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Osmeriformes
Temporal range: Late Paleocene–present
Delta smelt, Hypomesus transpacificus
(Osmeroidei: Osmeridae)
Scientific classification Edit this classification
Kingdom: Animalia
Phylum: Chordata
Class: Actinopterygii
Superorder: Osmeromorpha
Order: Osmeriformes
Regan, 1913[1]
Type species
Salmo eperlanus
Families

The Osmeriformes /ɒsˈmɛrɪfɔːrmz/ are an order of ray-finned fish that includes the true or freshwater smelts and allies, such as the noodlefishes; they are also collectively called osmeriforms. They belong to the teleost superorder Protacanthopterygii, which also includes pike and salmon, among others.[2] The order's name means "smelt-shaped", from Osmerus (the type genus) + the standard fish order suffix "-formes". It ultimately derives from Ancient Greek osmé (ὀσμή, "pungent smell") + Latin forma ("external form"), the former in reference to the characteristic aroma of the flesh of Osmerus.[3][4][5]

In the classification used here, the order Osmeriformes contains two suborders, four families, some 17 genera, and about 52 species.[6] The "marine" smelts and allies (e.g. the odd-looking barreleyes) were formerly included here as suborder Argentinoidei; they are now usually considered more distantly related than it was believed and treated as order Argentiniformes. When the marine smelts were included here, the subdivisions of the Osmeriformes were down-ranked by one.[7] The galaxiids were also previously placed in this order, being treated as allied with the retropinnids, but are now known to represent their own, distinct order.[8]

Description and ecology

[edit]
Noodlefish (Salangidae) are unusual osmeriforms that are commonly harvested

Osmeriformes are small to mid-sized slender fish. Their maxilla is usually included in the mouth's gape, and most of them have an adipose fin as is often found in the Protacanthopterygii. Their [pterosphenoid] usually has a ventral flange, and the vomer has a short posterior shaft. They have reduced or even missing articular and mesopterygoid teeth, and the basisphenoid and orbitosphenoid bones are entirely absent. Their scales lack radii.[7]

Despite the term "freshwater smelts", the members of the Osmeriformes are generally marine, amphidromous or anadromous migrants. Even the sedentary freshwater species in this family are usually tolerant of considerable changes in salinity. Almost all osmeriforms spawn in fresh water, thus the marine species are generally anadromous. They are found in temperate oceans worldwide and in temperate freshwater of the Holarctic and around the South Pacific region; only a handful of species occur in tropical waters. The eggs are surrounded by an adhesive membrane.[7]

Systematics

[edit]
New Zealand smelt (Retropinna retropinna), one of the few species in the Retropinnidae

With the Argentiniformes, Alepocephaliformes, Galaxiiformes, and Lepidogalaxiiformes separated as distinct orders, the remaining Osmeriformes appear to be a monophyletic group. As protacanthopterygians, they are known to be related to the Salmoniformes (pikes and salmon). However, more recent studies incorporating anatomical and DNA sequence data suggest that their closest relatives are the deep-sea Stomiiformes.[9][10][11]

The classification of the Osmeriformes as approached here is:[6][10][12]

The Late Cretaceous-aged Spaniodon potentially represents an early osmeriform[9]

A possible fossil osmeriform is Spaniodon, a piscivore from Late Cretaceous seas.[9] The group originated probably somewhat earlier, but a Cretaceous age maybe about 110 million years ago or so is likely.[5][7] The oldest definite osmeriform is Speirsaenigma from the Paleocene of Alberta, Canada, which was a relative of the modern ayu fish and appears to have been a freshwater species.[14][15] In 2025, a new, extinct family of freshwater Southern Hemisphere smelt, the Ferruaspidae, was identified from the Miocene-aged McGraths Flat fossil site of Australia.[13]

The families Galaxiidae and Lepidogalaxiidae were at one time placed together with Retropinnidae in the sub order Galaxoidei, however with new molecular studies they have been elevated to the ordinal level.[12]

Timeline of genera

[edit]
QuaternaryNeogenePaleogeneCretaceousHolocenePleistocenePlioceneMioceneOligoceneEocenePaleoceneLate CretaceousEarly CretaceousAllosmerusMallotusMaulisiaSpirinchusNanseniaBathylagusHypomesusCarpathichthysEnoplophthalmusOphisthoproctusProargentinaArgentinaOsmerusNybelinoidesQuaternaryNeogenePaleogeneCretaceousHolocenePleistocenePlioceneMioceneOligoceneEocenePaleoceneLate CretaceousEarly Cretaceous

