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Perna viridis

Perna viridis, commonly known as the Asian , is a bivalve mollusc in the family , characterized by its oval-shaped shell with a coloration, particularly around the edges, reaching lengths of up to 168 mm, though typically 80-100 mm in adults. The shell features a triangular half, a downturned , and a concave ventral margin, with juveniles displaying and hues that shift to with white or patches in adults after surface . Native to the Indo-West Pacific region, it ranges from the eastwards through the , , to the western Pacific including and , and has been introduced to areas including the (from to ), southeastern United States ( to the ), , sporadically in , established in , and in the South Atlantic (as of 2024). This species thrives in shallow subtidal and lower intertidal zones, attaching to hard substrates like rocks, wood, or shells, as well as soft sediments, using strong threads. It tolerates a wide range of 19-58 PSU and temperatures from 12-32.5°C, commonly inhabiting coastal waters, estuaries, mangroves, and reefs at depths less than 10 meters. As a suspension feeder, P. viridis primarily consumes and , filtered from the , and faces predation from crabs, fishes, and snails while competing with species such as Perna perna and Mytilus galloprovincialis. Reproduction in P. viridis involves separate sexes, with individuals reaching at less than one year and shell lengths of 15-30 mm. Spawning occurs year-round in tropical regions, often triggered by temperature optima around 29°C or drops to about 20 PSU, producing larvae that settle after 13-41 days at approximately 215 µm in size. Economically, P. viridis is cultured for human consumption in countries like , , and , valued in for its rapid growth and nutritional content. However, as an in non-native regions, it causes significant on such as power plants and ships—exemplified by impacts in —and competes with native bivalves like oysters, potentially altering habitats and contributing to through mass die-offs.

Taxonomy and description

Taxonomy

Perna viridis is classified within the kingdom Animalia, phylum , class , order Mytilida, family , genus Perna, and species P. viridis (Linnaeus, 1758). The species was originally described as Mytilus viridis by in 1758, marking its basionym within the Mytilidae family. Within the Mytilidae, the genus Perna is distinguished from related genera such as Mytilus—which includes temperate species—primarily through differences in morphology, including a smoother surface and a distinctive green periostracum in Perna, contrasted with the more ribbed, brownish-black periostracum typical of Mytilus. Genetic markers, including mitochondrial subunit I (COI) and nuclear (ITS1 and ITS2) sequences, further confirm this separation, revealing consistent phylogenetic divergence between tropical Perna lineages and temperate Mytilus clades. Historical nomenclature includes several junior synonyms, such as Mytilus smaragdinus Gmelin, 1791, Mytilus opalus Lamarck, 1819, and Chloromya viridis Dodge, 1952, all of which have been synonymized under Perna viridis based on morphological and molecular evidence. The International Commission on Zoological Nomenclature (ICZN) recognizes Perna viridis as the valid name through prevailing usage and taxonomic stability, as codified in the World Register of Marine Species (WoRMS). Phylogenetic analyses indicate an origin for the Perna, dating back to the Eocene approximately 60 million years ago, with P. viridis exhibiting regional genetic differentiation shaped by barriers like freshwater inputs in the . Molecular studies using and ITS sequences support the divergence of Perna from temperate lineages, aligning with its adaptation to tropical environments.

Physical characteristics

Perna viridis possesses an elongated, asymmetrical that is thin-walled and roughly trigonal-ovate in outline, with the anterior end swollen and pointed, the posterior end rounded and compressed, and the umbo positioned terminally and anteriorly with a sharply tapering, incurved . The exterior is covered by a thick, periostracum that is dark , often becoming brownish toward the umbo and attachment point, while the interior is nacreous and iridescent with a pale bluish or purplish tinge and a vivid green margin. The surface is nearly , featuring concentric lines and faint radial markings, with a slightly ventral margin. Typical adult shell length measures 80-100 mm, though maximum lengths reach up to 165 mm; the height-to-length ratio is approximately 0.6-0.7, contributing to its streamlined profile. The soft anatomy includes byssus threads secreted from the byssal for permanent attachment to substrates, a long and flat muscular foot enabling slow locomotion and byssus deployment, paired gills (ctenidia) modified for filter feeding via ciliary-mucus capture of particles, and edges lined with sensory papillae for environmental detection. Sexual dimorphism is minimal, with no significant differences in external size or shell traits between males and females, though gonads can be distinguished internally by color—creamy in males and to in females. Juvenile shells are smoother, more triangular in shape, and exhibit a brighter periostracum, while adults develop a darker brown periostracum with margins and more pronounced concentric growth lines indicating age and environmental history.

