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Larimichthys crocea

Larimichthys crocea, commonly known as the large yellow croaker, is a ray-finned belonging to the , characterized by a body that appears golden when fresh, with fins supported by 9–10 spines and 30–35 soft rays, and anal fins with 2 spines and 7–9 soft rays. This species attains a maximum total length of 80 cm and a maximum reported weight of about 4 kg (historical), though typical market-sized individuals measure around 30–40 cm and weigh 0.5–1 kg due to intensive fishing pressures. It is distinguished by scales covering most of the soft-rayed portions of the dorsal and anal fins, and the posterior part of the pectoral fin lacks black pigmentation. Native to the northwest , L. crocea is distributed along coastal regions from northward to and , primarily in the , , and northern , spanning latitudes 13°N to 38°N and longitudes 106°E to 141°E. The species inhabits temperate coastal waters, estuaries, and brackish environments, preferring muddy or muddy-sandy bottoms at depths ranging from 0 to 120 m, though it is most common between 10 and 80 m. It exhibits seasonal migrations, moving from spawning and nursery grounds in nearshore areas to deeper offshore waters during non-reproductive periods. Ecologically, L. crocea is benthopelagic and carnivorous, preying mainly on crustaceans and small fishes, with juveniles showing ontogenetic shifts in diet from to benthic . is reached at lengths of 17 cm or more, typically around 1–2 years of age, with spawning occurring in coastal waters during and summer. The species can live up to 6 years in the wild, though has drastically reduced average lifespans and sizes in remaining populations. Of significant economic value in , L. crocea supports major commercial fisheries and is the most cultured marine fish in , with aquaculture production exceeding wild catches since the to meet demand for its nutritious flesh rich in proteins and omega-3 fatty acids. However, wild populations have declined by over 80% since the 1970s due to , habitat degradation from coastal development, and , leading to its classification as on the in 2020. Conservation efforts include fishery regulations, stock enhancement through hatchery releases, and ongoing research into and habitat restoration to support recovery.

Classification

Taxonomy

Larimichthys crocea is classified within the following taxonomic hierarchy: Kingdom Animalia, Phylum Chordata, Class Actinopterygii, Order Perciformes (sometimes classified in Acanthuriformes or Eupercaria incertae sedis following recent revisions; formerly placed in Perciformes), Family Sciaenidae, Genus Larimichthys, and Species L. crocea. The species was originally described by John Richardson in 1846 as Sciaena crocea, based on specimens from the coastal waters of and , establishing it as the for subsequent placements. Historically, it was classified as Pseudosciaena crocea, a homotypic reflecting an earlier assignment within . The Larimichthys was established in 1905 by and Edwin Chapin Starks, into which L. crocea was placed based on distinguishing morphological features. Other synonyms include Collichthys croceus and Pseudosciaena amblyceps, invalidated due to nomenclatural priority of the basionym Sciaena crocea and morphological mismatches, such as differences in fin ray counts and body proportions that align better with Larimichthys.

Etymology

The genus name Larimichthys combines Larimus, the name of a related genus in the Sciaenidae family, with the Greek ichthys meaning "fish," reflecting its close affinity to Larimus but distinguished by features such as cycloid scales on the head and body, unequal teeth, weak anal spines, and a more cavernous head structure. This nomenclature was established in 1905 by and Edwin Chapin Starks when they proposed the genus. The species epithet crocea derives from Latin, meaning "saffron-colored" or "yellowish," alluding to the saffron-yellow tint observed on the pectoral fins, lower body, sides of the head, and ventral-fin spine. L. crocea was originally described in 1846 by Scottish naturalist John Richardson as Sciaena crocea based on specimens from Chinese coastal waters, marking the initial formal recognition of the species within the family. Common names for L. crocea include "large yellow croaker" in English, emphasizing its prominent size and yellowish appearance, and dà huáng yú (大黃魚) in , translating to "large yellow ," a name that highlights its longstanding cultural and economic role in East Asian fisheries as a prized resource. Regional variations in Chinese, such as huáng huā yú (黃花魚, "yellow flower "), further underscore its traditional significance in coastal communities for food and trade.

