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Anabas testudineus

Anabas testudineus, commonly known as the climbing perch, is a of air-breathing belonging to the Anabantidae, characterized by its robust, fusiform body reaching a maximum length of 25 cm, greenish coloration, and distinctive labyrinth organ that enables obligate air-breathing. Native to South and , it inhabits a variety of lowland aquatic environments including canals, lakes, swamps, rivers, paddy fields, and brackish estuaries, demonstrating remarkable tolerance to low oxygen levels, turbid and stagnant waters, high temperatures, and pollution. This is renowned for its ability to traverse land over short distances—up to several hundred meters—using its strong pectoral fins and opercular movements, allowing it to migrate between water bodies or aestivate in moist mud during dry periods for extended durations. Ecologically, A. testudineus is an omnivorous predator that primarily feeds on smaller , such as and molluscs, and some plant matter, contributing to its role in local food webs within and systems. Reproduction occurs during the rainy season, with females producing 5,000 to 35,000 buoyant eggs per spawning event, which are guarded by males in shallow, hypoxic surface nests without further . Its wide-ranging distribution spans from and through , , , , , , , , southern , , , , and , with introductions to the and other regions where it can become invasive due to its adaptability. Despite facing localized threats from habitat degradation, , and competition with , A. testudineus maintains a stable and abundant population across its native range, leading to its classification as Least Concern on the . Economically significant, it supports commercial fisheries, , and live food markets in , valued for its flavorful meat and resilience in farming systems. Although occasionally kept in aquariums, its aggressive behavior limits its popularity in the trade.

Taxonomy

Classification

Anabas testudineus belongs to the domain Eukaryota, kingdom Animalia, phylum Chordata, class , order Anabantiformes, family Anabantidae, genus , and species A. testudineus (Bloch, 1792). The for this species is Anthias testudineus Bloch, 1792. It is known by several common names, including , , and snakehead-like fish. Although morphological variations occur across its range, A. testudineus has no recognized and is treated as a single . The Anabantidae family, to which it belongs, is distinguished by the labyrinth organ, an accessory respiratory structure enabling air breathing.

Taxonomic history

Anabas testudineus was first scientifically described by the German naturalist in 1792, based on specimens collected from . Bloch named the species Anthias testudineus in his work Naturgeschichte der ausländischen Fische, volume 6, where he detailed its distinctive morphology and noted its ability to survive out of water for extended periods. This description drew from earlier observations by Danish naturalist Dagobert Karl Daldorff in 1791, who documented the fish's amphibious behavior in Tranquebar (modern-day , ), including reports of it climbing vegetation. The species was initially classified within the genus Anthias, but subsequent taxonomic revisions reclassified it into the newly established genus Anabas by Georges Cuvier in 1816, reflecting its climbing capabilities (from Greek anabaino, meaning "to ascend"). Historical synonyms include Perca scandens (Daldorff, 1797) and Amphiprion scansor (Bloch & Schneider, 1801), the latter proposed in the posthumous continuation of Bloch's work by Johann Gottlob Schneider. Early European naturalists in the 18th and 19th centuries contributed significantly to its study through collections and illustrations; for instance, Johann Friedrich Hennig provided a colored plate in 1792, though it inaccurately depicted the eye color as blue rather than the actual yellowish to reddish hues. These efforts highlighted the fish's labyrinth organ, enabling air breathing, which fascinated researchers like Bloch and fueled interest in its amphibious traits. In modern taxonomy, a 2000 allozyme study of seven wild Thai populations of A. testudineus revealed significant genetic differentiation, with populations clustering into three geographic groups (central/eastern and peninsular). Despite this, the current consensus maintains Anabas testudineus as monotypic, with the genus Anabas often regarded as a pending comprehensive revision across its range; no formal taxonomic splits have been proposed. The assessment notes taxonomic uncertainties within the species, though it remains classified as Least Concern as of 2019.

Description

Morphology

Anabas testudineus exhibits an elongated, body shape that is robust anteriorly and compressed posteriorly, providing a streamlined form suited to its environment. Adults typically reach a maximum total length of 25 cm, though the common length is around 12.5 cm. The coloration of A. testudineus varies from dark to pale greenish dorsally, with the back appearing dusky to olive and the ventral surface very pale. The head bears longitudinal stripes ventrally, a dark spot on the posterior margin of the opercle, and a golden-reddish , contributing to its overall cryptic appearance. The fins are distinctive, with strong pectoral fins providing structural support. The dorsal fin comprises 16–20 spines and 7–10 soft rays, while the anal fin has 9–11 spines and 8–11 soft rays. The gill covers (opercula) are robust and edged with prominent spines. The head is scaled, featuring 4–5 rows of scales between the eye and the rear margin of the preoperculum, with a mouth position. The body is covered in large, regularly arranged ctenoid scales, and the is complete, bearing 26–32 pored scales. These robust opercula are linked to the species' air-breathing capability.

