulator (CFTR) Cl- channels and basolateral Na+/K+-ATPase for active salt secretion. Divalent ions like Mg2+ and SO4^2- are largely eliminated via minimal urine production by aglomerular or reduced-glomerular kidneys. Euryhaline teleosts, such as Atlantic salmon (Salmo salar), exhibit remarkable plasticity to transition between these environments. During smoltification, juvenile salmon undergo a developmental program triggered by environmental cues like photoperiod and temperature, remodeling gill ionocytes from freshwater-type (focused on ion uptake) to seawater-type (emphasizing ion secretion) and upregulating key transporters like Na+/K+/2Cl- cotransporter (NKCC) and CFTR to enable hypo-osmoregulation in seawater. This process ensures survival during seaward migration, with successful smolts showing increased plasma cortisol and gill Na+/K+-ATPase activity. Hormonal regulation orchestrates these adaptations. Prolactin, secreted by the pituitary, is crucial for freshwater osmoregulation by stimulating ion uptake in gills and reducing gill permeability to ions and water in species like tilapia (Oreochromis mossambicus). In contrast, cortisol, an adrenal steroid, promotes seawater acclimation by enhancing the proliferation and function of ion-secreting chloride cells, increasing Na+/K+-ATPase expression, and supporting overall hypo-osmoregulatory capacity during smoltification in salmonids. Growth hormone (GH) and insulin-like growth factor-1 (IGF-1) synergize with cortisol to amplify these effects, boosting gill transporter activity and overall euryhalinity in migratory teleosts.

Thermoregulation

The vast majority of teleost species are ectothermic, relying primarily on environmental heat sources to regulate their body rather than generating significant internal heat. As poikilotherms, their body closely tracks ambient conditions, influencing physiological processes such as activity and metabolic rates. Behavioral is the dominant strategy among ectothermic teleosts, enabling them to seek out thermally favorable microhabitats to optimize performance and survival. For instance, many exhibit shuttling , moving between warmer surface waters for and activity or cooler deeper layers to avoid overheating, as observed in reef-associated fishes like the bluegill sunfish. Basking near the water surface or selecting sunlit shallows allows solar heat absorption, while vertical migrations in the facilitate access to gradients. These behaviors are guided by sensory cues, including and thermal receptors, allowing precise selection of preferred temperatures that align with optimal ranges for growth and . Physiological thermoregulation in ectothermic teleosts is limited compared to behavioral mechanisms but includes subtle heat conservation and minor endothermic-like adjustments in select species. Some teleosts maintain body temperatures slightly above ambient through vascular arrangements that reduce convective heat loss, as documented in studies of temperate freshwater species. Overall, these physiological traits provide marginal buffering against rapid temperature fluctuations but do not confer true endothermy. A notable exception to widespread ectothermy occurs in certain pelagic teleosts, which have evolved regional endothermy to elevate temperatures in specific tissues for enhanced performance. In scombroid fishes such as tunas (family ) and billfishes like (Xiphias gladius), specialized vascular countercurrent heat exchangers, known as retia mirabilia, conserve metabolic heat generated by slow-twitch red muscle during sustained swimming. These networks of arterial and venous capillaries arranged in parallel minimize heat dissipation to the environment, maintaining muscle temperatures up to 10–20°C above ambient and similarly warming the , eyes, and viscera to improve neural function and in cold deep waters. This , which has arisen convergently in multiple lineages, supports higher cruising speeds and foraging efficiency in open ocean environments. In extreme cold environments, such as the , notothenioid teleosts (suborder Notothenioidei) have developed specialized proteins to prevent internal formation. These glycoproteins (AFGPs), consisting of small peptides linked to chains, evolved approximately 5–15 million years ago from a pancreatic through genomic duplication and divergence. By binding irreversibly to nascent crystals via hydrogen bonding, AFGPs lower the freezing point of bodily fluids without significantly depressing the , creating a thermal that inhibits growth even when freezes. This adaptation allows notothenioids, which dominate fish , to inhabit subzero waters where temperatures often approach -1.9°C, averting lethal in blood and tissues. Temperature profoundly impacts teleost metabolism, with the Q10 temperature coefficient quantifying this sensitivity by measuring the factor by which reaction rates, including metabolic processes, increase with a 10°C rise. In most ectothermic teleosts, Q10 values for standard metabolic rate range from 2 to 3, meaning metabolic rates approximately double or triple per 10°C increase, reflecting the temperature dependence of enzymatic kinetics and oxygen transport. This coefficient varies by species and life stage—for example, Q10 ≈ 2.5 in many temperate marine teleosts—but underscores how warming accelerates energy demands, potentially constraining activity in thermally variable habitats.

