Fact-checked by Grok 2 weeks ago

Bagridae

Bagridae is a family of freshwater catfishes in the order Siluriformes, characterized by scaleless bodies, typically four pairs of well-developed barbels, a strong spine preceding the with 6–7 soft rays (rarely more), serrated pectoral spines, and a variably developed adipose fin, encompassing about 240 valid species across 17–23 genera primarily native to and parts of . These catfishes are distributed across a wide range of freshwater systems, including rivers, lakes, and streams, with Asian species ranging from and the basin in the north to and in the south, while representatives like the genus Bagrus occur in the basin, west and central rivers south to the , and east rift lakes such as and . The family exhibits significant diversity in size, from small species under 10 cm to large forms exceeding 1 m in length, such as Hemibagrus wyckii, and displays sluggish behaviors adapted to benthic or mid-water lifestyles in tropical and subtropical environments. Taxonomically, Bagridae belongs to superfamily Bagroidea and includes the Bagrinae; it has been revised with the Claroteidae recognized as a separate family, though some phylogenetic studies debate exact boundaries. The family is distinguished from Claroteidae by osteological features such as the structure of the suspensorium and apparatus. Ecologically, bagrid catfishes are mostly carnivorous or omnivorous, feeding on , small , and , and many undertake seasonal migrations for in habitats. They hold significant economic value as food in local fisheries across South and and , with like Mystus vittatus and commercially important, while smaller forms such as those in Pseudomystus and Rita are popular in the aquarium trade for their distinctive patterns and behaviors. Conservation concerns affect several due to habitat loss, , and , with some, like Bagrus meridionalis, listed as critically endangered.

Description

Physical characteristics

Members of the Bagridae family exhibit a distinctive typical of catfishes, including a scaleless body with smooth, naked skin on the flanks that lacks any embedded scales, providing a streamlined form suited to their aquatic environments. A prominent is present, with high interspecific variability in size. The is equipped with a strong, rigid spine at its leading edge, while the pectoral fins feature serrated spines that aid in defense and . The anal fin contributes to stability and maneuvering, and the caudal fin is typically deeply forked to enhance propulsion. The head of bagrid catfishes is broad and depressed, flattened dorsoventrally to facilitate bottom-dwelling habits, with eyes positioned dorsally for enhanced visibility in low-light conditions. The mouth is inferior, wide, and bordered by four pairs of well-developed barbels—nasal, maxillary, and two pairs of mandibular—with the nasal barbels representing a key diagnostic trait that distinguishes Bagridae from related families lacking them, such as . These barbels, covered in taste bud-enriched , play a crucial role in sensory detection of prey and navigation. Internally, bagrid catfishes possess short rakers on the first , which in some , such as those in the genus , number 13-22 and facilitate filter feeding by trapping small particles from the alongside more general predatory behaviors. This structure supports their opportunistic diet in diverse freshwater habitats.

Size and coloration

Species in the Bagridae family exhibit considerable variation in body size, ranging from diminutive forms to large-bodied taxa. The smallest species reach a maximum standard length (SL) of approximately 29 mm, such as certain members of the genus Nanobagrus, while the largest can attain up to 130 cm total length (TL), exemplified by Hemibagrus wyckioides. As of November 2025, across the family's approximately 233 species, the average maximum SL is around 259 mm, with most commonly reaching about 150 mm SL. Coloration in Bagridae is diverse but generally features a dorsal surface that is olive-brown to yellowish, transitioning to lighter, often whitish or pale undersides, providing in varied substrates. Many display distinctive patterns, including dark s, irregular mottling, or longitudinal stripes and bands; for instance, tengara exhibits a light brown to dull yellow body with four to five parallel dark brown stripes along the sides and a prominent tympanic behind the operculum. These patterns can vary by , with some like Hemibagrus showing mottled or barred appearances, while others in Bagrichthys feature to black bases accented by cream-colored markings. Sexual dimorphism in Bagridae primarily manifests in body proportions and growth rates rather than pronounced color differences, though some genera show subtle variations. Males are often slimmer with elongated barbels or larger fins compared to females, and in species like Pelteobagrus fulvidraco, males grow significantly larger—up to three times the size of females—potentially influencing color intensity during reproductive phases. Color variations by sex or age are less common but reported in certain Mystus species, where mature individuals may exhibit brighter or altered skin tones. Ontogenetic changes in coloration are evident in many Bagridae, with juveniles typically displaying more vivid and contrasting patterns that serve antipredator functions, such as bold stripes or blotches, which often fade or become subdued in adults. For example, in Tachysurus taeniatus, young individuals show polymorphism with distinct banded morphs, while adults adopt a more uniform yellowish-gray tone with obscured blotches. Similarly, juveniles of Bagrus bajad feature prominent dark markings that diminish as the fish matures, aligning with shifts in habitat use and predation risks.

