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Bullet tuna
Bullet tuna
Bullet tuna
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Bullet tuna
Scientific classification Edit this classification
Kingdom: Animalia
Phylum: Chordata
Class: Actinopterygii
Order: Scombriformes
Family: Scombridae
Genus: Auxis
Species:
A. rochei
Binomial name
Auxis rochei
(Risso, 1810)
Synonyms[2]
  • Scomber rochei Risso, 1810
  • Scomber bisus Rafinesque, 1810
  • Auxis bisus (Rafinesque, 1810)
  • Thynnus rocheanus Risso, 1827
  • Thunnus rocheanus (Risso, 1827)
  • Auxis vulgaris Cuvier, 1832
  • Auxis thynnoides Bleeker, 1855
  • Auxis ramsayi Castelnau, 1879
  • Auxis maru Kishinouye, 1915

The bullet tuna (Auxis rochei) is a species of tuna, in the family Scombridae, found circumglobally in tropical oceans, including the Mediterranean Sea,[2] in open surface waters to depths of 50 m (164 ft). The population of bullet tuna in the Eastern Pacific was classified as a subspecies of A. rochei, A. rochei eudorax, but some authorities regard this as a valid species Auxis eudorax.[3] Its maximum length is 50 centimetres (20 in).

Sometimes called bullet mackerel, the bullet tuna is a comparatively small and slender tuna. It has a triangular first dorsal fin, widely separated from the second dorsal fin, which, like the anal and pectoral fins, is relatively small. There are the usual finlets of the tuna. There is a small corselet of small scales around the pectoral region of the body.

Bullet tunas are blue-black on the back with a pattern of zig-zag dark markings on the upper hind body, and silver below. The fins are dark grey.

They feed on small fish, squid, planktonic crustaceans, and stomatopod larvae.

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Bullet tuna

View on Grokipedia
from Grokipedia
The bullet tuna (Auxis rochei) is a small, epipelagic of in the family , characterized by its streamlined, bullet-shaped body and circumglobal distribution in tropical and subtropical marine waters, including the Atlantic, Indian, and Pacific Oceans as well as the . Reaching a maximum fork length of 50 cm and a lifespan of up to 5 years, it inhabits neritic and oceanic environments from the surface to depths of 200 m, often forming schools in coastal areas and around islands. As a carnivorous , it primarily feeds on small fishes such as anchovies, crustaceans, and other pelagic prey, contributing to its role in marine food webs. Bullet tuna exhibits regional variations in spawning, typically occurring in coastal subtropical and tropical zones with ranging from approximately 85,000 to 134,000 eggs per , and first maturity achieved at around 35 cm in length. Its populations are found on both sides of the Atlantic, including the and , with distinct recognized in the eastern Pacific (A. r. eudorax). Economically significant in small pelagic fisheries, bullet tuna supports commercial catches via purse seines and other methods, particularly in regions like , the Mediterranean, and , where it provides a vital protein source and generates substantial revenue for coastal communities. Additionally, it is targeted as a gamefish in recreational due to its schooling behavior and fighting qualities. It is classified as Least Concern on the as of 2022.