Buoyancy Control

Teleosts primarily maintain through the , a gas-filled sac located in the dorsal that adjusts the overall of the to match the surrounding . This , homologous to the lungs of tetrapods, allows teleosts to hover at various depths without constant muscular effort, conserving energy for other activities. In most species, the contains a of gases dominated by oxygen, which provides lift to offset the higher of the 's body tissues compared to . Teleosts exhibit two main types of swim bladders based on their connection to the digestive tract: physostomous and physoclistous. Physostomous swim bladders are open systems with a pneumatic duct linking the bladder to the , enabling to gulp air from the surface to inflate the organ or expel gas for deflation; this type is common in shallow-water like cyprinids. In contrast, physoclistous swim bladders are closed, lacking a direct connection to the gut, and rely on internal physiological mechanisms for gas regulation; this configuration predominates in advanced teleost lineages and supports life in diverse habitats. Gas regulation in physoclistous teleosts occurs via specialized structures in the wall. The gas gland, composed of epithelial cells, secretes primarily oxygen and into the bladder lumen by acidifying the blood supply, which leverages the Root effect in teleost to unload oxygen at low pH. This process is enhanced by the rete mirabile, a dense network of countercurrent capillaries adjacent to the gas gland that multiplies gas partial pressures through repeated diffusion exchanges, concentrating oxygen up to 200 times atmospheric levels to overcome hydrostatic pressure. The rete mirabile's efficiency allows precise control of by modulating blood flow and gas secretion rates. Buoyancy adjustments are particularly critical with depth changes, governed by Boyle's law, which describes the inverse relationship between gas volume and pressure at constant temperature: P_1 V_1 = P_2 V_2 Here, P_1 and V_1 represent initial pressure and volume, while P_2 and V_2 denote values at a new depth; as hydrostatic pressure increases (approximately 1 atm per 10 m), the swim bladder gas compresses, potentially causing the fish to sink unless volume is restored via gas secretion. Deep-sea teleosts adapt to these pressures with reinforced swim bladder walls of thickened, fibrous tissue to resist collapse, enabling habitation at depths exceeding 1,000 m where pressures can surpass 100 atm. Conversely, many bottom-dwelling teleosts, such as Antarctic notothenioids, have secondarily lost the swim bladder entirely, relying instead on reduced skeletal mass or lipid-rich tissues for neutral buoyancy in benthic environments.

Locomotion

Teleosts primarily achieve locomotion through undulatory propulsion, where lateral undulations of the body and tail generate thrust via the interaction of body waves with the surrounding water. These undulations are produced by sequential contractions of myotomal muscles, which are segmented blocks of arranged along the , propagating a traveling wave from head to tail that creates reactive forces for forward movement. The form of undulatory propulsion varies among teleost species, classified along a spectrum from anguilliform to thunniform modes based on the extent of body involvement. In anguilliform swimming, characteristic of elongate species like eels ( spp.), the entire body participates in generating a sinuous wave with high and low frequency, enabling efficient maneuvering in complex environments through widespread myotomal activation. In contrast, thunniform swimming, seen in high-performance teleosts such as tunas ( spp.), confines major undulations to the posterior body and caudal fin, minimizing drag on the rigid anterior body while maximizing thrust from a lunate , which supports sustained high-speed travel. Teleost fins play crucial roles in modulating beyond primary . Median fins, including the , anal, and caudal fins, enhance by functioning as keels that counteract rolling and yawing motions during steady swimming, with the caudal fin also contributing to thrust generation in undulatory modes. Pectoral fins, positioned laterally behind the head, facilitate braking and turning by abducting to increase or asymmetrically to produce , as observed in species like (Oncorhynchus mykiss) where fin protraction during maneuvers generates substantial hydrodynamic forces. Swimming speeds in teleosts range from sustained cruising to burst capabilities adapted to ecological demands. Sustained cruising speeds, aerobically supported for extended periods, typically reach 1-2 body lengths per second (L/s) in active species like tunas, enabling long-distance migrations without fatigue. Burst speeds, powered by white muscle, allow short accelerations up to 100 km/h in predatory billfishes such as marlins ( spp.), facilitating prey capture. Energy efficiency in teleost is optimized through hydrodynamic principles, particularly the (), defined as the ratio of tail-beat amplitude and frequency to forward speed, which governs in the wake. Teleosts achieve high when St falls within 0.2-0.4, as this range promotes coherent vortex formation that minimizes loss and maximizes , a pattern conserved across diverse swimmers from eels to tunas.00709-6)