Distribution and habitat

Geographic range

The Bagridae family exhibits a broad distribution across continental and , with all genera except Bagrus confined to and Bagrus plus a few others endemic to . In , the range spans from the River basin and in the north westward through the and southward across to and , encompassing diverse riverine networks in these regions. High species diversity characterizes Asian hotspots, particularly the river basins of , , , , and , where numerous genera such as , Sperata, and Hemibagrus thrive. For example, Sperata aor is widespread in the Ganges-Brahmaputra-Surma systems of and , extending southward to the , highlighting the family's prominence in South Asian freshwater ecosystems. Similarly, species like Batasio convexirostrum occur in transboundary drainages such as the Koladyne basin shared by and , underscoring regional and . In Africa, the family's presence is more restricted, primarily to freshwater systems in the River basin, West, central, and southern African rivers (e.g., , , , Sanaga, and ) south to the , and East African Rift Valley lakes such as and . The genus Bagrus is notable in the and basins, with species like Bagrus bajad recorded from the , , , Sénégal, and Lakes and Turkana; additional genera including Auchenoglanis and Parauchenoglanis occupy Central and West African waters. is evident in , where species such as Lophiobagrus aquilus are confined to its rocky habitats. These African distributions reflect ancient continental river connections rather than recent dispersals.

Preferred environments

Bagridae species primarily inhabit lotic freshwater systems, including rivers, streams, and rapids, where they thrive in flowing waters that provide dynamic conditions for their lifestyle. Some species also occupy lentic environments such as lakes and floodplains, particularly during seasonal inundations, but the family as a whole avoids brackish or waters, remaining confined to strictly freshwater habitats across their range in and . These catfishes are adapted to warm tropical and subtropical conditions, with preferred water temperatures typically ranging from 20 to 30°C, as observed in habitats like the rivers where mysticetus occurs year-round in stable warm waters. Water pH levels generally fall between 6.5 and 8.0, supporting neutral to slightly alkaline environments common in their riverine systems. Dissolved oxygen concentrations are often low to moderate, particularly in slower-flowing or seasonally hypoxic sections, to which many species show tolerance through physiological adaptations. Additionally, Bagridae exhibit resilience to elevated levels, especially in monsoon-influenced rivers where sediment loads increase, allowing them to persist in visually obscured waters without significant disruption to their ecology. In terms of microhabitats, Bagridae often occupy benthic or mid-water zones, positioning themselves close to submerged or rocky substrates that offer cover and foraging opportunities. For instance, species like Hemibagrus wyckioides prefer large upland rivers with rocky bottoms and variable depths, while others associate with vegetated margins in streams. Certain genera, such as Batasio, are specialized torrent-dwellers, favoring fast-flowing hill streams with high current velocities and gravelly or rocky beds, where they exploit the oxygen-rich, turbulent conditions. Key adaptations enable Bagridae to exploit these environments effectively, including streamlined body shapes that reduce drag and enhance maneuverability against strong currents in rapids and streams. Some species, particularly within the Mystus, possess a suprabranchial organ that facilitates facultative air-breathing, allowing survival in hypoxic waters by supplementing respiration with atmospheric oxygen uptake.

Biology and ecology

Reproduction and development

Bagridae species exhibit as their primary reproductive mode, characterized by where males release over eggs laid by females. The eggs are typically demersal and , allowing them to attach to substrates such as rocks, vegetation, or nest structures in riverbeds or ponds, which helps prevent drift in flowing waters. For example, in Leiocassis ussuriensis, eggs measure approximately 2.36 mm in diameter, lack oil globules, and are covered in a mucous layer enhancing . Similarly, fertilized eggs of Pseudobagrus fulvidraco are compressed spherical, light-yellowish, and , with an featuring outer electron-dense fibers for attachment. Breeding in Bagridae is generally seasonal, closely aligned with environmental cues like rainfall and water levels. In Asian species, spawning is predominantly tied to the period, occurring from May to to coincide with increased river flow and flooding that facilitates egg dispersal and larval survival. For instance, Rita chrysea breeds during June to in the River system, while Mystus vittatus peaks from May to in rivers. In African species, such as Bagrus docmak in Lake Chamo, , reproduction occurs during the , with mature individuals migrating to shallow spawning grounds. Sperata seenghala, an Asian bagrid, shows an extended breeding window from May to , peaking in July-, often in constructed nests. Parental care in Bagridae is typically limited, with most species scattering eggs without post-spawning attention, relying on high for recruitment success. However, some taxa display male-mediated guarding behaviors to protect eggs from predators and environmental hazards. Similarly, Bagrus meridionalis in demonstrates bi-parental care, with adults defending nests during the January-to-March spawning period. In , parents construct and utilize nests for egg deposition and early fry protection, observed during peak breeding months. Early development in Bagridae proceeds rapidly, enabling quick transition to independent feeding amid high predation pressures. Larvae typically hatch 2–3 days post-fertilization, depending on (e.g., 51 hours at 26.5–31.5°C in Mystus macropterus, or 73 hours at 25°C in Leiocassis ussuriensis). At hatching, prelarvae measure 6–7 mm in total length, with a prominent providing initial nourishment; absorption occurs within 6–12 days, marking the shift to exogenous feeding around days 5–7. Growth to the juvenile stage is swift, spanning weeks, during which key morphological features like barbels emerge early for sensory enhancement—rudimentary barbels are present at hatching in M. macropterus, with three pairs fully positioned by day 5 and pigmentation developing by day 18. By 20 days post-hatching, juveniles reach 23 mm, with complete fin development and a functional system.