Biology

Physical description

Larimichthys crocea possesses an elongated, body with an cross-section, facilitating efficient swimming in coastal environments. The head is large and bluntly pointed, featuring a small in an inferior , with the upper length approximately equal to the lower . The pectoral fins are notably long and can appear filamentous in structure. The body exhibits a silvery coloration overall, accented by a tint on the sides and fins, while the region appears darker, often purplish-brown above transitioning to golden below. The is divided into a spinous portion with 9–10 spines and a soft-rayed portion with 30–35 rays; the anal fin has 2 spines and 7–9 soft rays (typically 8). Soft-rayed sections of the and anal fins are largely covered with scales, and the posterior portion of the pectoral lacks black pigmentation. Juveniles display a more mottled pattern compared to adults. Internally, the is associated with sonic muscles that enable sound production, a typical of sciaenids, and also contributes to and auditory functions. Otoliths in the are utilized for age determination through analysis of growth rings. is evident, with females attaining larger sizes than males—females become heavier beyond approximately 61 mm standard length—and showing distinct differences in gonad development related to reproductive maturity. Due to , modern individuals typically reach 30–40 cm total length, though historical records indicate a maximum of up to 80 cm total length.

Reproduction and life cycle

Larimichthys crocea is a gonochoristic species with separate sexes and an overall sex ratio close to 1:1 (female:male). Females exhibit growth dimorphism, becoming heavier than males at standard lengths exceeding 61 mm. Sexual maturity is reached at sizes of 17 cm total length or more, with minimum sizes of 112 mm SL for males and 160 mm SL for females; 50% maturity occurs at 150.2 mm SL for males and 187.2 mm SL for females, typically at 2–4 years of age based on growth rates. The species is a batch spawner capable of nearly year-round reproduction in coastal waters, with two distinct peaks: (March–May for both sexes) and autumn (October–November). Spawning occurs in waters with between 18°C and 24°C, ceasing above 26°C, and is influenced by seasonal temperature increases that have shifted and extended peak periods over recent decades. Optimal for gonadal maturation and early development ranges from 25‰ to 28‰, with lower or higher levels affecting and larval survival. Eggs are pelagic and buoyant, with a of about 1.27 mm, and hatch within 25–50 hours at 23–24°C. Larval development lasts 18–25 days in the pelagic phase, transitioning to settlement around 20–30 days post-hatch, after which juveniles inhabit nursery grounds. During the larval stage, individuals engage in filter-feeding on , shifting ontogenetically to piscivory as juveniles. 50% maturity is typically reached at approximately 25 cm total length after 2–3 years in current populations, with full lifespan extending 5–7 years in modern populations (historically up to 21 years). Recent 2024 studies show modern asymptotic lengths reduced to 33.9 cm, with maximum ages up to 11 years.

Diet and feeding

_Larimichthys crocea exhibits a carnivorous diet that undergoes an ontogenetic shift from planktivory in early life stages to piscivory and benthic foraging in later stages. Larvae primarily consume zooplankton, including copepods and rotifers, through filter-feeding mechanisms adapted for capturing small particulate prey in the water column. As juveniles grow, typically transitioning around early post-larval development, their diversifies to include a mix of pelagic and benthic organisms, such as small (e.g., Engraulis sp.), decapods, polychaetes, and macrozooplankton. Adults, functioning as opportunistic mid-level carnivores, predominantly feed on bottom-dwelling like (e.g., Sicyonia sp.) and crabs, as well as small (e.g., ), with seasonal variations observed; for instance, summer diets in the emphasize decapods and over zooplankton. This shift reflects an adaptation to benthic habitats, facilitated by a protrusible that enables efficient prey capture during on or near the seafloor. The occupies a of approximately 3.7, positioning it as a secondary in webs, with dietary intake estimated at 1.2–1.5% of body weight daily in controlled settings, though wild rations may vary with prey availability. Recent stable (δ¹³C and δ¹⁵N) from 2025 studies highlights trophic variability, showing disrupted ontogenetic transitions in polluted habitats like waters—where adult δ¹⁵N values (11.72‰) are unexpectedly lower than in juveniles (12.40‰)—compared to more stable shifts in populations, where adults exhibit higher δ¹⁵N (13.63‰) indicative of increased piscivory. These findings underscore environmental influences on feeding , with juveniles displaying broader trophic niches (e.g., SEAc 0.73–0.89‰²) than adults (0.23–0.55‰²).