Habitat and distribution

Environmental preferences

Perna viridis thrives in warm tropical and subtropical waters, with an optimal temperature range of 25–30°C for growth and survival. The species exhibits broad thermal tolerance, surviving between 9–35°C under favorable conditions, though prolonged exposure below 10°C or above 35°C can be lethal. As an species, P. viridis tolerates salinities from 19–58 PSU, though it prefers full conditions around 25–35 PSU for optimal performance; it can survive in hypersaline environments up to 58 PSU. Lower salinities near 19 PSU are endured in estuarine settings, but combined with extreme temperatures, they reduce limits. The inhabits intertidal to shallow subtidal zones, typically up to 10–15 m depth, attaching via byssal threads to hard substrates such as rocks, pilings, and roots. High population densities, reaching up to 35,000 individuals per m², occur in sheltered bays where water flow is moderate and protection from wave action is provided. P. viridis favors nutrient-rich, turbid coastal waters that support its filter-feeding lifestyle, with preferred levels of 7.5–8.5 and dissolved oxygen concentrations above 4 mg/L. It can tolerate brief down to 0.5–1 mg/L through metabolic adjustments, but sustained low oxygen impairs growth. A key enabling survival in fluctuating intertidal environments is the ability to close its valves tightly during low tide exposure to prevent or during events to limit uptake. This filter-feeding anatomy also facilitates in varied salinities by selectively processing suspended particles.

Geographic range

Perna viridis is native to the Indo-West Pacific region, spanning tropical and subtropical marine and estuarine waters from the in the west to the in the east. This range includes key Southeast Asian locales such as the , , and the coastal waters of , where the species forms dense aggregations on hard substrates in intertidal and shallow subtidal zones. The green mussel has been introduced to multiple regions beyond its native distribution, primarily through human activities. In the western Atlantic, populations were first established in the and in the late 1990s, with subsequent spread to starting around 2019. Introductions to and several other Pacific islands occurred deliberately between 1972 and 1982 for purposes, though commercial operations have since ceased. In , the species became established in coastal areas from the 1960s onward, likely via shipping and . Records also exist from the eastern Pacific coasts of , where it has been reported in fouling communities. Recent expansions have been documented in the western Atlantic, with the species first recorded in southeastern (Rio de Janeiro) in 2019 and spreading southward, reaching São Paulo and southern as of 2025. In , potential establishment is under active monitoring by biosecurity authorities, with detections on arriving vessels and a 2025 finding in , , but no confirmed self-sustaining populations as of November 2025. These developments highlight ongoing risks of further spread in temperate-subtropical transition zones. Dispersal of Perna viridis is constrained by its life history, with the planktonic larval stage lasting 10-12 days, enabling natural spread over distances of approximately 100 km via ocean currents. Long-distance colonization, however, is predominantly human-mediated, facilitated by shipping vectors such as ballast water and hull fouling, which transport larvae or juveniles across ocean basins. Phylogeographic analyses of introduced populations reveal low , characterized by reduced variation and evidence of bottlenecks, consistent with effects from small propagule sizes. These patterns indicate multiple independent introductions primarily from Asian source populations, rather than stepwise expansion from a single entry point, underscoring the role of global maritime trade in facilitating invasions.

Biology and life history

Reproduction

Perna viridis exhibits gonochoristic sexuality, with separate sexes and a close to 1:1, as observed in populations from the where the ratio was 1:0.93 and not significantly different from unity. is rare, with incidences of hermaphroditism below 5% across studied populations along the west coast of . Reproduction occurs via external broadcast fertilization, where males and females synchronously release gametes into the water column. Spawning is triggered by environmental cues including temperatures exceeding 25°C and sufficient food availability, such as elevated levels. In tropical regions like the , spawning happens year-round with peaks during periods of high productivity, while in subtropical areas it is typically biannual, often aligned with warmer seasons. proceeds continuously, with sexual maturation achieved in 2-3 months, enabling rapid reproductive cycles; females release approximately 5-7 million eggs per spawning event, while males produce a comparable volume of . Following fertilization, embryonic development leads to the trochophore larval stage within 8 hours, transitioning to the veliger stage 8-12 hours later, completing this progression in 24-48 hours overall. The veliger develops into the pediveliger stage, which becomes competent for after 10-12 days at a size of 200-300 μm, at which point larvae seek suitable substrates for . Fecundity in Perna viridis is density-dependent, with higher reproductive outputs observed in controlled settings facilitated by optimized feeding and reduced stress. Post-, juveniles initiate byssal attachment to substrates, marking the transition to benthic life.