References

[edit]

Further reading

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Osmeriformes

View on Grokipedia
from Grokipedia
Osmeriformes is an order of ray-finned fishes within the superorder Protacanthopterygii, consisting of four families—Osmeridae (smelts), Plecoglossidae (ayu fishes), Retropinnidae ( smelts), and (icefishes or noodlefishes)—encompassing approximately 40 of small to medium-sized, elongate, and often silvery fishes that primarily inhabit marine, brackish, and freshwater environments. These fishes are characterized by features such as a typically included within the gape of the mouth (with exceptions in some retropinnids), the presence or absence of an adipose fin, cycloid scales lacking radii, and the loss of certain cranial bones like the basisphenoid and orbitosphenoid. Members of Osmeriformes are predominantly water-column dwellers, with many species exhibiting anadromous life histories, spawning in freshwater while spending most of their adult lives in marine or brackish waters. The order is distributed mainly in the Northern Hemisphere's temperate and boreal regions for osmerids and salangids, extending to coastal Pacific and Atlantic waters, while retropinnids are confined to freshwater and coastal systems in and southeastern . Commercially significant species include the (Mallotus villosus) and (Thaleichthys pacificus) from the Osmeridae, valued as , and the ayu (Plecoglossus altivelis) from the Plecoglossidae, a culturally important in . Osmeriformes play key ecological roles as prey for larger predatory fishes, birds, and marine mammals, and their populations have faced pressures from overfishing, habitat alteration, and climate change in some regions. Recent phylogenetic studies support the monophyly of this order, distinguishing it from related groups like Galaxiiformes, which includes galaxiids and was previously allied but now recognized separately based on molecular and morphological evidence. The fossil record of Osmeriformes dates back to the Cretaceous, highlighting their ancient lineage within teleost fishes.

Taxonomy and Systematics

Current Classification

Osmeriformes is recognized as an order of () within the superorder Protacanthopterygii, a basal group of euteleostean fishes characterized by primitive traits such as the presence of an adipose fin in many members. The order encompasses small to moderate-sized, elongate, silvery fishes primarily inhabiting freshwater, brackish, and coastal marine environments in the Northern and Southern Hemispheres. In contemporary classifications, Osmeriformes includes two suborders, four families, 17 genera, and 42 species, reflecting post-2017 phylogenetic revisions that emphasize molecular data over traditional morphology. The suborder Osmeroidei contains three families: Osmeridae (Northern Hemisphere smelts; 6 genera, 15 species, e.g., the rainbow smelt Osmerus mordax), Plecoglossidae (ayu fishes; 1 genus, 1 species, Plecoglossus altivelis), and Salangidae (icefishes or noodlefishes; 7 genera, 19 species). The suborder Retropinnoidei includes the single family Retropinnidae (New Zealand smelts or southern smelts; 3 genera, 6 species, e.g., Retropinna retropinna). These groupings are supported by high bootstrap values (100%) in molecular phylogenies, resolving Osmeriformes as a monophyletic clade distinct from formerly associated lineages. Key diagnostic traits of Osmeriformes include the being included within the gape of the mouth and an that is either present or absent, features shared with other protacanthopterygians but variably expressed across the order. Scales are typically and , while internal cranial features, such as the absence of the basisphenoid and orbitosphenoid bones, further delineate the group from related orders. Recent taxonomic updates, particularly from 2017 onward, have separated , Galaxiiformes, and Lepidogalaxiiformes as independent orders based on genomic and morphological evidence, narrowing Osmeriformes to its current composition and resolving prior . These revisions, adopted in authoritative catalogs, underscore the order's position as a compact within Protacanthopterygii.