Diet and feeding behavior

Members of the Bagridae family exhibit a diet that ranges from omnivorous to predominantly carnivorous, with benthic feeding being the dominant mode across species. Common prey items include (such as larvae and nymphs), crustaceans (including amphipods and shrimps), small , (diatoms and ), and , though the exact composition varies by and . For instance, in Bagrus bajad from , the diet is largely carnivorous, featuring cichlids, , shrimps, and amphipods as primary components, with a relative gut index indicating adaptation to animal matter. Similarly, vittatus primarily consumes copepods, diatoms, parts, and insect larvae, reflecting an omnivorous strategy in estuarine environments. These catfishes contribute to nutrient cycling in riverine ecosystems by processing and , facilitating energy transfer in benthic food webs. Foraging strategies in Bagridae are adapted to their bottom-dwelling , with most relying on sensitive barbels equipped with to probe sediments and detect prey in low-visibility conditions. This chemosensory mechanism plays a crucial role in the initial stages of feeding, allowing detection of food items buried in substrates. Some , like certain Chrysichthys, employ mid-water tactics with rapid strikes on passing prey, though benthic probing remains prevalent. Feeding intensity varies seasonally; for example, Bagrus bajad shows maximum gut fullness in (fullness index 0.98), when crustaceans dominate, shifting to higher fish consumption in summer and autumn (up to 86% occurrence). In rivers, flood pulses enhance availability during wet seasons, influencing prey abundance and dietary shifts. Ontogenetic shifts in are evident in many bagrid , where juveniles initially feed on planktonic and small , transitioning to larger prey like as adults grow. In Bagrus docmak from Lake Chamo, juveniles under 40 cm fork length consume primarily , while adults over this size are almost exclusively piscivorous, with comprising over 98% of their by weight and a prey:predator length ratio of 1:2 to 1:6. This progression positions Bagridae as mid-level predators in aquatic food webs, preying on primary consumers while serving as forage for higher trophic levels, thus maintaining ecological balance in freshwater systems.

Predation and threats

Bagridae catfishes serve as prey for a variety of aquatic and riparian predators across their native ranges in and . Larger predatory fishes, including cyprinids such as ( spp.) and other siluriform catfishes, consume smaller individuals and juveniles, which are particularly vulnerable due to their size and limited defensive capabilities. Avian predators like ( spp.) and () target juveniles and smaller species in shallow waters, while mammals such as otters (Lutrinae) occasionally prey on them in riverine habitats. To mitigate predation risks, Bagridae employ several antipredator adaptations. Sharp, stout spines in the dorsal and pectoral fins can be locked in place to deter attackers, inflicting injury or making capture difficult; these structures are particularly effective against gape-limited predators. Many species exhibit mottled or cryptic brown and gray coloration that provides camouflage against benthic substrates like mud and gravel, enhancing concealment during rest periods. Additionally, several genera, such as Pseudobagrus, display predominantly nocturnal activity patterns, reducing encounters with diurnal visual hunters by foraging primarily at night. Ecologically, Bagridae occupy an intermediate trophic position, functioning as key prey for higher-level consumers and thereby supporting stability in freshwater systems. Their sensitivity to organic pollution and habitat degradation positions them as bioindicators of riverine , with population declines often signaling environmental stress. In terms of interactions, native Bagridae populations in regions like Lake Dianchi, China, experience competitive pressure from such as (Ctenopharyngodon idella) and tilapias ( spp.), which exploit similar resources and contribute to native declines through resource overlap. In areas with high population densities, such as seasonally flooded rivers, Bagridae may facilitate disease transmission among conspecifics and other fish via shared pathogens in confined spaces, though specific vectors remain understudied.

Taxonomy and systematics

Classification history

The family Bagridae was established by in 1858 as part of the order Siluriformes, encompassing a broad assemblage of Asian catfishes characterized by their lack of scales and presence of barbels. Initially, the family included a diverse range of taxa from freshwater and brackish environments across and , reflecting the limited morphological distinctions available at the time and leading to overlaps with other siluriform groups. This early classification laid the foundation for recognizing bagrids as a distinct lineage within the superfamily Bagroidea, though boundaries were fluid and subject to ongoing refinement. During the 19th and 20th centuries, key revisions narrowed the family's scope through morphological analyses, particularly emphasizing traits such as barbel configuration, fin structure, and cephalic features. Splits from families like Schilbeidae occurred progressively, with taxa such as Neotropius reassigned to Bagridae based on shared autapomorphies like specific cranial and fin morphologies. In the 20th century, studies focused on barbel length, adipose fin shape, and dorsal spine serrations to delineate genera, culminating in comprehensive works that revalidated groups like Hemibagrus and described new ones, reducing synonymy and clarifying intrafamilial relationships. The advent of in the , utilizing markers such as and , has confirmed the of Bagridae (excluding outliers like Rita) and resolved deeper evolutionary relationships within Siluriformes. Recent post-2020 studies employing integrative taxonomy—combining genetics, morphometrics, and ecology—have further refined genera like , revealing cryptic diversity and validating new species through multi-locus approaches. Recent phylogenetic studies have supported the separation of the African Claroteinae as the distinct family Claroteidae, restricting Bagridae primarily to Asian taxa, though some classifications retain a broader . Taxonomic debates have persisted, notably regarding the historical inclusion of genera like , which morphological and molecular evidence has since transferred to Sisoridae based on distinct sisorid synapomorphies such as thoracic adhesive organs. These advancements have driven a significant increase in recognized , from approximately 120 in mid-20th-century estimates to 233 by 2025, reflecting enhanced sampling and analytical tools.