Taxonomy and description

Taxonomy

The bullet tuna is classified under the binomial name Auxis rochei (Risso, 1810), originally described from Mediterranean specimens as Scomber rochei by Giuseppe Risso in his 1810 work Ichthyologie de Nice. Earlier nomenclature included synonyms such as Auxis vulgaris (Cuvier, 1831), Auxis bisus (Bonaparte, 1845), and Auxis thynnoides (Bleeker, 1855), reflecting historical taxonomic revisions within the family. For much of the 19th and early 20th centuries, A. rochei was often conflated with the closely related (Auxis thazard), leading to widespread use of the latter name for both species in a presumed single cosmopolitan . The full taxonomic hierarchy of the bullet tuna is as follows:
RankClassification
KingdomAnimalia
PhylumChordata
Class
OrderScombriformes
Family
SubfamilyScombrinae
GenusAuxis
SpeciesA. rochei
Two subspecies are recognized: the nominotypical Auxis rochei rochei, which inhabits tropical and subtropical waters globally except the eastern Pacific, and Auxis rochei eudorax (Temminck & Schlegel, 1844), restricted to the eastern Pacific, though the latter's status as a distinct subspecies rather than a full species remains debated in some ichthyological assessments. Phylogenetically, A. rochei belongs to the tribe Thunnini (true tunas) within the subfamily Scombrinae, representing one of the smaller members of this group alongside genera like Thunnus and Katsuwonus. It is distinguished from the sympatric frigate tuna (A. thazard) primarily by morphological traits, including a wider posterior corselet spanning 6-19 scales (usually 7-15; versus 1-5 scales) under the origin of the second dorsal fin, and corroborated genetic divergences in mitochondrial DNA sequences such as COI and D-loop regions.

Physical characteristics

The bullet tuna (Auxis rochei) possesses a robust, elongate body that is with an oval cross-section, adapted for fast in pelagic environments. It reaches a maximum fork of 50 cm, with common lengths around 35-40 cm, and a maximum weight of approximately 1.8 kg. The body is largely naked except for a well-developed corselet of scales extending from the pectoral region, and it features two small keels on each side of the caudal peduncle flanking a larger median keel. There is no , and the teeth are small and conical, arranged in a single series. The fins include a first dorsal fin with 9-12 spines, triangular in shape and separated from the second dorsal fin, which has 10-13 soft rays followed by 6-7 dorsal finlets. The anal fin lacks spines and has 12-14 soft rays, also followed by 6-7 finlets. Pectoral fins are short, typically under 18 cm in adults, with 22-25 rays, and do not reach the scaleless area above the corselet; the pelvic fins feature a single, short, pointed interpelvic flap. Gill rakers number 38-47 on the first arch. Coloration consists of a bluish back with iridescent hues, a deep to head, and a silver-white belly lacking spots or stripes. The scaleless body area above the displays 15 or more dark, oblique or wavy vertical bars or lines. Pectoral and pelvic fins are with inner edges, while the eye has a patch at its postero-ventral border. No pronounced is observed in bullet tuna. Individuals reach at around 35 cm fork length. The maximum reported age is 5 years, with most individuals aged 2-3 years in fished populations. Growth exhibits medium resilience, with a population doubling time of 1.4-4.4 years.

Distribution and habitat

Geographic range

The bullet tuna (Auxis rochei) has a circumglobal distribution in tropical and subtropical waters of the Atlantic, Indian, and Pacific Oceans, including the . Its latitudinal range extends from 61°N to 51°S, with a longitudinal span from 180°W to 180°E. The is particularly abundant in coastal waters of the region, the eastern Atlantic off the African coast, and around oceanic islands. A , A. r. eudorax, is restricted to the eastern . Designated as a highly migratory (HMS) by the FAO, the bullet tuna exhibits oceanodromous movements that follow warm ocean currents, though these are shorter-range compared to those of larger tunas like bluefin. Its presence in the dates to the early 19th century, with no significant range shifts documented in available records.

Habitat preferences

The bullet tuna (Auxis rochei) is a pelagic-neritic that primarily inhabits the open surface waters of tropical and subtropical oceans, extending from the epipelagic zone down to depths of 200 m, though it is most commonly found in the upper 10 m of the . It occasionally ventures into brackish waters near estuaries, reflecting its tolerance for varying conditions. This species thrives in warm waters with temperatures ranging from 13.6°C to 29°C, averaging 26°C, and prefers oligotrophic marine environments characterized by salinities of 32–35 ppt. It avoids cold zones, favoring stable, nutrient-poor tropical conditions across its global range. Bullet tuna often form schools associated with coastal structures such as islands and reefs, as well as floating debris, with adults showing a stronger coastal orientation compared to more oceanic juveniles. Seasonally, populations move closer to shore during the spawning period, which aligns with warmer months in subtropical regions, enhancing their proximity to neritic habitats.

