Mobula is a genus of large, filter-feeding rays in the family Mobulidae, consisting of ten extant species—three manta rays and seven devil rays—that inhabit tropical and subtropical waters worldwide, often in pelagic environments over continental shelves and oceanic islands.[1] These rays are distinguished by their flattened, diamond-shaped bodies with wing-like pectoral fins spanning up to 7 meters in the largest species, prominent cephalic fins that form "horns" to direct plankton-rich water into their mouths, and a terminal mouth positioned forward on the head for ram-filter feeding.[2] The genus underwent taxonomic revision in 2017, synonymizing the former genus Manta into Mobula based on phylogenetic analysis revealing close relatedness, with a third manta species, Mobula yarae, formally described in 2025 from the western Atlantic.[3][4]All Mobula species are highly migratory, often traveling long distances singly or in schools to aggregate at productive feeding grounds or cleaning stations, where they interact with reef fish that remove parasites from their skin.[5] They primarily consume zooplankton, small fishes, and crustaceans, with low reproductive rates—typically giving birth to a single pup after a gestation period of 12–15 months—making populations particularly vulnerable to overexploitation.[6]Mobula rays play a key ecological role in marine food webs as predators of plankton and indicators of ocean health, but all species are threatened with extinction due to targeted fisheries for their gill plates (used in traditional Asian medicine), meat, and bycatch in gillnets and purse seines.[7] Conservation efforts, including CITES Appendix II listing since 2014 and IUCN Red List assessments classifying most as Vulnerable to Critically Endangered, have led to international trade regulations and protected areas to mitigate declines.[8]
Description and Anatomy
Physical Characteristics
Mobula rays are characterized by a distinctive body plan featuring diamond-shaped or rhomboidal pectoral fins that fuse anteriorly with the head, forming a subrostral lobe which enhances hydrodynamic efficiency during swimming.[9] These fins create a broad, flattened disc typical of the genus, with the overall body adapted for pelagic lifestyles in open waters. Prominent cephalic fins, derived from the anterior lobes of the pectoral fins, project forward like horns and vary in length among species; they are present in all Mobula and play a role in channeling food toward the mouth.[10]The tail of Mobula rays is typically whip-like and longer than the disc width in most species, providing agility for propulsion, though it is shorter in manta rays such as Mobula birostris. A stinging spine is absent in the majority of species, but Mobula mobular retains a functional one located dorsally on the tail. The genus possesses five pairs of gill slits, each encircled by feathery gill rakers that form a specialized filter-feeding apparatus to retain planktonic prey while expelling water.[11]The skin of Mobula rays is covered with small dermal denticles, contributing to their streamlined form and providing protection, though a thick mucus layer gives it a smooth texture; some species may have more pronounced denticles near the tail or cloaca.[12] Coloration is generally dark on the dorsal surface, ranging from bluish-black to brown, contrasting with a pale ventral side that aids in camouflage against ocean surfaces.[10] Disc widths vary widely within the genus, from approximately 1.1–1.2 m in smaller species like Mobula kuhlii to 7.1 m in the giant manta ray Mobula birostris, with the largest individuals reaching weights of up to 3,000 kg.[10] The recently described Mobula yarae (2025) shares similar features with other manta species, including a serrated caudal spine and stellate-shaped dermal denticles.[4]
Sensory and Defensive Adaptations
Mobula rays, like other elasmobranchs, possess ampullae of Lorenzini, specialized electroreceptors that detect weak electric fields generated by prey muscle contractions and potential mates, particularly in low-visibility or murky waters where visual cues are limited.[13] These gel-filled pores are distributed across the head and ventral surface, with a higher density on the underside to facilitate detection during filter-feeding near the ocean floor or in plankton-rich currents.[14] This adaptation enhances foraging efficiency and social interactions in pelagic environments.The olfactory system in Mobula features paired nares equipped with nasal flaps or curtains that direct water flow over the olfactory rosette, amplifying chemical detection of plankton blooms and environmental cues essential for filter-feeding navigation.