Current genera and species

The Bagridae family is classified within the superorder , order Siluriformes, and suborder Siluroidei, encompassing a diverse group of primarily freshwater catfishes distributed across and . As of November 2025, the family comprises 17 valid genera and 233 valid species, reflecting ongoing taxonomic refinements through morphological and molecular analyses. Among the major genera, Bagrus, restricted to African river systems, includes 9 recognized species, such as B. bayad, B. docmak, B. ubangii, B. meridionalis, and others, which are notable for their larger body sizes and piscivorous habits. In contrast, Hemibagrus, predominantly Asian, contains approximately 41 species, such as H. nemurus and H. wyckii, many of which inhabit fast-flowing rivers in and exhibit elongated bodies adapted to rheophilic environments. Leiocassis, centered in , encompasses about 10 species, including L. poeciloptera and L. crassirostris, often found in Chinese and Vietnamese drainages with subdued fin spines characteristic of the genus. The most speciose genus is , with around 50 valid species distributed widely across , exemplars like M. vittatus and M. bleekeri demonstrating high adaptability to varied freshwater habitats from to Indochina. Species diversity within Bagridae is highest in the , encompassing the , Salween, and basins, where complex topography and seasonal monsoons support elevated and rates. Recent taxonomic additions from 2016 to 2025, totaling 18 new species, have primarily involved the genus and allies, often identified through of the cytochrome c oxidase subunit I gene alongside traditional ; notable examples include cyrusi from Iranian waters in 2022 and Pseudomystus nuchalis from Borneo's Barito River in 2025. Endemism is pronounced in Bagridae, with numerous confined to single river basins or tributaries, such as albolineatus limited to the system in , , and , underscoring their vulnerability to localized habitat alterations. Formally recognized are absent across the family, as taxonomic practice emphasizes species-level distinctions based on genetic and morphological discontinuities rather than infraspecific categories.

Conservation status

Threats and declines

Bagridae populations across their native ranges in and are primarily threatened by for food and the ornamental trade, which has caused significant reductions in catch sizes and local abundances for species such as Horabagrus brachysoma in rivers. Intensive exploitation, including in multispecies fisheries, is driven by high market demand in , where bagrid catfishes like vittatus are harvested for consumption despite their least concern status, resulting in observed population decreases. Habitat loss from dam construction and deforestation represents another critical pressure, fragmenting riverine ecosystems and blocking migratory pathways essential for bagrid dispersal and access to spawning grounds. In Southeast Asian basins, hydroelectric projects have altered flow regimes, directly impacting species through habitat degradation. Similarly, in African systems, overfishing threatens Bagrus docmak in East African waters. Pollution from agricultural runoff, industrial effluents, and urban development degrades in key Asian river habitats, leading to of toxins and reduced oxygen levels that affect bagrid and . For example, chemical contaminants in the have contributed to the decline of Horabagrus brachysoma. Pollution and from conversion to ponds also affect species such as Pseudobagrus medianalis. IUCN assessments indicate declining trends for multiple Bagridae species due to these pressures; taxa include Hemibagrus punctatus in India's , where siltation and exploitation have nearly eliminated populations. As of 2025, approximately 26% of assessed species, including some Bagridae, are threatened with . Regional disruptions from impoundments further hinder spawning by desynchronizing flood cues, as observed in Horabagrus species that rely on pre-monsoon flows for gonadal development. In altered riverine environments, competition from invasive species exacerbates declines, with introduced predators and competitors displacing native bagrids like Pseudobagrus medianalis through resource overlap in fragmented habitats.

Protection efforts

Protection efforts for Bagridae species focus on legal safeguards, international assessments, habitat initiatives, and targeted research to mitigate declines in this diverse family of catfishes. Although no Bagridae species are currently listed under the Convention on International Trade in Endangered Species (CITES) Appendices, national legislation provides critical protections in key range countries. In India, the Wildlife (Protection) Act, 1972 safeguards threatened freshwater fishes, including critically endangered species such as the Nilgiri mystus (Hemibagrus punctatus), which is endemic to the Western Ghats and benefits from habitat conservation measures under this framework. In China, the revised Wildlife Protection Law (effective 2023) enhances protections for rare and endangered aquatic species, encompassing several Bagridae assessed as at-risk, such as those in the Yangtze River basin, by prohibiting unauthorized capture and trade while promoting biodiversity preservation. The International Union for Conservation of Nature (IUCN) Red List serves as a foundational tool for Bagridae conservation, with assessments updated between 2021 and 2025 highlighting status changes for multiple species and guiding priority actions. For instance, reassessments have informed recovery plans for vulnerable taxa like Mystus vittatus, emphasizing the need for sustained monitoring amid ongoing habitat pressures. Complementing these, the World Wildlife Fund (WWF) supports habitat restoration in the Mekong River basin, where projects aim to protect critical spawning grounds for migratory catfishes, including Bagridae genera such as Hemibagrus, through riverine connectivity enhancements and anti-dam advocacy. Research and breeding programs are pivotal for preserving and bolstering populations of endangered Bagridae. Captive breeding initiatives, particularly for species, have advanced through hormone-induced spawning techniques; for example, successful protocols for Mystus dibrugarensis in controlled aquaria demonstrate good fertilization and hatching rates, offering a model for restocking depleted rivers in and . Genetic studies further support these efforts by mapping population structures, such as analyses of Hemibagrus guttatus revealing low diversity in fragmented habitats, which inform targeted gene banking and reintroduction strategies to maintain evolutionary potential. Notable successes underscore the efficacy of integrated approaches. In , community-based (CBFM) programs have led to recoveries for indigenous Bagridae like gulio, contributing to increased overall fish yields in managed wetlands through regulated access and establishment, enhancing local livelihoods while conserving . Similarly, protected reserves in have facilitated gradual recoveries for Bagridae species via reduced and rehabilitation, aligning with broader IUCN plans for freshwater fishes.