Sound Production

Teleost fishes produce sounds through a variety of mechanisms, primarily to facilitate acoustic communication for , territorial , and social interactions. The most common method involves fast-contracting sonic muscles attached to the , which vibrate this gas-filled organ to generate low-frequency pulses or tones. In the family (drums and croakers), these sonic muscles enable "drumming" sounds by rapidly contracting against the swim bladder walls, producing characteristic knocks, grunts, or purrs used in courtship choruses. Another prevalent mechanism is , where fish rub or strike rigid skeletal structures such as rays, teeth, or the pectoral girdle against one another to create clicks or scrapes. These mechanisms allow teleosts to produce sounds without , adapting to underwater propagation where low frequencies travel efficiently. Sound frequencies in teleosts typically range from 20 to 1000 Hz, with dominant frequencies often between 50 and 500 Hz to match the hearing sensitivities of conspecifics and minimize in water. These calls serve specific behavioral roles: for instance, tonal boatwhistles in toadfishes (Opsanus spp.) function as advertisement calls to attract females during breeding seasons, consisting of amplitude-modulated pulses at around 100-400 Hz. In damselfishes (Pomacentridae), short grunt-like pulses (often 200-800 Hz) are emitted during aggressive territorial disputes or chases, produced via of the pectoral girdle. Sciaenids, such as the (Sciaenops ocellatus), generate low-frequency drums (below 500 Hz) in nocturnal choruses to synchronize spawning aggregations. These frequencies are evolutionarily tuned for effective communication over short to moderate distances in diverse habitats. Teleost hearing, essential for detecting these conspecific signals, relies on the inner ear's sensory epithelia, with enhanced in otophysan lineages (e.g., carps, catfishes) by the —a chain of modified vertebrae that transmits vibrations directly to the ear, extending detectable frequencies up to 1000-5000 Hz in some species. This adaptation supports reciprocal acoustic communication, where produced sounds elicit responses in receivers. Overall, sound production underscores the behavioral complexity of teleosts, enabling species-specific interactions in noisy aquatic environments.