[15] In species like the manta ray (Mobula birostris), these structures form a square nasal curtain extending toward the mouth, optimizing scent capture during oscillatory swimming in open water.[16]Vision is supported by large, dorsally positioned eyes that provide a wide field for spotting predators from above, complemented by a tapetum lucidum—a reflective choroidal layer that boosts sensitivity in dim conditions by redirecting light through the retina.[17]Defensively, most Mobula species have evolved to forgo a venomous tail spine, an apparent loss favoring hydrodynamic streamlining for agile swimming and evasion through bursts of speed or aerial breaching maneuvers.[18] This reliance on mobility over armament reduces drag in their fast-paced, migratory lifestyle. An exception occurs in the spinetail devil ray (Mobula mobular), which retains a caudal spine with mild venomous properties for deterrence, though it is rarely used aggressively.[19] Acoustic sensitivity is mediated by otoliths in the inner ear, enabling detection of low-frequency sounds (typically 20–800 Hz) for orientation and depth assessment during long-distance migrations across varying ocean depths.[20]
Habitat and Distribution
Geographic Range
Mobula rays inhabit tropical and subtropical waters across all major ocean basins, with a predominantly pelagic lifestyle that keeps them offshore except during periodic aggregations near productive coastal areas. In the Atlantic Ocean, they range from the Gulf of Mexico southward to Brazil, while in the Eastern Pacific, distributions extend from Baja California to Peru. The Indo-Pacific represents the broadest expanse, spanning from the Red Sea through the Indian Ocean to Australia and the western Pacific islands.[21]These rays exhibit latitudinal limits generally between 40°N and 40°S, aligning with warm water masses and avoiding polar extremes. Seasonal migrations track oceanographic features such as warm currents, including the Gulf Stream in the Atlantic, enabling individuals to follow prey-rich zones and maintain access to suitable temperatures. For instance, populations in the northern hemisphere may shift southward during cooler months, while southern groups move poleward in summer.[21][22]Depth utilization spans from the surface to approximately 1,000 m, though the majority of observed activity occurs in the upper 200 m of the water column, where they engage in filter-feeding near plankton blooms. Aggregations occasionally bring them closer to shore, as seen in the Sea of Cortez for Mobula japanica, where large schools form in shallow bays during peak seasons.[23]Distribution patterns vary by species, with some achieving circumglobal reach and others showing regional endemism. Mobula tarapacana maintains a broad, continuous presence across tropical and warm temperate waters of the Atlantic, Indian, and Pacific Oceans. In contrast, Mobula thurstoni is more restricted to the Indian Ocean, with sporadic records elsewhere, highlighting fragmented populations within the genus.[24][25]
Environmental Preferences
Mobula rays thrive in tropical and subtropical waters with temperatures typically ranging from 20 to 30 °C, though they can tolerate down to approximately 19 °C in certain regions; they avoid colder waters below 15 °C by employing behavioral thermoregulation, such as thermotaxis to seek warmer layers.[22][5][26]These rays are strictly marine, preferring salinities of 30 to 35 practical salinity units (ppt) and showing intolerance to brackish conditions, with abundance increasing in higher salinity environments associated with oceanic upwelling.[27][28][29]They favor productive zones characterized by upwelling areas and oceanographic convergence fronts, where chlorophyll-a concentrations of 0.5 to 1 mg/m³ indicate plankton blooms, such as those driven by equatorial currents.[30][31]Mobula rays primarily occupy the epipelagic zone (0–200 m depth), with occasional dives into the mesopelagic layer (200–1,000 m) for foraging, while actively avoiding hypoxic zones with low dissolved oxygen levels below 2 mg/L.[32][33]As fully pelagic species, they exhibit no significant benthic interactions in adults, though juveniles of some species may occasionally associate with near-bottom substrates in shallow coastal areas.[5][34]
Behavior and Ecology
Locomotion and Social Interactions