References

  1. [1]
    FAMILY Details for Bagridae - Bagrid catfishes
    Summary of each segment:
  2. [2]
    CAS - Eschmeyer's Catalog of Fishes - Genera/Species by Family/Subfamily
    ### Summary for Bagridae
  3. [3]
    Complete mitochondrial genomes of two catfishes (Siluriformes, Bagridae) and their phylogenetic implications
    **Summary of Bagridae Taxonomy, Distribution, Number of Species, and Characteristics:**
  4. [4]
    [PDF] An Extensive Taxonomic Analysis of Catfish Species (Family ... - AWS
    Jan 22, 2025 · The study aims to assess the diversity and threatened status of Bagridae catfishes in the region, identify morphological discrimination using ...
  5. [5]
    CAS - Eschmeyer's Catalog of Fishes
    Bagridae. Distribution: Southern Africa: Shire River and Lake Malawi. IUCN (2019): Critically endangered. Habitat: freshwater.
  6. [6]
    (PDF) Biometry of Bagrid Fish Mystus pelusius (Solander, 1794 ...
    Aug 7, 2025 · Meristic and morphometric characters are given. Dorsal fin containing one strong spine and 6-8 rays, anal fin 9-12 rays, total gill raker 14 on ...
  7. [7]
    Eight in One: Hidden Diversity of the Bagrid Catfish Tachysurus ...
    Head depressed, broad, and covered with thin skin. Snout blunt in dorsal view, longer than eye diameter. Eye large, elliptical, covered with thick membrane ...
  8. [8]
    Barbel regeneration and function divergence in red-tail catfish ...
    ... four pairs of barbels (including nasal barbels, maxillary barbels, outer ... Bagridae family. Genet. Mol. Res., 13 (2014), pp. 9533-9542, 10.4238/2014 ...
  9. [9]
    Mystus - an overview | ScienceDirect Topics
    Short adipose fin, originated considerably well behind dorsal fin and ... head length, first branchial arch with 13–22 gill rakers. Coloration. In live ...
  10. [10]
    PlanetCatfish.com - The catfish family Bagridae - Cat-eLog
    Family Overview. Pronounced, BAG rid day. Family Common Name, Asian Antennae ... Distribution, Primarily Asia but a handful of species in Africa. Login to ...
  11. [11]
    FAMILY Details for Bagridae - Bagrid catfishes - FishBase
    Nov 29, 2012 · Distribution includes the Nile River basin and most of west and central Africa south to the Tropic of Capricorn, including the east African ...
  12. [12]
    Mystus tengara (Bagridae) Cat-eLog - PlanetCatfish.com
    This species is easily distinguished by its small size, golden yellow color, and small adipose fin. Sexing, Males have an elongate genital papilla in front of ...Missing: coloration | Show results with:coloration
  13. [13]
    ScotCat Factsheets: December 2009: Mystus tengara (Hamilton, 1822)
    ... Bagridae family and most (but not all) can be predatory. Furnish the ... Four pairs of barbels; maxillary pair extending to base of anal fin, nasal ...
  14. [14]
    Hemibagrus variegatus (Bagridae) Cat-eLog - PlanetCatfish.com
    Jan 1, 2025 · This species is easily distinguished by its mottled color pattern and moderately long adipose fin. Sexing, Males have an elongate genital ...
  15. [15]
    [PDF] Notes on the Lancers of the genus Bagrichthys (Teleostei, Bagridae)
    Coloration amongst the members of the genus runs from tan to black, usually with some white or cream-colored markings. However, the exact coloration of any ...
  16. [16]
    [PDF] Sexual dimorphism in morphometric characters of Mystus ...
    However, other fish from Bagridae family, such as Mystus pelusius, do not show any different form of sexual dimorphism in terms of body size (Esmaeili et al.
  17. [17]
    Insights into chromosomal evolution and sex determination of ...
    Additionally, the sexual dimorphism in P. ussuriensis is extremely obvious,19 with males growing approximately three times faster and larger than females, ...
  18. [18]
    [PDF] SEXUAL DIMORPHISM IN MYSTUS VITTATUS (BLOCH.)
    Data on length at first maturity and change in colour of skin were also recorded (Bhatt,1970). MATERIAL AND METHODS. The fresh water catfish Mystus vittatus ...
  19. [19]
    Tachysurus taeniatus (Günther, 1873), a senior synonym ... - ZooKeys
    Nov 20, 2024 · Coloration polymorphism was also observed in the juveniles and sub-adults of T. taeniatus with three coloration morphs detected (Fig. 2 ) ...
  20. [20]
    https://zookeys.pensoft.net/article/135630/
  21. [21]
    FAMILY Details for Bagridae - Bagrid catfishes
    Summary of each segment:
  22. [22]
    The Catfishes of Asia Series, Part 1 • Family Bagridae - Geography
    The family Bagridae has a huge range and members of this family can be found throughout all of Asia, Africa, and the Middle East.
  23. [23]
    Catfishes of the genus Sperata (Pisces:Bagridae) in India - PubMed