Reproduction and Life Cycle

Sex Determination

Sex determination in teleosts is highly diverse, encompassing genetic sex determination (GSD), (ESD), and hybrid systems where both factors interact to influence gonadal differentiation. Unlike the conserved system in mammals, teleost sex determination exhibits frequent evolutionary turnovers, with over 30 independent origins of sex chromosomes identified across the . This plasticity allows for adaptation to varying ecological pressures, but primary mechanisms are established early in embryonic development, typically within the first few weeks post-fertilization. In GSD, sex is fixed at fertilization by chromosomal or genic differences, with male heterogamety ( males, XX females) being the most common pattern. A seminal example is the medaka fish (Oryzias latipes), where the Y-linked DMY (a teleost-specific duplicate of dmrt1, also called dmrt1bY) serves as the primary sex-determining factor, triggering testis formation by expressing a DM-domain exclusively in male gonads from early embryogenesis. Loss-of-function mutations in DMY cause XY individuals to develop as s, confirming its master regulatory role. Other GSD variants include ZW systems (female heterogamety) in species like the platyfish (Xiphophorus maculatus), where a Y-linked homolog of sdY (from salmonid lineages) has been implicated. ESD, in contrast, decouples from , with environmental cues like modulating the trajectory of undifferentiated gonads toward or female fates. (TSD) is documented in approximately 20 teleost species, often as a low-frequency or hybrid mechanism overlaid on GSD. For instance, in the pejerrey (Odontesthes bonariensis), exposure to high (above 27°C) during the thermosensitive period promotes development by upregulating male-promoting genes like dmrt1 and suppressing synthesis, while cooler (below 18°C) favor ovarian differentiation. This system can produce highly skewed ratios under scenarios, as seen in wild populations where warming waters increase proportions. pH and also influence ESD in some cases, such as in the swordtail (Xiphophorus helleri) for pH, but remains the dominant cue. Polygenic sex determination systems, involving multiple minor-effect loci rather than a single dominant , are prevalent in several teleost lineages and provide a buffer against environmental perturbations. In the European sea bass ( labrax), genome-wide association studies have identified at least four sex-influencing quantitative trait loci (QTLs) on different chromosomes, collectively accounting for over 90% of variation and interacting with to shift sex ratios. Similarly, in (Danio rerio), polygenic control involves multiple QTLs across chromosomes, with no single locus dominating, allowing for gradual sex allocation based on genetic background. These systems contrast with monogenic GSD by enabling finer-tuned responses to selection pressures. Recent genomic studies have identified amh/amhr2 homologs as predominant recurrent sex-determining genes in many teleost species, contributing to the observed evolutionary lability. At the genomic level, the dmrt1 gene functions as a conserved downstream master regulator of male fate in most teleosts, regardless of upstream GSD or ESD triggers. Expressed in precursors, dmrt1 promotes testis differentiation by activating pro-male pathways and repressing ovarian genes like foxl2; its knockout in species such as the (Oreochromis niloticus) induces complete male-to-female sex reversal. In ESD contexts, temperature modulates dmrt1 expression levels to direct sex outcomes. in some teleosts builds on this flexibility, with transitions often triggered by attaining a critical size or age threshold, as in protogynous species where larger individuals shift to female to maximize . Hermaphroditic variants, such as those in , briefly illustrate how environmental and can override initial sex determination.

Hermaphroditism

Hermaphroditism in teleost fishes encompasses reproductive strategies where individuals possess both reproductive organs, either simultaneously or sequentially, allowing for functional dual sexuality. This condition is documented in approximately 2% of extant teleost species, distributed across more than 20 families and 9 orders, providing evolutionary advantages in certain ecological contexts. Teleosts exhibit two primary forms of hermaphroditism: simultaneous and sequential. In simultaneous hermaphroditism, individuals produce both eggs and sperm concurrently within the same gonad, though self-fertilization is rare and outcrossing is typical; notable examples include species in the genus Serranus (such as the barred hamlet S. psittacinus), where paired individuals alternate roles during spawning to fertilize each other's gametes. Sequential hermaphroditism involves a change in functional sex over the lifespan, either protandrous (male to female) or protogynous (female to male). Protandrous species, like clownfishes in the family Pomacentridae (e.g., Amphiprion ocellaris), begin as males and transition to females upon the death of the dominant female in a social group. Protogynous hermaphroditism is more common, seen in wrasses (family Labridae, e.g., bluehead wrasse Thalassoma bifasciatum) and groupers (family Serranidae, e.g., red grouper Epinephelus morio), where females change to males as they grow larger, often triggered by social cues like the removal of the dominant male. The advantages of hermaphroditism in teleosts include enhanced reproductive flexibility, particularly in sparse or low-density populations where locating opposite-sex partners is challenging; this strategy ensures higher mating success and reproductive assurance by allowing individuals to adopt either as needed. Endocrine mechanisms underpin these transitions, primarily through the enzyme (encoded by cyp19a1 genes), which catalyzes the conversion of androgens like testosterone to estrogens; elevated aromatase activity promotes ovarian development and female function, while its inhibition can trigger gonadal reorganization and in sequential hermaphrodites. Recent studies from the indicate that climate-induced increases may disrupt hermaphroditism rates in teleosts by altering sex synthesis and timing of sex changes, potentially favoring protogynous patterns in warming tropical habitats while impairing reproductive output in thermo-sensitive species. For instance, elevated temperatures have been shown to suppress self-fertility in simultaneous hermaphrodites like Kryptolebias marmoratus and influence for in sequential forms.