Physiology

Anabas testudineus possesses a specialized respiratory organ known as the labyrinth organ, which is derived from modified and fused arches positioned above the opercular cavity. This structure consists of numerous thin, vascularized plates arranged in a labyrinthine configuration, facilitating the absorption of oxygen directly from the air. The labyrinth organ enables the to function as an obligate air-breather, requiring periodic gulps of atmospheric air to meet its oxygen demands, even in well-oxygenated water. In aquatic habitats, A. testudineus relies primarily on its gills for , extracting dissolved oxygen from water, while tolerating hypoxic conditions common in its native stagnant or swampy environments. Upon emersion or in low-oxygen waters, it shifts to bimodal respiration, utilizing the labyrinth organ for aerial oxygen uptake supplemented by through the highly vascularized skin and buccopharyngeal cavity. This adaptation allows survival out of water for several days to weeks, provided the respiratory surfaces remain moist to prevent . As a species, A. testudineus demonstrates robust osmoregulatory capabilities, maintaining ionic balance across a range of salinities from freshwater to brackish conditions up to 10-15 parts per thousand (). It achieves this through active ion transport in the gills and intestine, with optimal observed in salinities below 10.2 and reduced survival above 12.4 in juveniles. The species exhibits advanced sensory adaptations, particularly an expanded with a large repertoire of olfactory receptor genes (approximately 615), which enhances chemosensory detection during terrestrial movements. This well-developed olfaction allows A. testudineus to orient toward distant water bodies over by perceiving gradients or chemical cues in the air. During prolonged terrestrial phases, A. testudineus undergoes metabolic adjustments, including reduced locomotor activity and lowered overall energy expenditure, to conserve internal moisture and minimize evaporative water loss. This strategy, coupled with efficient excretion via volatilization in air, supports extended emersion without significant physiological stress.

Distribution and habitat

Native range

Anabas testudineus is native to South and , with its distribution extending from and —including , , and —in the west, eastward to southern , , , , , , , up to the . Historical records confirm its presence in the , though it is absent from higher altitudes above 150 m. The species is particularly abundant in lowland river basins, such as the in , the in , and the Irrawaddy in , where it thrives in tropical and subtropical climates. It prefers water temperatures ranging from 22°C to 30°C, reflecting its adaptation to warm, stable environments in these regions. Within its native range, A. testudineus occupies diverse freshwater habitats like swamps, rivers, canals, and flooded fields, often in sluggish or stagnant waters.

Introduced populations

Anabas testudineus has been intentionally introduced to several regions outside its native range primarily for purposes, with notable establishments in and parts of the Pacific. In , the species was first introduced to the adjacent Irian Jaya (now part of ) around the 1970s, likely for food production, and subsequently spread naturally into the Fly River system by 1983, where it has since established self-sustaining populations through natural reproduction. In the Pacific, introductions have occurred to islands such as those in the from and to other nearby locales, often tied to initiatives, leading to established populations in freshwater habitats. Accidental introductions via the aquarium trade have also contributed to its spread, though these have been less successful in establishing long-term populations. In , A. testudineus has established in the , including Boigu and Saibai, where it was likely introduced through human-mediated transport from , possibly via fishing activities or informal trade. From these sites, the species has begun invading northern freshwater systems, facilitated by its air-breathing ability that enables overland dispersal of up to several kilometers. As an invasive species, it poses significant ecological threats by competing aggressively with native for resources, potentially dominating aquatic communities and altering local ; for instance, it can outnumber indigenous species in affected waterways and prey on or suffocate smaller vertebrates. Attempts to establish A. testudineus in the United States, particularly in , were unsuccessful, with populations introduced via aquarium releases in the mid-20th century being eradicated by the 1970s due to inability to tolerate cold winters and limited . Similar failed efforts have been noted in other regions, such as parts of , where introductions did not lead to widespread establishment. Currently, the species' non-native range remains limited but is expanding in , where it is actively monitored as a high-risk invasive under regulations, with requirements for reporting and removal of individuals to prevent further spread into mainland waterways. In and Pacific islands, established populations continue to persist in riverine and pond habitats, though their overall distribution outside is not yet extensive.