    DNA barcode data of the South Asian bagrid catfish genus Sperata indicate the presence of at least five species in the Indian subcontinent.<|control11|><|separator|>
  24. [24]
    Batasio convexirostrum, a new species of catfish (Teleostei
    Aug 7, 2025 · After originating from the Chin Hills in Myanmar it flows into India and drains the south-eastern part of Mizoram before draining finally into ...
  25. [25]
    Fish diversity and selection of taxa for conservation in the Salween ...
    Jan 29, 2024 · The Salween forms the Myanmar-Thailand border across the ... West Asia, South Asia, Southeast Asia, and East Asia distribution pattern.
  26. [26]
    Bagrus bajad (Bagridae) Cat-eLog - PlanetCatfish.com
    Aug 30, 2003 · Distribution ; Africa: Nile River, Lake Chad, Niger and Sénégal River, Lakes Mobutu (Lake Albert) and Turkana. Reported from Sanaga River basin.
  27. [27]
    https://www.planetcatfish.com/bagrus_bajad
  28. [28]
    Life‐history traits of a tropical bagrid catfish, Mystus mysticetus ...
    Jul 9, 2023 · 1. INTRODUCTION ... The Mystus is of genera of the family Bagridae, a family of fish native to Africa and Asia (Berg, 1858), with about 21 genera ...
  29. [29]
    Effect of Temperature, pH, Salinity and Dissolved Oxygen on Fishes
    Nov 1, 2023 · Environmental factors, including temperature, pH, salinity, and dissolved oxygen, are paramount in shaping fish physiology, behavior, and survival.Missing: Bagridae | Show results with:Bagridae<|separator|>
  30. [30]
    https://www.researchgate.net/publication/375919681_Effect_of_Temperature_pH_Salinity_and_Dissolved_Oxygen_on_Fishes
  31. [31]
    The influence of habitat on the spatial variation in fish assemblage ...
    Aug 5, 2025 · Regarding the microhabitat, hydromorphological parameters (depth and current velocity) followed by temperature, turbidity and total dissolve ...
  32. [32]
    Hemibagrus wyckioides - Facts, Diet, Habitat & Pictures on Animalia ...
    Hemibagrus wyckioides occurs in large upland rivers, and is common in areas with rocky bottoms and irregular depths. These fish do not migrate, but they ...
  33. [33]
    Egg Development of the Ussurian Bullhead Fish, Leiocassis ... - NIH
    This study was examined the ovogenesis of Ussurian bullhead, Leiocassis ussuriensis and the morphological development of its larvae and juveniles and to use ...
  34. [34]
    Ultrastructure of the Fertilized Egg Envelope from Pseudobagrus ...
    The fertilized egg was compressed spherical, light-yellowish, demersal, and adhesive. The size of fertilized egg is about 1.85±0.13 ...Missing: oviparous | Show results with:oviparous
  35. [35]
    (PDF) Morphology, Length–Weight Relationship, Biology and ...
    ... breeding programme. The species breeds in monsoon season, June-August. The fecundity was found to be 10,000-13,000 per 90-130 g brooder. The fertilization ...
  36. [36]
    Bagridae) in the Mathabhanga River, Southwestern Bangladesh
    Aug 7, 2025 · Their peak breeding season occurs usually in the monsoon season (May to August and breeding could be extended till the month of September) ...
  37. [37]
    Reproductive biology and condition factor of the catfish Bagrus ...
    Aug 5, 2025 · During the breeding season, mature individuals migrate from deep to shallow waters to find suitable spawning grounds (Anja et al., 2009) . Like ...
  38. [38]
    None
    ### Reproduction Aspects for Sperata seenghala
  39. [39]
    The interactive effects of paternal size and offspring feeding strategy ...
    Mar 3, 2020 · The present study revealed significant paternal size effects on offspring fitness; that is, larger males sired offspring showed significantly ...
  40. [40]
    Observations on the larval development of Mystus macvopterus ...
    Aug 7, 2025 · Twelve days after hatching, at 18.4 mm t.l., the yolk sac disappeared, organogenesis was almost complete and the juvenile period began. At ...
  41. [41]
    [PDF] FOOD AND FEEDING HABITS OF BAY AD FISH BAGRUS BAJAD ...
    The maximum feeding intensity was in spring, while the lowest was in winter. Seasonal variation in the diet composition of B bajed revealed that fish prey was ...
  42. [42]
    Feeding Ecology with Prey Electivity and Growth Performance of ...
    M. vittatus is an omnivorous small bagrid and it mostly preferred food as Copepods, Bacillariophyceae, Fish parts and larvae, Insect parts and larvae and ...
  43. [43]
    Bagridae - an overview | ScienceDirect Topics
    Bagridae refers to a family of catfishes within the suborder Siluroidei, primarily found in Africa and Asia, which are characterized by their adaptation to ...
  44. [44]
    Barbel Taste System in Catfish and Goatfish | 14 | Fish Chemosenses |
    The barbels are densely supplied with taste buds and the sensory input from them plays an essential role in the initial stages of feeding behavior such as food ...<|control11|><|separator|>