Mating and Spawning

Teleosts display a wide array of tactics, reflecting adaptations to diverse ecological niches. Promiscuous systems are prevalent, where individuals mate with multiple partners without long-term bonds, often facilitating high reproductive output in with . For instance, in the Cyrtocara eucinostomus, males and females aggregate in spawning arenas, allowing opportunistic pairings without pair formation. In contrast, pair-bonding occurs in monogamous , where partners form stable associations that may last multiple seasons and involve coordinated displays such as parallel swimming and mutual territory defense. The Amatitlania siquia exemplifies this, with pairs exhibiting affiliative behaviors like greeting and circling to reinforce bonds during . Lekking systems, where males gather in display arenas to attract females without providing resources, are notable in certain ; territorial males in Tropheus duboisi from court females through visual and acoustic displays in communal leks, with dominant males securing most matings. Spawning in teleosts typically involves , where females release eggs and males ejaculate into the surrounding water, maximizing encounter rates in aquatic environments. This ancestral condition predominates across the group, enabling rapid dispersal but increasing vulnerability to predation and dilution. Broadcast spawning, common in pelagic species, entails mass release of gametes into open water without attachment, as seen in many fishes where synchronized group spawning enhances fertilization success amid currents. Alternatively, substrate spawners often construct nests to protect eggs; male three-spined sticklebacks (Gasterosteus aculeatus) build tubular nests from plant material glued with a specialized protein , into which females deposit eggs for targeted fertilization. Clutch sizes in teleosts vary dramatically, from tens of eggs in nest-building to millions in broadcast , correlating with egg size, , and environmental risks. Small-clutch like the Cyrtocara eucinostomus produce around 35 eggs per , allowing for potential , while large pelagic spawners such as the king (Scomberomorus cavalla) release over 6 million eggs to compensate for high mortality. The California grunion (Leuresthes tenuis), a beach-spawning silverside, exemplifies intermediate sizes, with females laying 1,600 to 3,600 eggs per event directly onto sandy shores during high . Many teleost synchronize spawning with environmental cues to optimize survival and dispersal. Lunar and cycles serve as key zeitgebers, particularly in inhabitants; for example, the grass pufferfish (Takifugu niphobles) spawns semilunarly during high spring tides influenced by the moon, exposing intertidal nests briefly for oxygenation. In reef settings, like the honeycomb grouper (Epinephelus merra) time mass spawnings around the , using to trigger gonadal maturation and release, which aligns with optimal larval via currents. This periodicity reduces predation risk and enhances offspring retention on reefs.

Parental Care and Development

Teleost fishes exhibit a wide range of parental care strategies following spawning, with many species providing no care at all by releasing buoyant pelagic eggs into the open water column, where they develop independently and are subject to high environmental risks. In contrast, approximately 30% of teleost families demonstrate some form of parental investment, often involving a single parent, with male care being the most prevalent (over 50% of caring species). Notable examples include maternal mouthbrooding in cichlids, where females retain fertilized eggs and early larvae in their buccal cavity for protection and oxygenation until the young are free-swimming, a behavior that enhances offspring survival in predator-rich freshwater habitats. Similarly, male nest guarding occurs in species like the threespine stickleback, where fathers construct and defend nests, fan eggs to improve oxygen flow, and remove debris, thereby reducing fungal infections and predation. Embryonic development in teleosts typically begins with , leading to telolecithal eggs rich in that incubate for 1-2 weeks, depending on , , and oxygen levels, before . Upon , larvae emerge as yolk-sac dependents, relying on the internalized reserve for initial nourishment over several days until it is fully absorbed, marking the transition to exogenous feeding. This larval phase involves rapid morphological changes, including development and sensory organ maturation, culminating in to the juvenile stage, where body form aligns more closely with the adult morphology and . Growth rates during post-larval vary widely across teleost , influenced by environmental factors, , and , but can be exceptionally rapid in anadromous forms like . For instance, juvenile may progress from approximately 1 g to 100 g in just a few months under optimal conditions in settings, reflecting their for quick growth phases. Despite these potentials, early life stages suffer extraordinarily high mortality, often exceeding 90% due to predation, , and abiotic stressors, which shapes and success. This vulnerability underscores the selective pressures driving diverse strategies in teleosts.