Biology and ecology

Behavior and migration

Bullet tuna (Auxis rochei) exhibit strong schooling behavior, forming large, fast-moving aggregations typically composed of similarly sized individuals. These schools are often surface-oriented and can mix with other small pelagic species, such as (Auxis thazard) and (Euthynnus affinis), facilitating coordinated movement in epipelagic waters. School size and composition vary by region, with observations in the Mediterranean and Pacific indicating orderly vertical stratification within schools, where smaller juveniles occupy near-surface layers and larger adults position in mid-depths. Daily activity patterns in bullet tuna include heightened surface activity during mornings, evenings, and conditions, when schools are more responsive to methods like trolling. Evidence suggests possible diurnal vertical migrations, with juveniles showing increased vulnerability to midwater trawls at night, potentially due to deeper positioning or reduced avoidance behavior in low light. Seasonally, schools approach coastal surfaces in summer for but shift to deeper offshore waters in winter, aligning with warm water associations (preferred temperatures 13.6–29°C). Bullet tuna serve as key prey for larger predators, including tunas, pelagic sharks, billfishes, and dolphinfish (Coryphaena hippurus), contributing to their role in marine food webs without notable aggressive interactions among conspecifics. Migration in bullet tuna is characterized by short-distance oceanodromous patterns, with individuals following seasonal currents for rather than long-range displacements seen in larger tunas. In the Atlantic-Mediterranean system, populations show massive nearshore movements from the Atlantic through the into Mediterranean spawning areas, followed by returns, alongside local migrations around neritic habitats. Genetic studies reveal distinct stocks, such as those along the –Strait of Gibraltar and North African coasts, shaped by larval retention and homing behavior that limits extensive mixing. In the western Pacific, tagging data indicate northward migrations in early year and southward shifts from August to November, often preceding larger individuals.

Diet and feeding

The bullet tuna (Auxis rochei) is primarily an opportunistic that preys on small pelagic fishes such as clupeids (e.g., Sardinella aurita and Amblygaster sirm), crustaceans including copepods, shrimps, crabs, and euphausiaceans, cephalopods like small squids (Heteroteuthis dispar), and planktonic organisms such as appendicularians and amphipods. content analyses across various regions indicate that fishes dominate the diet by weight and index of relative importance (IRI), often comprising 39–80% of the prey, while crustaceans contribute 17–25%, reflecting availability in epipelagic waters. As a mid-level with a of approximately 4.1, the bullet tuna employs a generalized feeding strategy, targeting abundant resources in offshore environments and relying on continuous for ram ventilation to support active predation. This obligate ram ventilation, facilitated by adaptations common to scombrids, allows efficient oxygen uptake during high-speed without pausing to over the s. Studies show seasonal and regional variations, with teleosts peaking in winter diets and crustaceans more prominent in autumn, underscoring its non-selective, availability-driven habits. Recent stomach content analysis (2024) in Sri Lankan waters confirms dominance of small fishes and crustaceans in the diet. Ontogenetic shifts in diet are evident, with juveniles and smaller individuals (≤33 cm fork length) consuming more planktonic and crustaceans—such as copepods and shrimps, which can comprise up to 58% IRI—while adults shift toward schooling fishes, increasing consumption to over 80% IRI as body size grows. Larval stages (2–7 mm standard length) further emphasize this progression, starting with nauplii and cladocerans before favoring larger appendicularians and fish larvae around 5 mm. Foraging involves high-speed pursuits of prey schools, often in mixed-species aggregations that facilitate access to dense groups, with daily consumption estimated at levels supporting rapid growth. This behavior positions the bullet tuna as an important mid-trophic predator in pelagic food webs.