  45. [45]
    [PDF] Growth Performance, Feeding Ecology and Prey Preference of ...
    Feb 14, 2017 · Changes in feeding habits of a fish species are a function of the interactions among several environmental factors that influence the ...
  46. [46]
    Food and feeding habits of the catfish, Bagrus docmak (Forsskal ...
    Aug 5, 2025 · The diet composition, ontogenetic dietary shifts and reproduction of the tigerfish Hydrocynus forskahlii (Cuvier, 1819) were studied from ...
  47. [47]
    Mahseer - Wikipedia
    Like other types of carps, they are omnivorous, eating not only algae, crustaceans, insects, frogs, and other fish, but also fruits that fall from trees ...
  48. [48]
    predator-prey relationship in lake victoria with special reference to ...
    The principal predatory fishes are Lates niloticus, Bagrus docmac, Clarias mossambicus, Schilbe mystus and some species of Haplochromis (sensu lato). Other ...
  49. [49]
    All About Otters - Diet & Eating Habits | United Parks & Resorts
    Cape clawless and Asian small-clawed otters feed mainly on crabs and other crustaceans, molluscs, and frogs. Fish are relatively insignificant in their diets.Missing: bagrid | Show results with:bagrid
  50. [50]
    [PDF] A preliminary study of the defensive spines of some Malayan ...
    Denticle-bearing spines occur in the catfishes (Order-Nematognathi). Those having denticles on one face occur in the Bagridae, Siluridae,. Sisoridae, and ...
  51. [51]
    Giraffes, Lancers, and Just Bagrid Catfishes, the Family Bagridae
    Most are small, but there are a few giants here (Chrysichthys grandis of Lake Tanganyika attains a length of 2 meters). Physical characteristics are variable ...
  52. [52]
    Diel Activity and Feeding Habitat of Pseudobagrus brevicorpus (Pisces
    Aug 6, 2025 · Foraging, in P. brevicorpus, occurs primarily at night, and most nocturnal movements, aside from during spawning, are believed to be related ...
  53. [53]
    Impacts on Fishing and Adaptation Strategies in Volta Basin
    ... Bagridae, among others, are very sensitive species to organic pollution. Indeed, the first rains are likely to drain household waste such as very basic ...
  54. [54]
    Threatened fishes of the world: Pseudobagrus medianalis (Regan ...
    Feb 6, 2007 · Conservation status: Pseudobagrus medianalis is one of the endangered fishes in Lake Dianchi (24°28′–25°28′ N, 102°30′–103°00′ E, 1,886 m above ...
  55. [55]
    WoRMS - World Register of Marine Species - Bagridae Bleeker, 1858
    ### Classification History of Bagridae
  56. [56]
    https://www.alr-journal.org/articles/alr/pdf/1996/05/alr96hs01.pdf
  57. [57]
    Taxonomy, phylogeny and biogeography of catfishes \(Ostariophysi ...
    An overview is given of our prcsent knowledge on taxonomy, phylogeny and biogcography of catfishes or Siluroidei, one of thc worlds economically important ...
  58. [58]
    [PDF] 205 REVISION OF THE ASIAN CATFISH GENUS HEMIBAGRUS ...
    The Old World catfish family Bagridae, commonly found throughout fresh- and brackish-water bodies in Asia and. Africa, includes more than 200 species in 17 ...<|control11|><|separator|>
  59. [59]
    Complete mitochondrial genomes of two catfishes (Siluriformes ...
    Jul 29, 2022 · In the past two decades, molecular phylogenetic studies showed that Bagridae is monophyletic, with only Rita excluded (Sullivan et al. 2006; Vu ...
  60. [60]
    A Time-Calibrated Mitogenome Phylogeny of Catfish (Teleostei
    Dec 1, 2016 · The divergence of Siluroidei most likely postdated the final separation of Africa and South America. ... Bagridae, Horabagridae, Akysidae ...
  61. [61]
    Profiling Genetic Breeding Progress in Bagrid Catfishes - MDPI
    This review highlights progress in the research on the breeding conditions, genetic background, stress resistance, metabolic nutrition, and heterosis of hybrid ...Missing: round | Show results with:round
  62. [62]
    New phylogenetic insights into the African catfish families ...
    Mar 9, 2022 · The order Siluriformes (Superorder: Ostariophysi; Series: Otophysi), commonly known as catfishes, represents one of the most diverse vertebrate ...
  63. [63]
    CAS - Eschmeyer's Catalog of Fishes - Genera/Species by Family/Subfamily
    - **Number of Genera and Species for Bagridae Family:**
  64. [64]
    https://www.fishbase.se/identification/SpeciesList.php?genus=Mystus
  65. [65]
    https://mapress.com/zt/article/view/zootaxa.5099.3.2
  66. [66]
    Fish Identification: Find Species - FishBase
    Class: Teleostei Order: Siluriformes Family: Bagridae Bagrid catfishes. Genus: Leiocassis (See list of species below) ; No picture found. Max. Length 17.9 cm SL.
  67. [67]