Growth and development

Juvenile Perna viridis exhibit rapid somatic growth following settlement, typically reaching shell lengths of 20-30 mm within 3-6 months under optimal conditions, driven by high rates and abundant availability. Growth during this phase follows the von Bertalanffy model, with parameters varying by location, such as an asymptotic length (L∞) of approximately 120-140 mm and growth coefficient (K) ranging from 0.1 to 1.3 per year, reflecting fast initial expansion before asymptotic slowing. As individuals transition to adulthood, growth decelerates significantly, averaging 0.1-0.2 mm per month, allowing mussels to attain sizes of 50-80 mm in 6-12 months from . This phase is characterized by increased shell thickening and tissue accumulation, with overall gains of about 80-90 mm in the first year before tapering. In the wild, P. viridis typically lives 2-3 years, though cultured individuals may reach up to 3-4 years under controlled conditions; is indicated by progressive erosion and reduced byssal attachment strength in older specimens. Reproductive maturity is generally achieved at 2-3 months and 15-30 mm length. Growth across all phases is influenced by environmental factors, notably , with optimal rates at around 28-31°C yielding up to 20% faster compared to cooler regimes. In culture, high stocking densities in cages can reduce growth by 15-20% due to competition for food and space, emphasizing the need for spacing to mimic natural dispersion.

Ecology

Feeding behavior

Perna viridis, the Asian green , is a suspension-feeding bivalve that utilizes a ciliary- system on its s to capture particulate from surrounding . Water enters through the incurrent and flows over the gill filaments, where rhythmic beating of cilia propels a mucus sheet that traps suspended particles, primarily those ranging from 4 to 20 μm in . Suitable particles are directed toward the labial palps and for and in the , while larger or inorganic particles are rejected as pseudofeces and expelled via the excurrent . This process allows for efficient selective feeding, with the mussel discriminating between nutritious and less desirable material. The diet of P. viridis consists mainly of , including diatoms such as Skeletonema costatum and Thalassiosira fluviatilis, and dinoflagellates, with opportunistic consumption of and . Filtration and clearance rates vary with mussel size, seston concentration, and particle quality, typically ranging from 1 to 10 L of per hour per individual for adults, and scaling allometrically with body size. Pumping rates can attain up to 50–100 mL/min per g dry tissue weight under optimal conditions, though these decrease exponentially with increasing or high suspension densities to prevent overload. efficiency for phytoplankton diets generally falls between 60% and 87%, depending on and nutritional value, with higher rates observed for flagellates and dinoflagellates compared to diatoms. Optimal feeding requires chlorophyll-a concentrations of approximately 0.7–17 μg/L, supporting maximal ingestion and growth rates. Through this diet, P. viridis bioaccumulates and toxins, such as and paralytic shellfish poisons, from contaminated particles, with dietary uptake often exceeding aqueous sources due to the high volume of filtered water. Behavioral adaptations include reduced pumping and clearance rates in response to low dissolved oxygen levels or high (e.g., Secchi depth <25 cm), which can impair function and lead to pseudofeces production or closure to mitigate stress.