Reproduction and life cycle

The bullet tuna (Auxis rochei) is a multiple spawner exhibiting asynchronous oocyte development, allowing for several spawning events within a single reproductive season. Spawning seasons vary by region, occurring year-round in tropical waters such as the with peaks from July to September, while in temperate areas like the Mediterranean, it is concentrated in summer from June to September. Recent surveys (2024) have identified the in the northeastern Atlantic as an additional spawning area. Unlike many larger species that spawn in open oceanic waters, bullet tuna reproduction takes place closer to coastal areas, often near traps or inshore zones. shows regional variation, e.g., 31,000 to 103,000 eggs per spawning female in the , scaling with body size (higher ranges reported in the Mediterranean). The eggs are pelagic, released into surface waters where they float and develop. Upon hatching after approximately 2-3 days under typical tropical temperatures, the larvae remain planktonic and pelagic, undergoing rapid ontogenetic development including preflexion, flexion, and postflexion stages within the first few weeks; the larval period is short. Sexual maturity is typically reached at a fork length of around 35 cm, corresponding to 1-2 years of age, with batch spawning facilitating repeated releases over the season. The maximum lifespan is up to 5 years, as determined from age-growth studies in Mediterranean populations. The life cycle progresses from pelagic eggs to planktonic larvae, which metamorphose into juveniles around 10 cm fork length where schooling behavior begins in surface waters. Juveniles grow into adults by approximately 25 cm, at which point they engage in full migratory patterns across epipelagic habitats.

Fisheries and human use

Commercial fishing

The bullet tuna (Auxis rochei) supports a substantial commercial , with global annual landings ranging from approximately 30,000 to 50,000 tonnes for the years 2017–2020 according to FAO capture production statistics. These figures reflect the species' widespread exploitation in tropical and subtropical waters, where it is targeted for its abundance in surface schools. Major producing countries include and in the region, as well as Mediterranean nations such as , , and . In , average annual catches along the coast from 2006 to 2013 totaled about 2,637 tonnes, primarily from artisanal operations. In the , and have been the leading reporters of landings, with regional totals reaching around 5,000 tonnes in 2011. Algerian landings alone increased from 391 tonnes in 2004 to 732 tonnes in 2020. Commercial fishing methods for bullet tuna emphasize surface-oriented techniques suited to its epipelagic habits, including encircling nets such as purse seines, which capture schooling in open waters. Troll lines and pole-and-line gear are also employed, particularly in artisanal fleets, while the species frequently appears as in purse seine and longline operations targeting larger tunas like skipjack and yellowfin. In coastal areas, surface-set gillnets are a key gear, deployed to intercept seasonal schools during migrations; for instance, in Indonesian waters like the , gillnets and handlines dominate local catches. Targeting intensifies during peak schooling periods, often linked to warmer months in subtropical zones. Economically, bullet tuna contributes to regional fisheries through its dual role as bait for larger pelagic species and as a direct food source, with low unit prices (under US$1 per kg) supporting high-volume trade. In Asia, particularly Indonesia and India, it is canned for local and export markets, with production values reflecting its importance to coastal communities; for example, single-day catches at Indonesian ports like Prigi have exceeded 500 tonnes, generating significant revenue. Trade volumes in the region have risen with expanding artisanal and semi-industrial fleets, underscoring the species' growing role in food security and export earnings.

Culinary and other uses

Bullet tuna possesses a mildly tangy flavor with subtle , which is less intense than that of but more flavorful than many other small pelagic species. Its firm yet tender flesh offers a milder profile compared to larger varieties, making it versatile for various preparations. In culinary applications, bullet tuna is commonly grilled, pan-seared, or broiled, particularly in Mediterranean cuisines where its mild taste pairs well with and herbs. It is also widely canned in as fillets, prized for its pinkish color, firm texture, and distinctive flavor in Spanish and Italian markets. Traditional methods include salting and for preservation, as well as incorporation into soups and salads across tropical regions. Nutritionally, bullet tuna is high in protein, providing 20-25% by weight in muscle tissue, which supports muscle growth and repair. It is rich in omega-3 fatty acids, contributing to heart health, while maintaining low fat content under 2%. Compared to larger tunas, it has lower mercury levels, typically around 0.46 mg/kg or less, making it a safer choice for frequent consumption. Beyond food uses, bullet tuna serves as effective bait for larger gamefish due to its high oil content and durability when cut into strips or used whole. It is occasionally processed into fishmeal for feeds, leveraging its protein-rich byproducts. Aquaculture production of bullet tuna itself remains limited, primarily due to its small adult size despite rapid growth rates.