Mobula rays exhibit a pelagic lifestyle characterized by efficient propulsion through undulatory swimming, where their enlarged pectoral fins undulate in a sinusoidal wave from anterior to posterior, generating thrust via leading-edge vortices and asymmetric motion during downstrokes. This flapping mechanism, known as mobuliform locomotion, allows for sustained cruising speeds of approximately 2 m/s (7.2 km/h), with higher burst capabilities during evasion or migration.[35][36] Their flattened disc shape contributes to hydrodynamic efficiency, enabling gliding phases that minimize energy expenditure over extended travels, with pectoral fin flexibility optimizing thrust-to-power ratios up to 0.89.[35] The cephalic fins play a supplementary role in steering and maneuvering during these swims.[37]Mobula rays also perform deep dives, particularly oceanic manta rays (M. birostris), which can descend rapidly to depths exceeding 500 m at speeds up to 2.9 m/s, featuring horizontal movements at depth and slow ascents, likely for surveying water column properties to aid navigation rather than foraging.[38]A distinctive locomotor behavior in Mobula is breaching, where individuals propel themselves out of the water to heights exceeding 1 m, and up to several meters in species like the pygmy devil ray (Mobula munkiana). This aerial display serves multiple functions, including the removal of ectoparasites such as isopods, dislodging attached remoras (which can number in the dozens and cause irritation), and potentially facilitating communication among conspecifics through visual or acoustic signals. Breaching frequency increases in aggregations, with observations recording up to 286 events over 89 surveys in reef manta rays (Mobula alfredi), often peaking before feeding periods.Socially, Mobula rays display a fission-fusion structure, occurring solitarily or in schools typically ranging from 1 to 67 individuals (mean ~7), though larger aggregations of 100 or more form at productive sites.[40] These groups often exhibit sexual segregation, with females predominating at cleaning stations (up to 77% in some sites) for parasite removal by cleaner fish, while males favor feeding areas.[40] Such aggregations, which may coincide briefly with feeding grounds, foster interactions like synchronized swimming, indicative of playful or coordinated behaviors, with minimal aggression observed due to the absence of territorial defense in this nomadic genus.[40]Migration patterns in Mobula are nomadic and long-distance, with satellite telemetry revealing transits exceeding 1,000 km; for instance, reef manta rays have been tracked over total paths of up to 1,817 km, with linear displacements averaging 262 km between sites.[41] These movements connect distant habitats, such as UNESCO World Heritage areas, and reflect a strategy of exploiting transient resources while maintaining site fidelity to key aggregation points.[41]
Feeding Strategies
Mobula rays employ a specialized filter-feeding mechanism adapted for capturing small prey from vast volumes of seawater. The prominent cephalic fins, which curl forward during feeding, channel plankton-rich water directly into the terminal or subterminal mouth. Water passes over a sieve-like filtration apparatus composed of modified gill arches lined with leaf-shaped lobes that form the branchial filter pads. These structures facilitate ricochet separation, a nonclogging process where incoming particles collide with the lobes, generating vortices that redirect larger particles toward the esophagus while allowing clean water to exit through the five pairs of gill slits. This mechanism, distinct from crossflow filtration in other elasmobranchs, maintains efficiency even at low prey densities by minimizing resistance and preventing buildup of debris.[42]The filtration system's selectivity is determined by the spacing and morphology of the filter lobes, which vary across Mobula species. Pore sizes range from approximately 340 μm in giant oceanic manta rays (M. birostris) to 1100 μm in some devil rays like M. tarapacana, enabling retention of particles larger than 200–250 μm while expelling finer sediment. This raking-like arrangement of gill plates ensures effective capture of mesozooplankton without excessive energy expenditure. The diet primarily comprises zooplankton, including copepods (Calanoida), euphausiids (such as Euphausia spp.), and mysids, alongside small fish (e.g., lanternfish and jack mackerel juveniles) and fish eggs; manta species preferentially target dense schools of larger krill, reflecting their access to coastal upwelling zones. Stomach content and DNA metabarcoding analyses confirm euphausiids as the dominant component, comprising up to 95% of identifiable prey sequences across multiple species.