Interspecies interactions

_Perna viridis experiences significant predation pressure in its native habitats, primarily from crustaceans such as the swimming crab Thalamita danae, predatory gastropods like Thais clavigera, fishes including groupers, and such as . Predation is particularly intense on juveniles, where clumping reduces mortality by providing refuge, though overall juvenile losses are high due to these predators. In response, P. viridis induces anti-predator defenses, including increased thread production and shell thickening when exposed to predator cues. Recent studies indicate that and elevated temperatures can impair these anti-predator responses, potentially altering predation dynamics. Commensal relationships involve epibionts and fouling organisms that colonize the shells of P. viridis, such as (Amphibalanus spp.) and calcareous polychaetes (), which attach to provide structural complexity but increase hydrodynamic drag on the host. These epibionts may offer incidental benefits like against visual predators, though they can also compete for space on the shell surface. In competitive interactions, P. viridis outcompetes native mussels such as Mytilus spp. and Perna perna for benthic space and resources, leveraging its faster growth rates and broader tolerance to and fluctuations. This dominance alters community structure in intertidal and subtidal zones, often leading to displacement of slower-growing congeners. Mutualistic associations include P. viridis enhancing in ecosystems by attaching to prop roots and stabilizing sediments through byssal attachment and pseudofeces deposition, which reduces and supports associated and . Additionally, P. viridis serves as an intermediate host for parasites, including digenetic trematodes, facilitating their cycles within the broader . As a filter feeder, P. viridis plays a critical trophic role by clearing suspended particles, including , from the in dense beds, significantly reducing phytoplankton densities and influencing primary productivity in coastal systems. This filtration activity also deposits nutrient-rich pseudofeces, enriching benthic sediments and supporting detritivores.

Invasive status

Introduction vectors

The dispersal of Perna viridis beyond its native range has primarily occurred through -mediated pathways, overcoming natural oceanic barriers that limit long-distance larval transport. The species' planktonic larval stage typically lasts 2-3 weeks, allowing only limited passive dispersal via currents, which is insufficient for transoceanic crossings without assistance. As a result, nearly all documented range expansions are attributed to activities, with shipping, , and serving as the dominant vectors. Shipping represents a key vector for P. viridis introductions, primarily via hull fouling and ballast water discharge. Adults and larvae readily attach to vessel hulls, enabling transport over thousands of kilometers; for instance, fouling on commercial ships has facilitated establishments in the since the 1990s. Ballast water, exchanged during voyages, can carry viable planktonic larvae, with studies indicating that such discharges have contributed to invasions in regions like the and South Atlantic. Although exact survival rates vary, larvae remain viable in tanks under certain conditions, underscoring the role of this vector in global spread. Intentional introductions for aquaculture have also driven P. viridis dispersal, often leading to unintended wild establishments through escapees. In the Pacific, deliberate transfers from Southeast Asia occurred between 1972 and 1982 to support fisheries and farming on islands like Fiji. More recently, in Brazil, the species was first reported in 2018 at a mariculture site in Guanabara Bay, where experimental farming efforts likely initiated local populations that subsequently escaped and proliferated. These aquaculture-related translocations have resulted in self-sustaining populations in over a dozen non-native regions since the mid-20th century. Trade activities provide additional pathways for P. viridis. In recent years, particularly post-2000, recreational has emerged as a notable vector in the , where small vessels' hulls facilitate secondary spread of juveniles and adults among islands and mainland coasts. To mitigate these risks, international monitoring protocols have been strengthened; as of 2025, the International Maritime Organization's updates, including revised record-keeping requirements effective February 1, 2025, emphasize exchange and treatment to reduce viable organism discharge.

Ecological and economic impacts

As an , Perna viridis significantly impacts native ecosystems by displacing local bivalves through competitive exclusion and substrate domination. In , , it has displaced approximately 50% of native populations, altering benthic community structures. Experimental evidence from , , shows that P. viridis on artificial substrates reduces larval settlement of the (Crassostrea virginica) by interfering with recruitment sites. This displacement extends to other regions, where dense aggregations outcompete native fouling organisms, leading to shifts in community composition. The alters webs through its high filtration capacity, which depletes resources in invaded estuaries. As a , P. viridis processes large volumes of water, severely impacting coastal communities and potentially reducing availability for native pelagic . Additionally, its pseudofecal and fecal deposits increase rates, enhancing recycling but smothering soft sediments and altering suitability for infaunal organisms in estuarine environments. On , P. viridis forms extensive monocultures that reduce heterogeneity, promoting uniform mussel beds over diverse epifaunal assemblages; while hybridization with natives is rare, its aggressive competition for space and resources diminishes overall . Economically, P. viridis causes substantial losses through of infrastructure, particularly clogging cooling water intakes at coastal power plants and facilities in regions like , , , and . This fouling damages fishing gear, such as crab traps and nets, and impedes commercial harvests by overgrowing structures, leading to reduced operational efficiency and maintenance costs. Although it provides harvestable in some invaded areas, the net economic burden includes high control expenditures. Recent studies highlight ongoing range expansions with ecological consequences, such as the 2023 documentation of P. viridis in a Brazilian Marine Extractive Reserve, where it fouls substrates in coastal zones potentially affecting mangrove-associated communities. In 2025, the species was reported for the first time in Santa Catarina state, southern Brazil, indicating further expansion along the Brazilian coast. By 2025, assessments confirm its role as a sentinel species for monitoring coastal pollution, accumulating heavy metals and pollutants in invaded areas like the Colombian Caribbean. However, dense populations exacerbate eutrophication by recycling nutrients through biodeposition in nutrient-enriched waters. Mitigation efforts face significant challenges, with eradication rarely achievable due to the ' rapid and broad environmental ; physical removal is labor-intensive and often ineffective for established populations. P. viridis exhibits strong anti-predator responses and high resilience to predation pressure by native gastropods and crabs.