Ecology and behavior

Feeding and diet

Anabas testudineus exhibits an omnivorous diet, with feeding preferences varying between juveniles and adults. Juveniles primarily consume , , and small such as and rotifers, reflecting a more herbivorous tendency in smaller size classes (95–164 mm total length). As the fish mature into adults (165–194 mm total length), their diet shifts toward a more carnivorous composition, incorporating , crustaceans, small , and matter including , diatoms, and debris. The species employs an opportunistic strategy as a surface feeder, utilizing its protrusible mouth to gulp prey from the water surface or nearby vegetation. Feeding activity peaks during nocturnal or crepuscular periods, enabling efficient capture of mobile prey like and small organisms in low-light conditions. Occasionally, individuals undertake brief terrestrial excursions to access additional food sources such as land-based . Stomach content analyses from wild populations reveal a dominated by animal matter, comprising 62.58–79.66% (up to over 70% in some studies) of the total intake, including , , , snails, and , with the remainder consisting of plant material and debris. In floodplain habitats, the adapts flexibly to seasonally available resources, increasing consumption of flooded and during wet periods. The high protein content from animal-based foods supports rapid juvenile growth, allowing A. testudineus to reach 10–15 cm in total length within the first year, facilitating early maturation and survival in dynamic environments.

Reproduction and life cycle

In , Anabas testudineus exhibits a group-synchronous reproductive cycle divided into four stages: preparatory (), pre-spawning (May–), spawning (), and post-spawning (September–January), as determined by gonadosomatic index (GSI) and histological analysis of gonads. Spawning occurs during the season, triggered by rising water levels and temperatures around 28°C, with the gonadosomatic index showing significant increases leading up to peak activity in and . The is a multiple spawner capable of intermittent spawning events within the season, though no nest-building behavior is observed, and the is characterized by or . Reproductive timing varies across its range, with more continuous spawning in equatorial regions. Females produce pelagic eggs that are positively buoyant and scattered randomly in the during spawning. is reportedly absent, with no ing behavior observed and by adults common, though some sources suggest males may eggs at the surface of hypoxic waters and the topic remains debated in the literature. varies widely from about 1,500 to over 70,000 eggs per female depending on size and location; for example, one study reported 6,500 to 11,000 eggs for females weighing 7.5–9 g, positively correlated with body weight and weight (900–1,700 mg), with higher values up to 10,804 eggs recorded in pond conditions simulating natural habitats. is reached at approximately 8.4 total length, typically within the first year of life under natural conditions. The life cycle begins with embryonic development, where fertilized eggs hatch after about 24–36 hours at 28°C, progressing through , morula, blastula, gastrula, and neurula stages. Larvae are initially pelagic, relying on a for nutrition before transitioning to exogenous feeding on within days of hatching. The juvenile stage is attained around 8.3 mm standard length, marked by the completion of fin ray development, during which individuals begin to show schooling tendencies in shallow waters. Early juveniles develop air-breathing capabilities via the labyrinth organ, aiding in low-oxygen environments. Adults to solitary or loose aggregations, foraging independently in wetlands and streams, with a wild lifespan estimated at up to 9.65 years based on natural mortality rates.

Human uses

As food and aquaculture

Anabas testudineus is a valued in , particularly in , , and , where it is commonly prepared as grilled, curried, or fermented dishes. Despite its appealing taste, the fish is noted for being bony, which limits its appeal in some markets. The species supports substantial wild capture fisheries in rivers, ponds, and floodplains across the region. In , annual production reached approximately 66,497 metric tons in the 2019–20 fiscal year, contributing significantly to inland fisheries. It is often exported dried or live, with its air-breathing ability facilitating overland transport to distant markets without . In aquaculture, A. testudineus is cultured in ponds and integrated rice-field systems, where it helps pests like weeds and . A faster-growing Thai strain was introduced to in 2002 to enhance production, showing superior growth rates compared to local varieties. However, challenges such as among juveniles and low survival rates persist; hormone-induced has achieved survival rates of 73–85% in controlled systems. Nutritionally, A. testudineus offers high protein content (16–18% of body weight) and omega-3 fatty acids, making it a beneficial dietary source. In integrated rice-fish farming, it also aids by preying on larvae in paddies.