[42][43][5]Foraging behaviors are tailored to prey distribution and include surface skimming, where rays cruise with mouths agape at the water's surface to intercept epipelagic plankton, and ram-filtering dives that target deeper aggregations during tidal currents or upwellings. These rays often form loose schools during foraging to exploit patchy, high-density patches of zooplankton, briefly leveraging their modified gill slits for efficient water expulsion. Estimated daily intake reaches up to 2% of body weight, based on weekly consumption rates of 12.7% observed in reef manta rays (M. alfredi) feeding on euphausiids. Given their large body sizes (up to 3 m disc width) and ectothermic physiology with elevated activity levels, Mobula rays face substantial metabolic demands, sustained by near-continuous feeding in productive oceanic waters where prey abundance supports their energy needs. As secondary consumers in pelagic food webs, they regulate zooplankton populations, linking primary production to higher trophic levels.[44][43][45]
Reproduction and Life History
Mating and Courtship
Mobula rays exhibit polygynandrous mating systems, in which individual males pursue and copulate with multiple females, while females may mate with several males during a reproductive cycle.[46]Courtship behaviors are elaborate and often occur in large aggregations, facilitating mate selection and pair formation. These interactions typically involve "mating trains," where groups of 2–20 (sometimes up to 26) males closely follow and pursue a single receptive female in a coordinated chase, with male-to-female ratios averaging 3:1 but increasing during evasion maneuvers.[47][46]Key courtship displays include synchronized belly rolls, where rays expose their ventral surfaces while swimming in close proximity; acrobatic somersaults performed by pursuing males to attract attention; and rhythmic waving of cephalic fins to signal readiness or dominance.[46] Males may also engage in agonistic behaviors, such as gently biting the trailing edge of the female's pectoral fin to position her for copulation, which occurs via internal fertilization with the male inserting claspers into the female's cloaca.[46] In some species, such as Mobula munkiana, courtship can escalate into a "vortex" formation, where dozens of individuals (up to 122 observed) circle in a relaxed, touching manner to facilitate interactions among 30–40 females and pursuing males.[48]Reproductive activity shows strong seasonality, peaking during warmer months in tropical and subtropical regions; for instance, in the Gulf of California, courtship and mating for species like M. mobular, M. thurstoni, and M. munkiana occur from March to August, with highest intensity in May.[47] Mobula rays demonstrate site fidelity to specific aggregation areas for mating, returning annually to locations such as the Revillagigedo Islands in Mexico, where large schools converge for reproductive purposes.[49]Sexual maturity is reached at varying disc widths across species, with males typically maturing at 2–3 m (e.g., M. mobular males at 2.0–2.2 m) and females at larger sizes (e.g., 2.07–2.4 m for the same species).[7] Age at maturity also varies, estimated at 4.5–9.1 years for M. thurstoni and 7.7 years for M. mobular males and 8.9 years for females (as of 2025).[50][51]Following a gestation period of 12–15 months, Mobula rays are viviparous, giving live birth to a single, well-developed pup per reproductive cycle, with no parental care provided post-parturition.[7][50] This low reproductive output underscores the vulnerability of these behaviors to disruptions in aggregation sites.[47]
Embryonic Development
Mobula rays exhibit viviparous reproduction, in which embryos develop internally within the mother's uterus, nourished initially by a yolk sac and subsequently through histotrophy, the absorption of nutrient-rich uterine secretions known as histotroph. This lipid-based histotroph, secreted by specialized uterine villi called trophonemata, provides essential lipids and proteins for embryonic growth after yolk depletion, enabling the development of large, well-formed pups without reliance on placental exchange. Unlike some elasmobranchs that employ oophagy or intrauterine cannibalism, Mobula species lack such mechanisms, ensuring all embryos receive maternal nutrients equitably.[52]Litter sizes in Mobula rays are typically small, consisting of a single pup, though twins occur occasionally in some species such as Mobula mobular and Mobula thurstoni. Gestation periods last approximately 12 months across most species, including the sicklefin devil ray (M. tarapacana), while larger manta species like Mobula birostris and Mobula alfredi may extend to 12–13 months; for M. mobular, a 2025 study documented a gestation of 464 days (about 15 months).