Phylogenetic Position and Relationships

Osmeriformes is recognized as a monophyletic order within the Euteleostei clade of ray-finned fishes (Actinopterygii), specifically as part of the larger Clupeocephala group, which encompasses the majority of teleost diversity. This narrow definition of Osmeriformes, comprising families such as Osmeridae, Plecoglossidae, Retropinnidae, and Salangidae, emerged from molecular phylogenetic analyses that resolved its boundaries by excluding previously included groups like Argentiniformes and Galaxiiformes. Historically, prior to 2017, broader classifications encompassed these taxa under Osmeriformes or related "Osmeromorpha," but post-2020 phylogenomic studies demonstrated paraphyly in such arrangements, leading to the elevation of Argentiniformes and Galaxiiformes as distinct orders based on incongruent molecular data. The monophyly of modern Osmeriformes is supported by shared morphological traits, including the presence of an adipose fin in approximately 70% of species and the loss of certain cranial bones such as the posttemporal and supratemporal, which align with molecular evidence from multi-locus datasets. Within Euteleostei, Osmeriformes forms the subcohort Stomiati alongside (dragonfishes and allies), with the two orders consistently resolved as sister groups in phylogenomic reconstructions using genome-wide data from hundreds of loci. This relationship is bolstered by morphological synapomorphies, notably the crumenal organ—a complex posterior branchial structure involved in prey retention and digestion—present in both Osmeriformes and basal , providing evidence for their close evolutionary ties despite limited fossil corroboration. Earlier hypotheses positioned Osmeriformes as sister to Esociformes (pikes and mudminnows) within a monophyletic Protacanthopterygii, based on shared protacanthopterygian features like the adipose fin and certain myological patterns; however, recent analyses (2020–2025) have rejected Protacanthopterygii's , placing it as a grade rather than a and relocating Osmeriformes basal to other euteleosts like Salmoniformes and Esociformes. Genome-wide studies from 2025 further stabilize Osmeriformes as a basal euteleost lineage, with some trees showing transient affinities to subclades, though overall resolution emphasizes Stomiati's integrity. These controversies highlight ongoing refinements in Osmeriformes systematics, driven by increasing genomic sampling that challenges pre-2020 morphological classifications while affirming its position as a distinct, monophyletic basal euteleost group.

Morphology and Description

External Features

Members of the order Osmeriformes exhibit a body form that is small to moderate in size, generally reaching up to 60 cm in length, though most species are smaller, with Osmeridae attaining up to 40 cm and Salangidae typically less than 10 cm. The body is slender and elongate, with moderate lateral compression, facilitating movement through pelagic or lotic environments. Scales are small, cycloid, and deciduous, often lacking distinct radii and contributing to a characteristic silvery iridescence in families such as Osmeridae, Plecoglossidae, and Retropinnidae; however, Salangidae are scaleless or nearly so. The fin configuration is distinctive, featuring a single positioned posteriorly near the midline of the body, an anal fin located opposite or slightly behind the , and abdominal pelvic fins inserted under or anterior to the . Pectoral fins are low on the body flanks, while the caudal fin is deeply forked. An adipose fin is present in most families, including Osmeridae, Retropinnidae, and Plecoglossidae, but absent in Salangidae, where pelvic fin rays number 6-8. The head is small to moderate, with a terminal in which the maxilla is included within the gape, though some Retropinnidae show an inferior orientation as an exception. Teeth are small and present on the jaws and sometimes other bones, with the snout pointed in Osmeridae. Eyes are moderately large, aiding in low-light conditions. Coloration across Osmeriformes is predominantly silvery overall, enhancing within the , with many species displaying iridescent hues on the sides. For instance, the rainbow smelt Osmerus mordax (Osmeridae) has a pale green dorsal surface, iridescent purple, blue, or pink lateral sides, and a white ventral surface, often with some dark dorsal pigmentation. Salangidae are translucent or transparent with a pearly white tint.

Internal Anatomy

The internal anatomy of Osmeriformes is characterized by several distinctive features in the skeletal, muscular, and organ systems that support their primarily pelagic and migratory lifestyles. The and jaws exhibit reduced , with small or absent teeth on the , , articular, and mesopterygoid bones, reflecting adaptations for filter-feeding or consuming small planktonic prey rather than grasping larger items. Notably, the basisphenoid and orbitosphenoid bones are entirely absent, a synapomorphy that distinguishes this order from many other teleosts and contributes to a lighter cranial structure suited for streamlined movement. A unique feature is the crumenal organ, a complex posterior branchial structure derived from the arches, which functions in fat storage and processing, aiding energy reserves during long migrations. The in Osmeriformes is typically physostomous, featuring an open pneumatic duct connecting it to the , which allows for rapid adjustment of gas volume to maintain during transitions between marine and freshwater environments. This open configuration is particularly advantageous for anadromous , enabling efficient regulation of hydrostatic changes encountered in rivers and coastal waters. Sensory systems are well-adapted for social and navigational behaviors; the system is prominently developed along the body, consisting of neuromasts that detect water movements and vibrations, facilitating coordinated schooling in open water where visual cues may be limited. In anadromous taxa, such as certain smelts in the family Osmeridae, olfactory organs are enhanced, with expanded rosettes containing numerous lamellae that improve detection of chemical cues for homing to spawning grounds. Musculature in Osmeriformes supports their elongate body form through segmented myomeres, blocks of arranged in a pattern that enable undulatory for sustained against currents. These myomeres include a layer of slow-twitch muscle fibers laterally, which provide for prolonged migrations without . A notable variation occurs in the family Plecoglossidae, where species like the ayu (Plecoglossus altivelis) possess specialized comb-like on the lower arches, adapted for scraping and grinding attached from substrates, complementing their primarily herbivorous diet in freshwater habitats.