Ecology

Distribution

Larimichthys crocea is natively distributed in the coastal waters of , primarily spanning the , , and northern , from to southern . Its historical range extended northward up to approximately 35°N latitude in the southern , encompassing areas off , , and provinces in . Currently, the is more restricted due to , with fragmented populations concentrated in coastal regions of the . The species exhibits oceanodromous patterns, with juveniles using estuarine and nearshore nursery grounds while adults occupy offshore marine waters. Seasonal movements occur for spawning, typically from May to mid-June in inshore coastal areas, followed by northward shifts in summer for feeding before migrating southward and offshore for overwintering in depths less than 100 m during to February. These migrations connect spawning grounds in bays like Sansha Bay to broader habitats. Prior to the 1980s, L. crocea maintained a wider, more continuous range across its native waters, supporting peak annual catches exceeding 200,000 tons in 1974; however, intense led to a drastic collapse, reducing by over 90% by the 1990s and fragmenting distributions. In response, stock enhancement programs initiated around 2000 have involved annual releases of billions of hatchery-reared juveniles, particularly in and provinces, to aid recovery and reestablishment in key coastal areas. Extralimital records are limited, with rare vagrant occurrences documented in southern waters, but no established populations exist outside the native East Asian range.

Habitat and behavior

Larimichthys crocea is a demersal species inhabiting coastal waters of the and , typically at depths shallower than 120 m, with optimal conditions often between 30 and 90 m where temperatures remain stable. Juveniles occupy estuarine and nearshore environments, such as those near the River , characterized by salinities of 10–30 , while adults shift to offshore areas during overwintering. The species prefers muddy or sandy-muddy bottoms in these shallow coastal zones. This fish exhibits seasonal migrations, moving from coastal spawning and nursery grounds along the to deeper offshore overwintering sites in autumn and winter, then returning to nearshore areas in spring and summer as temperatures rise. It forms large schools during and migratory movements, a that aids in predator avoidance by enhancing vigilance and coordinated escape responses to chemical and acoustic predator signals. Diel activity patterns include vertical migrations, with upward movements peaking at and dawn, and reduced motion during nighttime hours. Sound production is a key behavioral adaptation, with individuals generating low-frequency pulsed calls via contractions of sonic muscles attached to the , primarily during spawning aggregations to facilitate communication and mate attraction. Optimal environmental conditions include sea surface temperatures of 18–25°C and salinities around 33–34 ppt, though tolerances extend to 9–30°C and lower salinities in estuarine habitats. The species avoids low-oxygen conditions, as induces physiological stress and elevated metabolic rates. Habitat degradation from and coastal development further threatens these preferences, reducing suitable areas for juveniles and adults alike. In marine food webs, L. crocea serves as prey for larger piscivores, including and , contributing to trophic dynamics in coastal ecosystems despite its declining populations.

Population genetics

Genetic diversity in wild populations of Larimichthys crocea has been notably reduced due to historical bottlenecks from , with effective population sizes (Ne) estimated to have declined sharply in recent generations, often falling within the range of approximately 1,000–5,000 individuals based on genomic analyses. Aquaculture strains often exhibit lower genetic diversity compared to wild populations due to breeding bottlenecks, as evidenced by lower observed heterozygosity ( ≈ 0.09–0.12) in some farmed groups compared to wild samples ( ≈ 0.17–0.22), though can introduce variation from multiple founder stocks; overall variability remains constrained in cultured lines. Population structure analyses using () markers have identified three primary genetic clusters corresponding to northern, central, and southern regions along the Chinese coast, including populations in the , , and areas such as Nanhai, Mindong, and Daiqu. These clusters reflect limited , exacerbated by post-overfishing isolation and geographical barriers like the , with pairwise F_ST values indicating moderate differentiation (e.g., 0.02–0.05) among lineages. Recent stability studies from 2024 demonstrate that this population structure persists despite extensive restocking efforts, with wild remaining consistent ( diversity Hd ≈ 0.78–0.99; diversity π ≈ 0.002–0.005) and minimal from released hatchery fish in most areas. In farmed groups, coefficients (F_IS) range from 0.05 to 0.15, reflecting moderate levels of relatedness due to management, though not significantly deviating from Hardy-Weinberg expectations in many cases. Conservation genetics research employing loci and (mtDNA) sequences has highlighted risks of hybridization between wild stocks and escaped farmed individuals, particularly in coastal bays like and Luoyuan, where aquaculture-derived haplotypes comprise up to 75–94% of local mtDNA variation, potentially eroding adaptive genetic integrity. Such is driven by high escape rates from farms and overlapping spawning grounds, underscoring the need for genetically distinct restocking sources to mitigate these effects. These insights suggest that genetic structure not only maintains but also modulates ecological roles across life stages, informing targeted conservation strategies amid ongoing habitat pressures.