[50][5][51] Pups are born fully formed and mobile, emerging tail-first to facilitate passage through the birth canal and immediate swimming capability, with disc widths at birth ranging from 35–50 cm in smaller species like Mobula munkiana to 50–70 cm in mid-sized devil rays and up to 120–150 cm in mantas.[50][5]Post-birth growth in Mobula rays is rapid, allowing juveniles to reach sexual maturity within 5–10 years, depending on species and environmental factors; for instance, M. thurstoni matures around 4.5–9 years, while mantas may take longer. Lifespans vary similarly, estimated at 20–30 years for most devil rays and up to 40 years for larger mantas, contributing to their low overall reproductive output and vulnerability to overexploitation.[50][53]
Taxonomy and Evolution
Classification History
The genus Mobula was first described in 1810 by Constantine Samuel Rafinesque, who established it to encompass the devil fish, originally classified as Raia mobular (now Mobula mobular), with the name derived from the Azorean Portuguese term "mobula," referring to the ray's mobile nature, or possibly from the Latin mobilis meaning "movable."[54] Initially, Mobula was placed within the family Myliobatidae, reflecting the early taxonomic grouping of eagle rays and related forms based on shared morphological traits such as diamond-shaped pectoral fins.[55]During the 19th and 20th centuries, taxonomists began subdividing Mobula into subgenera to account for morphological variations, particularly distinguishing the larger, filter-feeding mantas, which were separated into the distinct genus Manta by Edward Nathaniel Bancroft in 1831 (originally under the synonym Cephaloptera).[2] This split was formalized in revisions such as Notarbartolo di Sciara's 1987 study, which recognized nine living species within Mobula (excluding mantas) and emphasized differences in fin shape, dentition, and body proportions to delineate subgenera like Lobatobatis and Rhineobatis.[56]A major taxonomic revision occurred in 2017, when White et al. integrated molecular data (including complete mitogenomes and nuclear loci) with morphological analyses, revealing that Manta species nested phylogenetically within Mobula. This led to the synonymization of Manta under Mobula, supported by evidence of homology in cephalic fins—previously seen as a distinguishing trait but now interpreted as a shared derived character across the group—resulting in a monogeneric family Mobulidae with nine recognized species.[2]In 2025, Bucair et al. further advanced the classification through an integrative approach, identifying a cryptic species in the Atlantic Ocean via mitochondrial genomes and nuclear markers, which formed a monophyletic lineage closely related to M. birostris and M. alfredi; named Mobula yarae, this addition brings the total to ten species.[4]Phylogenetically, Mobula occupies a derived position within the order Myliobatiformes, as the sole genus in the family Mobulidae, which is sister to the eagle ray lineage (Aetobatidae and Myliobatidae) based on combined molecular and skeletal data.[2] The fossil record traces back to the Miocene epoch, with early mobulid forms like the genus Archaeomobula documented from dental remains, indicating an ancient pelagic radiation predating modern diversity.[57]
Recognized Species
The genus Mobula comprises 10 recognized species, encompassing the former genus Manta following taxonomic revisions that integrated mantas into Mobula based on phylogenetic evidence from mitogenomes and nuclear sequences. This total reflects updates through 2025, including the recent description of a cryptic species, with FishBase listing 9–11 nominal taxa depending on synonymy resolutions.[58] Species are distinguished primarily by morphological traits such as cephalic fin length relative to mouth width, pectoral fin curvature, tail spine presence and position, denticle coverage, and coloration patterns like dorsal spots or ventral markings.Key species include the giant oceanic manta ray (Mobula birostris), which attains a maximum disc width of 7.1 m and features long cephalic fins exceeding mouth width, a short tail without a spine, and uniform black dorsal coloration with white ventral side; synonyms include Manta hamiltoni. The reef manta ray (Mobula alfredi) reaches up to 5.5 m disc width, characterized by shorter cephalic fins (about 25% of mouth width), a diagnostic white shoulder blaze on the ventral side, and a tailspine in juveniles that is often lost in adults. The spinetail devil ray (Mobula mobular), with disc widths of 1.1–3.4 m, has a prominent caudal spine near the tail tip, straight posterior pectoral fin margins, and dense denticles on the dorsal surface; Mobula japanica is a junior synonym.