Distribution, Habitat, and Ecology

Geographic Distribution

The order Osmeriformes exhibits a predominantly temperate distribution, with the majority of its approximately 50 occurring in the across marine, freshwater, and brackish habitats. The family Osmeridae, comprising northern smelts, is primarily Holarctic, ranging through the temperate waters of the North Atlantic and North Pacific Oceans, including coastal and inland systems from to and . In contrast, the families (icefishes or noodlefishes) and Plecoglossidae (ayu fishes) are confined to the region, extending from and Korea through to , where they occupy rivers, estuaries, and nearshore marine areas. These distributions reflect a general absence from deep tropical latitudes, with only a limited number of subtropical or marginally tropical in Salangidae. In the , representation is more restricted, primarily through the family Retropinnidae ( smelts), which is endemic to temperate , including , the , southeastern , and . These inhabit coastal rivers, lakes, and brackish zones, with some extending into marine environments. The overall pattern underscores a bipolar temperate bias, with no native Osmeriformes recorded in or truly tropical realms. Human-mediated introductions have expanded the range of certain species beyond their native distributions. Notably, the rainbow smelt (Osmerus mordax) from the Osmeridae was intentionally introduced to Crystal Lake in in 1912 and subsequently spread to the by the 1920s, where it has become invasive, altering local ecosystems through predation and competition. Biogeographically, Osmeriformes display a vicariant pattern tied to ancient continental configurations, with northern families such as Osmeridae, , and Plecoglossidae tracing origins to , while the southern Retropinnidae reflect Gondwanan ancestry, likely diverging during the breakup of the supercontinents. This division highlights limited post-Gondwanan dispersal, contributing to the order's disjunct ranges.

Habitat Preferences and Adaptations

Osmeriformes occupy a variety of aquatic environments, including pelagic marine waters, coastal zones, and freshwater rivers and lakes, with many species exhibiting amphidromous or anadromous life cycles that involve migrations between marine and freshwater habitats. These fishes are predominantly found in cold-temperate regions, showing a strong preference for waters below 20°C, as evidenced by species like the (Mallotus villosus), which thrives in temperatures between -1°C and 3°C. The (Hypomesus transpacificus), for instance, displays no temperature preference below 15°C but exhibits aversion to temperatures exceeding 28°C, highlighting their to cooler conditions typical of their estuarine and riverine habitats. Physiological adaptations enable Osmeriformes to tolerate fluctuating salinities through effective , allowing transitions between freshwater, brackish, and marine environments without significant physiological stress. This euryhalinity is crucial for anadromous species in the family Osmeridae, which spend much of their adult life in open ocean or epipelagic zones but return to freshwater for spawning, while the can endure salinities up to 19 ppt in brackish estuaries. Reproductive adaptations include the production of adhesive eggs with membranes that attach to substrates like , , or vegetation in fast-flowing rivers, ensuring successful development in dynamic freshwater spawning grounds. Family-specific preferences further define their niches: Osmeridae species, such as smelts and , are primarily epipelagic in marine settings, often in the North Pacific, while inhabit brackish estuaries and freshwater systems in , with some anadromous forms. Vertically, most Osmeriformes range from epipelagic to mesopelagic depths up to 200 m, performing diel migrations to optimize foraging and predator avoidance. Retropinnidae exhibit amphidromous patterns similar to galaxiids, migrating to freshwater for juvenile growth after marine larval stages. Habitat threats, particularly pollution in rivers, degrade spawning grounds by altering water quality and substrate integrity, impacting reproductive success in species like the rainbow smelt (Osmerus mordax). Such anthropogenic pressures exacerbate vulnerability in these cold-water adapted fishes, underscoring the need for conservation of transitional habitats.