    https://www.fishbase.se/summary/speciessummary.php?id=5137
  68. [68]
    Mystus cyrusi , a new species of bagrid catfish (Teleostei
    Feb 14, 2022 · Roberts, T.R. (1994) Systematic revision of Asian bagrid catfishes of the genus Mystus sensu stricto, with a new species from Thailand and ...
  69. [69]
    Threatened fishes of the world: Horabagrus brachysoma (Gunther ...
    Aug 9, 2025 · brachysoma has sharply declined due to over fishing, habitat loss, pollution and anthropogenic pressures (Sreeraj et al., 2006; Anvar Ali et al.
  70. [70]
    Mystus vittatus, Striped dwarf catfish : fisheries, aquarium - FishBase
    Usually found among marginal vegetation in lakes and swamps with a mud substrate. Feed on plants, shrimps, insects, mollusks and fish.
  71. [71]
    Threats of dams to the persistence of the world's freshwater fishes
    Feb 1, 2024 · Habitat fragmentation due to dams is a well-known threat to freshwater fish. Yet, the global consequences of fragmentation for the viability ...
  72. [72]
    ScotCat Factsheets: January 2025: Bagrus docmak (Fabricius, 1775)
    The above image from Lake Chad shows the size of this species when in adulthood. The African branch of Bagridae sports 8-11 soft rays in the dorsal fin whereas ...Missing: taxonomy | Show results with:taxonomy
  73. [73]
    Checklist on the ichthyofaunal resources and conservation status of
    Feb 26, 2025 · IUCN population status data shows that 57.1% are unknown, 10.7% stable, 10.7% not accessed, and 21.4% with decreasing population trends.
  74. [74]
    Hemibagrus punctatus - Wikipedia
    ... IUCN categorizes the species as critically endangered (possibly extinct). It is threatened by habitat degradation by excess siltation, excess fishing, and ...
  75. [75]
    Critically Endangered Hemibagrus punctatus Jerdon (1849) and ...
    Aug 6, 2025 · The IUCN classifies two-endemic fishes of the Western Ghats in Peninsular India: Nilgiri mystus Hemibagrus punctatus is critically endangered, ...<|separator|>
  76. [76]
    Nilgiri Mystus - GKToday
    Conservation and Management Measures. Efforts to protect the Nilgiri Mystus should focus on habitat conservation and sustainable freshwater resource management.
  77. [77]
    Wildlife Protection Law of the PRC (2022 Version)
    Article 1: This Law is formulated so as to protect wildlife, to rescue rare and endangered wildlife, to preserve biodiversity and ecological balance, to advance ...Missing: Bagridae India
  78. [78]
    A review of conservation status of freshwater fish diversity in China
    Nov 5, 2023 · Among Chinese freshwater fishes assessed, there are 355 at-risk species (22.3% of the total), including 69 ranked as Critically Endangered, 97 ...
  79. [79]
    IUCN Red List of Threatened Species
    The IUCN Red List Categories and Criteria are intended to be an easily and widely understood system for classifying species at high risk of global extinction.About · 3.1 · IUCN Species Information... · Iconic SpeciesMissing: Bagridae | Show results with:Bagridae
  80. [80]
    (PDF) Threatened Fishes: Mystus vittatus (Bloch, 1794)
    Aug 10, 2025 · This paper suggests the measures for the conservation of the remnant isolated population of M. vittatus in the waters of Asian countries.
  81. [81]
    Giant catfish conservation in the Mekong - WWF
    This WWF initiative aims to conserve the species and other large migrating fish through a regional management plan and conservation of catfish spawning sites in ...
  82. [82]
    Genetic diversity and population structure of Hemibagrus guttatus ...
    Jan 23, 2021 · guttatus population declined sharply due to over-fishing, water pollution, and hydraulic constructions and led to a degradation of their ...
  83. [83]
    [PDF] Impacts of community based fisheries management (CBFM) on the ...
    Mar 13, 2016 · In conclusion, the overall findings showed that community based fisheries management has significantly increased annual fish production, lifted ...
  84. [84]
    Establishment of a fish sanctuary for conserving indigenous ... - NIH
    Establishment of a fish sanctuary for conserving indigenous fishes in the largest freshwater swamp forest of Bangladesh: A community-based management approach.
  85. [85]
    [PDF] Monitoring biodiversity after oil spill remediation in the Niger Delta
    From across 14 families, 41 species were identified, with the Mochokidae, Cichlidae,. Claridae, Cyprinidae, and Bagridae families being the most represented.
  86. [86]
    New report reveals one in four freshwater fish species ... - WWF Africa
    Jul 9, 2025 · The report, titled “Africa’s Forgotten Fishes,” reveals that 26% of Africa’s assessed freshwater fish species are threatened with extinction.Missing: Bagridae reserves