Behavior

Shoaling and Schooling

Teleosts exhibit two primary forms of social grouping: . refers to loose aggregations of fish that remain in proximity without synchronized movement, often for mutual or resource access. In contrast, involves highly coordinated, polarized where individuals align and move in the same direction, maintaining consistent spacing and orientation. These behaviors are widespread among teleost , particularly in open-water or high-predation environments. The primary benefits of include enhanced protection from predators through the dilution , where the risk to any individual decreases as group size increases, and the confusion , which impairs a predator's ability to single out and target prey amid the coordinated movements of the group. Foraging efficiency also improves in groups, as individuals can benefit from shared vigilance, allowing more time for feeding while reducing individual search efforts. These advantages are particularly evident in pelagic teleosts, where grouping behaviors have evolved to counter constant predation pressure. At the neural level, schooling is facilitated by the optomotor response, a visual reflex that causes to align with the perceived motion of nearby conspecifics, promoting group cohesion. Synchronization is further supported by the system, which detects hydrodynamic pressure waves from neighboring , enabling precise adjustments in position and speed to maintain formation. These sensory mechanisms integrate visual and mechanosensory cues to sustain polarized swimming without direct contact. A prominent example is the massive schools formed by sardines (Sardinops sagax), which can number up to 10 million individuals and span kilometers in extent. In such formations, the confusion effect significantly reduces predator attack success; computational models of predator-prey interactions demonstrate that coordinated maneuvers can halve the probability of successful strikes compared to attacks on solitary or small groups. This collective defense underscores the adaptive value of schooling in teleost survival strategies.

Foraging and Feeding

Teleosts exhibit a wide array of strategies adapted to diverse environments, ranging from freshwater to , enabling them to exploit various food resources efficiently. Their feeding behaviors are influenced by morphological specializations that facilitate prey capture and processing, allowing occupation of multiple trophic levels within ecosystems. Teleosts occupy several trophic levels, including planktivory, piscivory, and herbivory. Planktivores, such as many clupeids, employ filtering mechanisms to capture small by generating through rapid protrusion and branchial pumping, often using rakers to strain prey from water. Piscivores, exemplified by species like the , utilize feeding—where the fish lunges toward prey—or feeding, creating a in the buccal to draw in smaller fish. Herbivores, such as parrotfishes in the family Scaridae, scrape from substrates using fused dental plates on their , followed by processing in the . Key adaptations enhance feeding efficiency across these groups. , located on the fifth , enable grinding of tough plant material or crushing of shells in herbivores and omnivores; for instance, in parrotfishes, these molar-like structures form a mill that breaks down ingested and . In certain lineages, such as the gymnotiform electric eels, modified electrocytes in electric organs generate high-voltage discharges up to 860 volts to stun prey like small fish or before consumption. morphology, including protrusible upper , supports these strategies by allowing precise prey interception. Many teleosts follow daily foraging patterns tied to prey availability. Diel vertical migrations are common among mesopelagic species like lanternfishes (family Myctophidae), which ascend to surface waters at night to feed on concentrated in the epipelagic zone, then descend during the day to avoid predators while digesting. Recent (eDNA) studies have uncovered diverse diets in deep-sea teleosts. Metabarcoding analyses of gut contents from mesopelagic teleosts, such as those in orders and Myctophiformes, have identified dominant prey including calanoid copepods and halocyprid ostracods, revealing greater dietary diversity than previously suggested by visual surveys.