Life History and Behavior

Reproduction and Development

Members of Osmeriformes typically reproduce through , with spawning occurring primarily in freshwater rivers, streams, or coastal areas during spring months when water temperatures range from 8.9°C to 18.3°C. Many species, particularly in the family Osmeridae, undertake anadromous migrations from marine environments to freshwater spawning grounds, where they deposit demersal eggs that adhere to or substrates via sticky filaments or coatings. These eggs are non-pelagic and develop , often in clean, oxygenated riffles to ensure high survival rates. Fecundity varies by species but generally ranges from 5,000 to 70,000 eggs per female, depending on body size and population; for example, European smelt (Osmerus eperlanus) produce 8,000–50,000 yellow eggs measuring about 0.6 mm in diameter. Sexual maturity is reached at 1–4 years of age and body lengths of 5–20 cm, with some species like (Hypomesus transpacificus) maturing in their first year. Reproductive strategies include semelparity in certain taxa, where adults die after spawning; this is observed in (Mallotus villosus), which exhibit facultative semelparity with post-spawning mortality in beach-spawning populations, and in (Plecoglossus altivelis), where adults spawn in river lower reaches and perish afterward. Family-specific variations occur in spawning patterns; Osmeridae species often feature single, large spawning events tied to anadromous migrations, while , such as Chinese icefish (Protosalanx chinensis), are multiple or batch spawners with ovaries containing oocytes of varying sizes, enabling several spawning episodes over an extended period from autumn to winter. In like Neosalanx taihuensis, absolute fecundity is lower at around 1,250 eggs per individual, with spawning protracted from October to December. Egg development lasts 10–21 days at temperatures of 12–16°C, hatching into transparent, pelagic yolk-sac larvae that are immediately transported downstream to estuarine or marine waters for further growth. These larvae remain pelagic, feeding on while absorbing the , and undergo into juveniles at lengths of 2–5 cm, marking the transition to a more benthic or schooling lifestyle. is often synchronized within populations to optimize survival against predation.

Feeding and Migration Patterns

Members of the order Osmeriformes exhibit primarily planktivorous diets, consuming such as copepods, cladocerans, and mysids, as well as in certain families. In the Osmeridae, species like the rainbow smelt (Osmerus mordax) feed on small crustaceans and shift to piscivory on smaller fish as adults, with larger individuals consuming up to 83% fish in their diet during certain seasons. The Plecoglossidae, represented by the (Plecoglossus altivelis), are largely herbivorous, grazing on diatoms, , and blue-green algae attached to substrates using specialized leaf-like teeth, though juveniles also ingest planktonic rotifers and cladocerans. Retropinnidae species, such as the smelt (Retropinna retropinna), consume including copepods and cladocerans as juveniles, transitioning to small larvae and surface-dwelling prey in adulthood. Foraging behaviors in Osmeriformes typically involve schooling in the to pursue prey, often guided by visual and olfactory cues. Many species, particularly in the Osmeridae, undertake diel vertical migrations, ascending to shallower waters at night to feed on and before descending during the day to avoid predators. Osmerids like the (Hypomesus transpacificus) forage actively during daylight in estuarine environments, targeting copepods and amphipods. In contrast, the herbivorous ayu employs territorial grazing on riverbed , defending patches of diatoms from competitors. Migration patterns among Osmeriformes are diverse, with many species displaying anadromous life histories for accessing marine feeding grounds. Osmerids such as the rainbow smelt and eulachon (Thaleichthys pacificus) migrate from coastal marine waters into rivers for spawning but feed extensively in oceanic plankton-rich zones during non-reproductive periods. Retropinnidae exhibit diadromous behaviors, including catadromous elements in some populations, where adults move from freshwater to coastal seas for feeding before returning upstream. The ayu is amphidromous, with larvae dispersing to sea for planktonic feeding before juveniles migrate back to rivers in spring to graze on algae. Osmeriformes play a crucial trophic role as , serving as primary prey for larger piscivores, seabirds, and marine mammals, particularly during coastal aggregations. Their abundance supports food webs in temperate marine and freshwater systems, with species like (Mallotus villosus) forming massive schools that sustain fisheries and predators. Certain taxa, such as the ayu, act as bioindicators of due to their preference for clean, oligotrophic rivers. Dietary variations occur ontogenetically across the order, with juveniles predominantly planktivorous on and rotifers, while adults often shift to larger prey including small or benthic . In Osmeridae, larval stages rely on copepods for growth, transitioning to mysids and in later life stages to meet energetic demands. This shift enhances survival and growth, as seen in rainbow smelt where piscivorous feeding correlates with larger body sizes.