Conservation

Status and population

The bullet tuna (Auxis rochei) is classified as Least Concern on the , with the global assessment conducted in 2022. This status reflects its extensive circumglobal distribution across tropical and subtropical waters, combined with high fecundity (31,000–103,000 eggs per spawning event), which contribute to stable overall populations despite localized fishing pressures. No evidence of widespread population declines has been documented, and the species' broad range buffers against regional vulnerabilities. Global population trends indicate no major declines, with abundance remaining high in tropical regions where the species predominates. In the Atlantic, International Commission for the Conservation of Atlantic Tunas (ICCAT) data show relatively stable catch levels over recent decades (averaging around 900 metric tons annually from 1981–2015, dropping modestly to 612 metric tons from 2016–2019), without signs of in key areas. Recent studies as of 2023 highlight ongoing concerns of high exploitation in areas like Indonesian waters, though no updated global catch data beyond 2019 is available. Limited estimates from regional stock assessments, such as those in the eastern Atlantic, suggest sustainable levels, though quantitative modeling remains constrained by data gaps. As a highly migratory species, the bullet tuna is tracked internationally under frameworks like the Convention on the Law of the Sea (UNCLOS) and regional bodies including ICCAT. Monitoring efforts focus on catch statistics, size distributions, and larval surveys, revealing regional variations such as stable stocks in the . The species demonstrates medium resilience to exploitation, with a minimum population doubling time of 1.4–4.4 years based on growth parameters (von Bertalanffy growth coefficient K = 0.32, age at maturity ≈2 years). This allows for relatively rapid recovery from moderate fishing intensities, supporting its overall population stability.

Threats and management

Bullet tuna populations face several primary threats, primarily from human activities in marine fisheries and environmental changes. As a common bycatch species in industrial tuna purse seine and longline fisheries targeting larger tunas, bullet tuna often suffers incidental capture and mortality, particularly in the Atlantic and Indian Oceans, where it constitutes a notable portion of non-target catches. Localized overexploitation in coastal stocks, such as those in the Indian Ocean off Indonesia, has led to concerns over immature individuals dominating catches and fluctuating production levels due to excessive fishing pressure, with studies as of 2023 indicating high fishing intensity. Habitat degradation from ocean pollution, including microplastic ingestion through opportunistic feeding—as documented in bullet tuna samples from Indonesian waters—further compounds these risks for this epipelagic species. Climate change poses additional challenges, with ocean warming driving potential range shifts that could alter suitable habitats for bullet tuna across tropical and subtropical waters. Ocean acidification, resulting from increased CO₂ absorption, may impair larval development by affecting formation critical for orientation and survival, as observed in related tuna species. These combined effects could lead to range contraction in some regions, exacerbating vulnerability in already pressured stocks. Management of bullet tuna occurs primarily through Regional Fisheries Management Organizations (RFMOs), such as the International Commission for the Conservation of Atlantic Tunas (ICCAT) and the Tuna Commission (IOTC), which oversee reporting of landings and promote ecosystem-based approaches for associated species. In the Mediterranean, landings are monitored via ICCAT databases, with some national quotas applied under regulations to control small pelagic fisheries, though no global bans exist for bullet tuna. Sustainable practices, particularly in purse-seine operations, are emphasized to minimize through measures like regulations and improved gear selectivity. Despite its classification as Least Concern by the , research gaps persist, notably the lack of quantitative stock assessments in the , hindering precise management. Recent studies highlight the need for updated impact data to inform adaptive strategies.

References

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