Human significance

Aquaculture and fisheries

Perna viridis is a key species in marine , particularly in , where it supports substantial commercial production through both wild capture and farming. Global aquaculture output of the species reached approximately 170,000 tonnes annually as of 2023, with accounting for about 50% of this total, followed by significant contributions from , , , and the . Production is concentrated in coastal areas of , where and longline methods predominate, yielding 10-20 kg/m² over the culture period. Farming techniques typically begin with seed collection using ropes or spat collectors deployed in natural settlement areas, where juvenile mussels attach byssally. Stocked at densities of 200-300 individuals per meter of , the mussels are suspended from floating rafts or longlines in sheltered bays at depths of 10-15 m to optimize water flow and food availability. occurs after 6-12 months, when shells reach marketable sizes of 50-100 mm, allowing for efficient growth to commercial standards. In culture systems, growth rates average 0.5-1 mm per day under optimal conditions, enabling rapid biomass accumulation. The nutritional profile of P. viridis enhances its value as a food resource, with dry weight protein content ranging from 15-20% and substantial levels of omega-3 fatty acids, including (EPA) and (DHA). These attributes make it a nutrient-dense , commonly prepared steamed, boiled, or in regional curries across . Aquaculture faces challenges such as disease outbreaks, including infections by protozoans like Perkinsus olseni, which have affected farmed stocks in during the 2010s, leading to mortality and reduced yields. Overharvesting of wild populations has also contributed to declines, notably in the , where natural stocks have diminished due to excessive collection for seed and direct consumption. The sector supports livelihoods in coastal communities through farming, processing, and trade, with strict regulations monitoring accumulation to ensure product safety.

Biofouling and management

Perna viridis exhibits rapid colonization as a organism, with larvae settling on submerged surfaces shortly after their planktonic phase, often within weeks of spawning due to high reproductive output and gregarious behavior. This leads to dense mats forming on artificial structures, with reported accumulations reaching up to 72 kg/m² in severe cases, such as on buoys in affected regions. The species commonly fouls critical marine infrastructure, including pipes, ship hulls, and industrial cooling systems, where attachment clogs conduits and increases hydrodynamic resistance. In seawater intake and cooling conduits, P. viridis fouling can reduce flow efficiency by causing blockages, leading to overheating of pumps and operational disruptions. Management strategies for P. viridis emphasize prevention and removal to mitigate damage. Antifouling paints, particularly -based formulations, are widely applied to hulls and structures as P. viridis is susceptible to ; however, these coatings release into the , posing ecotoxicological risks to non-target organisms. cleaning using high-pressure jets effectively removes established layers from accessible surfaces like and hulls, though it requires regular application to prevent regrowth. treatments, involving exposure to temperatures exceeding 40°C, have been employed in power plant cooling systems to induce mortality in attached mussels and larvae. Biological control approaches include experimental introductions of native predators, such as certain gastropods, to graze on settled mussels, though efficacy varies by site and requires careful assessment to avoid unintended ecological shifts. UV irradiation targets free-swimming larvae in piped systems, disrupting their development and preventing settlement downstream. Nanotechnology-based coatings, such as those incorporating metal oxide nanoparticles, have been explored for reducing larval attachment through surface modification and low-toxicity repellency.

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