Human use and conservation

Commercial utilization

Larimichthys crocea, commonly known as the large yellow croaker, has been a of fisheries since ancient times, with commercial exploitation peaking in the when annual wild catches exceeded 100,000 tons across the and adjacent waters. This abundance supported extensive trade and consumption, but intense led to a dramatic collapse, with catches plummeting by over 99% from 1974 levels, falling below 1,000 tons annually by the 1990s as spawning grounds were depleted and populations neared . In recent years, wild harvest of L. crocea has been strictly regulated through quota systems in to prevent further depletion. Much of the limited wild catch is processed into high-value exports, particularly dried fish maw (), which is prized in for its purported collagen-rich benefits in soups and tonics. The species commands significant market value due to demand for its protein-rich flesh, versatile used as for clarifying wines and beers, and even otoliths occasionally crafted into jewelry for their unique stone-like appearance. As of 2025, wholesale prices for premium wild-caught L. crocea range from approximately $5 to $10 per kg for frozen product, with fresh or large specimens fetching up to $20–25 per kg retail, reflecting scarcity and quality premiums over farmed alternatives. now supplies the majority of market needs, supplementing dwindling wild stocks. Culturally, L. crocea holds a prominent place in , often prepared steamed with ginger and to highlight its delicate flavor or braised in soy-based sauces for richer presentations, and it features symbolically in festivals like the as a denoting and family reunion. Byproducts from processing include extracted from viscera and muscle, valued for its high content (such as EPA and DHA) and used in nutritional supplements to support cardiovascular health.

Aquaculture

Commercial aquaculture of Larimichthys crocea, commonly known as the large yellow croaker, began in the in Province, , as part of government initiatives to propagate wild stocks and address declining natural populations through artificial breeding programs. By the , commercialization expanded rapidly, with production reaching 70,000 tonnes in 2000 from over 300,000 sea cages. As of 2023, annual output exceeded 280,000 tonnes, primarily from , which supplies over 90% of the global market for this . The primary farming method involves framed floating sea cages in coastal waters, particularly along the southeastern coast, where juveniles are often raised in earthen systems before transfer to open-sea cages for grow-out. Formulated pellet feeds, typically containing 40-45% protein, support efficient growth with feed conversion ratios ranging from 1.5 to 2.0, enabling fish to reach market size of approximately 1 kg within 1.5 years under optimal conditions. Breeding programs emphasize for enhanced growth rates and disease resistance, utilizing artificial fertilization techniques to produce high-quality seed stock in hatcheries. These efforts have established genetic improvement lines, with annual production supporting the industry's scale; recent 2025 reviews highlight morphological screening in selection to further optimize traits like vigor and uniformity. Key challenges include stress from high densities in cages, which can exacerbate outbreaks, and the escape of farmed individuals, potentially affecting wild through interbreeding. remains largely confined to , centered in , with limited global spread; exports primarily target markets in and Southeast Asian countries.

Conservation status

Larimichthys crocea is classified as on the , with the assessment conducted on 30 June 2016 under criterion A2bd, reflecting an inferred global of 80–95% over approximately three generations (about 47 years). This decline is primarily evidenced by a greater than 90% reduction in catches in the and around 80% in the northern from the mid-1970s to the late 1980s. The species faces multiple threats, including intense targeting spawning and overwintering aggregations, degradation from coastal development and , and in trawl fisheries. exacerbates these pressures by altering suitable and spawning grounds through warming waters and shifting oceanographic conditions. Poor and broader changes further compound the risks to remaining populations. Conservation efforts include seasonal fishing moratoria in Chinese waters, implemented since 1995 to prohibit fishing from May to and protect spawning periods. Large-scale restocking programs, initiated in the , have released millions of hatchery-reared juveniles to augment wild stocks, alongside protections for key spawning and nursery grounds in the . (eDNA) monitoring is increasingly used to track population distribution and abundance non-invasively. Despite these measures, wild populations show no significant recovery as of 2025, with remaining at critically low levels relative to historical abundances. Aquaculture production has played a role in alleviating pressure on wild stocks by meeting commercial demand through farmed individuals.