Fossil Record and Evolution

Evolutionary Timeline

The evolutionary history of Osmeriformes begins with molecular clock estimates placing their divergence from closely related groups, such as Esociformes, around 150 million years ago during the to period. This stem age reflects the early radiation within the broader Protacanthopterygii , with the order's emerging between 80 and 126 million years ago in the Early to mid-Cretaceous, based on Bayesian relaxed clock analyses calibrated with multiple constraints. Initial diversification likely occurred in marine and coastal environments during the , setting the stage for subsequent adaptive shifts to freshwater habitats in the . A major radiation followed the Cretaceous-Paleogene (K-Pg) extinction event approximately 66 million years ago, when Osmeriformes underwent rapid diversification in the , filling ecological niches vacated by extinct taxa. This post-extinction rebound is marked by the oldest definitive osmeriform fossils from deposits in , , representing early members of the order shortly after the boundary. Molecular estimates suggest the split between major suborders, such as Retropinnoidei and Osmeroidei, occurred around 80 million years ago in the , further structuring the group's internal diversity prior to the Paleocene expansion. Diversity peaked during the epoch, with evidence of widespread presence and ecological specialization, as highlighted by the description of the extinct family Ferruaspidae from approximately 15-million-year-old deposits in , . This period saw Osmeriformes achieving high species richness in temperate freshwater systems, particularly among retropinnids and smelts, before a decline in the . Repeated glaciations during this era contracted southern ranges, isolating populations and reducing overall distribution, especially in austral regions where ice advances eliminated habitats and drove local extinctions.

Extinct Taxa and Paleobiology

The fossil record of Osmeriformes includes several key taxa that provide insights into the early diversification of this order, primarily from the to epochs. One of the earliest known osmeriforms is Speirsaenigma lindoei, a primitive osmeroid discovered in deposits of the Cypress Hills Formation in and , . This species, described from articulated skeletal material, exhibits morphological features such as a plecoglossid-like body form, suggesting affinities with modern ayu fishes (Plecoglossus spp.), and is interpreted as a basal member of the Osmeriformes radiation. A notable recent discovery is Ferruaspis brocksi, the of the new family Ferruaspidae, from (approximately 11–16 million years ago) sediments at McGraths Flat in , . This is represented by exceptionally preserved articulated skeletons, including soft tissues like melanophores and stomach contents, embedded in goethite-rich concretions from what is inferred to be a freshwater connected to a river system. Morphologically, F. brocksi possesses a slender, body with 45 vertebrae, an adipose fin, counter-shading pigmentation, and two lateral stripes, resembling elongate forms in modern Retropinnidae; phylogenetic analyses position it as an early-diverging osmeriform. Other extinct osmeriforms include Osmerus-like forms known from otolith assemblages in Eocene deposits across , such as those attributed to primitive osmerids in Lutetian sediments of the Aquitaine Basin in southwestern , indicating early presence in northern temperate marine or brackish environments. In , potential early salangid relatives are suggested by otolith records from strata, though definitive skeletal evidence is lacking due to the group's cartilaginous endoskeletons. Preservation of osmeriform fossils is predominantly through s in marine and lagoonal deposits, with rarer articulated skeletons in lacustrine settings like those yielding Ferruaspis. Paleobiological inferences for extinct osmeriforms highlight lifestyles similar to many extant members, including anadromous or amphidromous migrations in early taxa like Speirsaenigma lindoei, which likely inhabited freshwater rivers with spawning runs akin to modern plecoglossids. In contrast, Ferruaspis brocksi appears adapted to fully freshwater habitats, with an opportunistic benthopelagic diet evidenced by preserved gut contents including phantom midge larvae, , and bivalves, and possible nocturnal foraging behaviors inferred from pigmentation patterns. The Australian occurrence of Ferruaspidae supports in situ evolution of southern osmeriforms, potentially linked to post-Gondwanan riverine adaptations rather than direct vicariance. Among more recent extinctions, the New Zealand grayling (Prototroctes oxyrhynchus), an osmeriform in the family Retropinnidae, is listed as Extinct by the IUCN due to overexploitation and habitat loss in the 19th–20th centuries; this species exhibited anadromous behavior, migrating from sea to freshwater rivers for spawning, mirroring paleobiological patterns in fossil relatives.

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