Cultural significance

In various Southeast Asian cultures, Anabas testudineus, known locally as betok in dialects, holds symbolic value tied to its remarkable ability to traverse land. attributes near-mythical climbing prowess to the fish, often portraying it as a resilient survivor capable of ascending trees during floods or dry spells. This imagery symbolizes adaptability and endurance in harsh environments, with communities in and viewing the fish as an emblem of perseverance against adversity. Among indigenous groups in , such as the Dayak in , the climbing perch—locally called ikan puyu—is incorporated into traditional beliefs as a protective . It is reared in household ponds or containers to ward off evil spirits and spells, attributed to the fish's hardy nature and air-breathing capability that allows survival in low-oxygen or terrestrial conditions. This practice underscores the fish's role in folk superstitions, where its "walking" behavior is seen as a trait conferring safeguarding to homes. In traditional medicine across South and Southeast Asia, A. testudineus is valued for its therapeutic properties, particularly in folk remedies linked to its air-breathing adaptation. In central Nepal's Chitwan-Annapurna Landscape, indigenous communities use the fish to treat respiratory problems, with 100% of surveyed informants reporting its efficacy when consumed as meat or soup. Similarly, among the Bodo tribe in , , the fish meat is ingested to alleviate , fever, , and general weakness, highlighting its role in ichthyotherapy for respiratory and vitality-related ailments. In , rural populations employ it to reduce labor pain, consuming extracts or the whole fish as part of Ayurvedic-inspired practices that emphasize its bioactive compounds for healing. The climbing perch also features in the aquarium trade as a novelty species, prized in and for demonstrations of its using pectoral fins and plates. Enthusiasts and educators maintain it in setups mimicking flooded fields to showcase amphibious adaptations, positioning it as a minor icon in education for illustrating evolutionary resilience.

Conservation

Status and threats

Anabas testudineus is classified as Least Concern on the , with the assessment conducted on 10 August 2019. This status reflects its widespread distribution across and the , where it remains relatively abundant in suitable habitats despite localized pressures. As of the 2025-1 IUCN Red List version, the status has not changed. The primary threats to native populations include habitat degradation from , dam construction, and , which fragment wetlands and floodplains essential for the ' survival. for food and aquarium trade exacerbates declines in heavily exploited regions, while in rivers and canals reduces sites by altering and oxygen levels. In seasonal wetlands, populations are particularly vulnerable to drying events, which limit access to refugia during low-water periods. Overall, global population trends are stable with no evidence of significant decline, though local reductions occur in overfished or polluted areas; the species remains abundant across its native range due to its adaptability and high reproductive capacity. In introduced regions like parts of , its invasive spread represents a reverse dynamic, posing threats to local rather than facing native-range pressures. Key research gaps include the need for updated genetic data on subpopulations to assess and , as current information on remains insufficient. Prior to its detection as an invasive in , the was considered in that context due to limited pre-establishment surveys.

Management and invasive impacts

In its native range, sustainable aquaculture practices for Anabas testudineus aim to alleviate pressure on wild stocks by increasing production through controlled farming. In , semi-intensive pond culture systems have been optimized for both Thai and Vietnamese strains, achieving higher growth rates and yields—such as up to 17 tons per hectare—while minimizing environmental impacts and supporting security. These methods, including supplemental feeding with bran and oil cake, reduce reliance on wild capture, which has declined due to in habitats. In , similar pond and cage-based systems enhance seed production and stock enhancement in reservoirs, promoting genetic purity to sustain natural populations amid habitat degradation. Restocking programs in both countries, often integrated with , release hatchery-reared juveniles into depleted wetlands to bolster , though risks from non-native strains necessitate careful genetic management. As an , A. testudineus poses significant challenges in non-native regions, prompting targeted control measures. In Australia's , where it was first detected on in late 2005, eradication efforts began in 2014 through the Torres Strait Regional Authority's Land and Sea Ranger program, with ongoing surveillance as of 2023. Rangers, trained in identification, employ physical barriers across wetlands to block overland migration, active trapping in swamps to remove individuals, and (eDNA) surveillance to map distributions and detect early incursions. Biosecurity protocols include community education on preventing transport via boats and gear from , alongside rapid response to curb spread toward the mainland, where establishment could devastate northern tropical waterways. In , the species is classified as a restricted noxious under the Biosecurity Act 2014, mandating immediate reporting of sightings, humane killing via head trauma, and localized intensive fishing or poisoning in contained water bodies to limit proliferation. The ecological impacts of invasive A. testudineus are primarily negative, driven by its opportunistic predation and habitat tolerance. In invaded wetlands, it preys on native , , and , disrupting local food webs by outcompeting endemic species and altering trophic dynamics in shallow, vegetated systems. This predation pressure, combined with consumption of macrophytes, can reduce in and field ecosystems, as observed in Pacific introductions where it dominates ephemeral pools. However, its surface-feeding behavior offers a potential benefit in agricultural settings, where it consumes culicine larvae—up to 1,158 fourth-instar individuals per fish daily in lab tests—potentially aiding in paddies without chemical interventions. Internationally, A. testudineus faces regulatory scrutiny to mitigate its invasive risks. In the United States, it is prohibited or restricted in several states, including and , due to its history of introduction and potential to establish in subtropical wetlands; federal ecological risk screenings highlight its high invasion potential, though no nationwide injurious listing exists. Under IUCN guidelines, it is monitored as an in regions like the and , with recommendations for prevention of further spread through trade and accidental releases, emphasizing early detection to protect hotspots.

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