Research and health

Genome and genetics

The genome of Larimichthys crocea, commonly known as the large yellow croaker, has been sequenced multiple times, with the initial draft assembly published in 2015 spanning approximately 679 Mb and consisting of 25,401 protein-coding genes. Subsequent efforts improved assembly quality, including a chromosome-level reference in 2019 using PacBio long-read sequencing, which estimated the genome size at 708.47 Mb and anchored sequences to 24 pseudochromosomes. More recent assemblies, such as those from 2024 and 2025, refined the total length to around 637–712 Mb across geographical stocks, enhancing resolution for functional genomics. Key genomic features include expansions in gene families associated with auditory function, such as otoferlin, claudin j, and otolin 1, which support the species' ability to produce drumming sounds via sonic muscles attached to the , a characteristic trait in . The genome also reveals a robust immune , with over 2,500 immune-related genes, including those involved in innate immunity like Toll-like receptors and , reflecting adaptations to environmental stressors and pathogens. Repetitive elements, particularly transposable elements, constitute about 18–20% of the genome, influencing structural variation. Comparative genomics highlights syntenic conservation with other fishes, sharing orthologous gene clusters for and stress response, with the divergence of L. crocea from other species estimated at around 65 million years ago. These similarities underscore family-level evolutionary patterns in perciform fishes. Genomic resources have enabled applications like genome-wide association studies (GWAS) for growth traits, identifying loci influencing body weight and length, with estimates ranging from 0.3 to 0.6. /Cas9 editing has been successfully applied to disrupt genes like mstn for enhanced growth and potential disease resistance, achieving high editing efficiency in embryos. Recent advances include single-cell sequencing of gill tissues in 2025, revealing organ-specific expression patterns of immunity-related genes during parasitic infections, such as those responding to Cryptocaryon irritans.

Diseases and parasites

_Larimichthys crocea is susceptible to various parasitic infections, with nematodes such as Anisakis spp. commonly found encapsulated in the viscera and abdominal cavity of infected individuals. Trematodes have also been reported in Chinese marine fishes including L. crocea, contributing to parasitic burdens in wild and farmed populations. Protozoan parasites like Cryptocaryon irritans cause white spot disease, leading to severe gill and skin lesions that impair respiration and increase mortality in aquaculture settings. Other protozoans, including scuticociliates such as Miamiensis avidus, have been isolated from fatal outbreaks in farmed L. crocea, resulting in high mortality rates up to 80% during epidemic seasons. Bacterial diseases pose significant threats, particularly vibriosis caused by , which induces skin ulcerations, septicemia, and rapid tissue degradation in high-density environments. Outbreaks of V. harveyi in L. crocea can lead to mortality rates exceeding 90% in virulent strains, exacerbating losses in . Other bacteria, such as Pseudomonas plecoglossicida, contribute to visceral white nodule disease, further complicating health management. Viral infections include nervous necrosis virus (NNV), a betanodavirus that targets neural tissues and has been detected in L. crocea populations, potentially causing neurological symptoms and high juvenile mortality. infections, specifically large yellow croaker (LYCIV), result in with hemorrhages and organ failure, representing a major economic threat to with outbreak mortality often reaching substantial levels. Coinfections amplify disease severity, as seen in synparasitism between trypanosomes (Trypanosoma sp.) and myxosporeans (Ceratomyxa xiangshanensis) in L. crocea, leading to compounded physiological stress. Recent 2025 studies highlight parasite-bacteria synergies in farmed fish, where Cryptocaryon irritans infection alters gill and skin microbiota, promoting opportunistic bacterial proliferation and reducing host resistance. Single-cell RNA sequencing (scRNA-seq) analyses have revealed leukocyte heterogeneity in immune responses, identifying distinct macrophage and T-cell subsets activated during parasitic infections to modulate inflammation and pathogen clearance. Disease management strategies include against vibriosis, with recombinant vaccines targeting V. harveyi genes like lafA achieving protective efficacies around 63% in challenged L. crocea. , such as Lactiplantibacillus plantarum and Ligilactobacillus murinus, enhance growth, intestinal health, and resistance to bacterial when supplemented in feed, offering alternatives. protocols and epidemiological monitoring in culture areas help mitigate introduction, with routine parasite detection reducing overall disease incidence in monitored farms. Genomic tools for breeding resistant strains, informed by GWAS on and NNV tolerance, support long-term health improvements.

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