Migration Patterns

Teleosts exhibit diverse migration patterns that reflect adaptations to their aquatic environments, enabling them to exploit varying resources across seasons and life stages. These movements range from extensive oceanic traversals to targeted freshwater incursions, often spanning thousands of kilometers. Such patterns are crucial for survival, growth, and reproduction, with species like and eels serving as paradigmatic examples of these behaviors. Anadromous migration involves teleosts such as (family ) that spend most of their adult lives in the before returning to freshwater to . This pattern allows oceanic juveniles to grow rapidly in nutrient-rich marine waters before navigating upstream as adults, sometimes against strong currents, to reach natal spawning grounds. In contrast, catadromous migration is exemplified by anguillid eels, which mature in freshwater or coastal habitats and migrate to distant spawning areas, such as the for the (Anguilla rostrata), before their larvae drift back to continental waters. Oceanodromous migrations occur entirely within marine environments, as seen in (Thunnus thynnus), which undertake transoceanic circuits between feeding grounds in temperate waters and spawning sites in subtropical regions, covering up to 10,000 km annually to follow prey and temperature gradients. Navigation during these migrations relies on a suite of sensory mechanisms, including sensitivity to for , olfactory cues from environmental chemicals to detect home streams, and celestial cues like 's position for directional guidance. Teleosts detect geomagnetic variations through specialized cells containing crystals, enabling long-distance homing with high fidelity, as demonstrated in studies of using conditioned magnetic imprints. Olfactory navigation allows returning adults to recognize specific river scents from thousands of kilometers away, while polarized light from aids in maintaining headings during open-ocean travel. These sensory aids integrate to form a compass system, though the exact neural integration remains under investigation.00844-0) Ecologically, teleost migrations play pivotal roles in nutrient cycling and connectivity. For instance, anadromous transport marine-derived nutrients inland upon death after spawning, with their carcasses fertilizing riparian forests and supporting terrestrial food webs; in rivers, this input can constitute up to 25% of the nitrogen in streamside , enhancing . Oceanodromous species like link distant marine provinces by redistributing energy through their , influencing predator-prey dynamics across ocean basins. These movements thus subsidize both and terrestrial habitats, underscoring the broad trophic impacts of teleost migrations.085[1217:MDNOMI]2.0.CO;2) Human-induced threats significantly disrupt these patterns, particularly dams that block migratory routes and fragment habitats. Hydroelectric and irrigation dams on rivers like the Columbia impede anadromous salmon, reducing populations by up to 90% in some basins through prevented access to spawning grounds and increased mortality during passages. Similar barriers affect catadromous eels in coastal rivers, exacerbating declines from overfishing and habitat loss. Mitigation efforts, such as fish ladders and trap-and-haul systems, have variable success, highlighting the need for restored connectivity to sustain teleost migrations.

Relationship with Humans

Economic Importance

Teleosts form the backbone of global capture fisheries, which produced approximately 92.3 million tonnes in 2022, accounting for the majority of the world's wild-caught fish supply. Key species driving this production include Peruvian anchoveta (Engraulis ringens), Atlantic herring (Clupea harengus), and Atlantic cod (Gadus morhua), which are harvested in vast quantities for human consumption, fishmeal, and oil. These fisheries support coastal communities and international trade, with teleosts comprising over 90 percent of total marine capture landings. In aquaculture, teleosts dominate production, with major species such as (Cyprinus carpio), (Oreochromis niloticus), and (Salmo salar) leading global output. In 2022, aquaculture yielded 130.9 million tonnes overall, surpassing capture fisheries and representing more than 50 percent of total production, a trend projected to continue through 2025 and beyond. This sector has expanded rapidly, particularly in and , providing a stable supply of protein-rich food amid fluctuating wild stocks. The combined fisheries and aquaculture industries generate substantial economic value; in 2022, the total first sale value was estimated at USD 452 billion, of which USD 296 billion came from aquaculture. These activities sustain approximately 62 million direct jobs in primary production worldwide, while broader supply chains and processing support livelihoods for hundreds of millions more, particularly in developing regions. Post-2020, innovations in plant-based feeds, such as soy and canola derivatives, have accelerated, reducing reliance on wild-caught fish for aquafeed and lowering the fish-in-fish-out ratio to below 1 in many operations. This shift enhances sustainability and cost-efficiency in teleost farming.

Conservation and Threats

Teleost fishes face significant threats from activities, with being a primary driver of population declines across many . Overexploitation through commercial and artisanal fisheries has led to the depletion of stocks, particularly for long-lived that reproduce slowly, making recovery challenging. Habitat loss, exacerbated by dam construction in freshwater systems, coastal development, and from agricultural runoff and industrial effluents, further fragments ecosystems essential for teleost and . Climate change compounds these pressures, as ocean warming prompts range shifts toward poles and higher latitudes, disrupting established distributions and increasing vulnerability to extreme events like marine heatwaves. Recent assessments indicate that approximately 12.7% of teleost are at risk of , a figure five times higher than previous IUCN estimates of 2.5%, highlighting underassessed threats in data-poor regions. Vulnerable groups include deep-sea like the (Hoplostethus atlanticus), which exhibits extremely slow growth rates—reaching maturity at around 20–30 years—and low fecundity, rendering it highly susceptible to with prolonged recovery times exceeding decades. Tropical and subtropical teleosts are particularly imperiled, with hotspots of predicted risk in regions like the , , and west coast of . Conservation efforts for teleosts emphasize sustainable management and habitat protection to mitigate these risks. Marine Protected Areas (MPAs) have proven effective in replenishing local populations by restricting fishing and preserving biodiversity hotspots, with spillover effects benefiting adjacent fisheries. Catch quotas and size limits, enforced through international agreements and national policies, aim to prevent , while restocking programs release hatchery-reared juveniles to bolster depleted stocks in targeted rivers and coastal zones. Notable attempts include recovery initiatives for (Gadus morhua), where strict quotas and seasonal closures in regions like the have led to partial rebounds, though full restoration remains elusive due to ongoing climate stressors; a 2022 management plan targets rebuilding U.S. stocks by 2033 with a 70% probability of success. These strategies underscore the need for integrated approaches combining enforcement, monitoring, and adaptation to climate impacts for long-term teleost viability.

Cultural and Scientific Significance

Teleosts have featured prominently in human culture and mythology across civilizations. The zodiac sign Pisces, depicted as two fish swimming in opposite directions and connected by a cord, symbolizes duality, intuition, and emotional depth in Western astrology, with roots in ancient Mesopotamian and Babylonian traditions where fish represented fertility and the divine. In Japanese culture, koi fish—a selectively bred variety of common carp (Cyprinus carpio), a teleost—embody perseverance, strength, and good fortune, inspired by legends of koi transforming into dragons after ascending waterfalls, and are central to art, festivals, and garden designs as emblems of love and friendship. The practice of aquaculture in ancient China, dating back to approximately 2500 BCE, involved pond-based rearing of common carp alongside crops like rice, marking one of the earliest forms of integrated fish farming and influencing global food systems. The aquarium hobby, which emerged from centuries of selective breeding of goldfish (Carassius auratus)—a teleost domesticated in China during the Tang Dynasty (618–907 CE) for their vibrant colors and ornamental appeal—has made teleosts enduring symbols of domestic tranquility and aesthetic pleasure worldwide. Goldfish, originally prized by imperial courts and later exported to Japan and Europe, represent the intersection of art and biology, with breeding techniques yielding diverse varieties that continue to captivate hobbyists. In scientific research, teleosts serve as vital model organisms, with the (Danio rerio) revolutionizing due to its rapid development, transparent embryos, and 70–84% genetic homology with humans, enabling breakthroughs in transgenics and . Similarly, the medaka fish (Oryzias latipes) is a cornerstone in , used to evaluate the impacts of pollutants like endocrine disruptors on and development owing to its short generation time and sensitivity to environmental stressors. Biomedically, teleosts contributed to early insulin production; in the , researchers extracted insulin from fish pancreases, such as those of and , providing a scalable source before mammalian extracts dominated treatment. Beyond research, teleosts are cherished as pets, with species like guppies (Poecilia reticulata) and bettas (Betta splendens) offering interactive companionship in home aquariums due to their vibrant displays and adaptability. Sport fishing also highlights their recreational value, targeting teleosts such as (Salmo trutta) and (Micropterus spp.) for their fighting spirit and accessibility in freshwater systems. Teleosts underpin aquatic , comprising approximately 96% of all living fish species and half of diversity, which underscores their ecological and evolutionary importance.

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