[59]Other notable species are the sicklefin devil ray (Mobula tarapacana), growing to 3.7 m disc width with highly curved, sickle-shaped pectoral fin tips, a low dorsal fin origin, and a caudal spine positioned low on the tail; genetic studies in 2025 identified cryptic lineages within this species, suggesting potential future splits. The bentfin devil ray (Mobula thurstoni) measures up to 1.2 m, distinguished by bent or angular posterior pectoral fin edges, a short tail with a spine, and sparse denticles. The shortfin pygmy devil ray (Mobula kuhlii) is smaller at 1.1 m maximum, featuring short cephalic fins, no caudal spine, and uniform grayish coloration.Additional species encompass the longhorned pygmy devil ray (Mobula eregoodoo, up to 1.3 m, with long cephalic fins and a low-placed caudal spine), Munk's pygmy devil ray (Mobula munkiana, ~1.1 m, broad disc with rounded tips and ventral white patches), and the Atlantic pygmy devil ray (Mobula hypostoma, ~1.1 m, short head and spine near dorsal fin base). The Atlantic manta ray (Mobula yarae), described in 2025 as a cryptic species distinct from M. birostris, reaches up to approximately 5 m disc width and is diagnosed by subtle genetic divergences and minor morphometric differences in fin proportions, primarily in Atlantic waters.[4]Extinct taxa, such as Mobula bukharinensis from the Pliocene, highlight the genus's evolutionary history but are not part of the current recognized living species inventory. Taxonomic mergers, such as incorporating Manta species, have streamlined the genus while ongoing genetic research continues to refine boundaries.
Species
Common Name
Max Disc Width (m)
Key Diagnostic Traits
M. birostris
Giant oceanic manta
7.1
Long cephalic fins > mouth width; no tail spine; black dorsal
M. alfredi
Reef manta
5.5
Short cephalic fins; white shoulder blaze; juvenile tail spine
M. mobular
Spinetail devil ray
3.4
Caudal spine at tail tip; straight pectoral margins; dense denticles
Angular pectoral edges; short tail with spine; sparse denticles
M. kuhlii
Shortfin pygmy devil ray
1.1
Short cephalic fins; no caudal spine; grayish uniform color
M. eregoodoo
Longhorned pygmy devil ray
1.3
Long cephalic fins; low-placed caudal spine
M. munkiana
Munk's pygmy devil ray
1.1
Rounded pectoral tips; ventral white patches
M. hypostoma
Atlantic pygmy devil ray
1.1
Short head; spine near dorsal base
M. yarae
Atlantic manta ray
5.0
Subtle fin proportion differences; genetic distinction from M. birostris
Conservation Status
Major Threats
The primary anthropogenic threat to Mobula populations is bycatch in commercial fisheries, particularly in the Indo-Pacific region where tuna purse seine and drifting gillnet operations are prevalent. These fisheries unintentionally capture large numbers of mobulid rays, with global documented landings exceeding 94,000 individuals annually prior to international trade restrictions in the mid-2010s, driven largely by incidental catches in the Indian and western Pacific Oceans. Retention of bycaught individuals for commercial use exacerbates the impact, as mobulids' pelagic lifestyle and low reproductive rates—typically producing only one pup every two to three years—render populations highly susceptible to even moderate fishing pressure.[9][60][61]Targeted fisheries further deplete Mobula stocks, primarily for their gill plates, which are harvested for use in traditional Chinese medicine to purportedly aid in detoxification and respiratory health, with high demand originating from markets in China and Hong Kong. These fisheries also utilize the rays' meat for human consumption and, to a lesser extent, their fins as a low-cost substitute in the shark fin trade, especially in regions like Indonesia and India where shark populations have declined due to overexploitation. Annual targeted catches in key areas such as the eastern tropical Pacific and Indian Ocean contributed significantly to pre-ban harvests, often exceeding tens of thousands of individuals per species in heavily fished locales.[9][62][63]Habitat degradation from climate change poses an escalating risk, with ocean acidification projected to reduce zooplankton abundance—the primary food source for filter-feeding Mobula species—in tropical waters by mid-century, potentially forcing dietary shifts or nutritional stress. Rising sea temperatures are altering migration patterns, with models indicating poleward range shifts of approximately 30 km per decade for pelagic elasmobranchs like mobulids by 2050, disrupting access to productive feeding grounds in the Indo-Pacific. Additionally, warming-induced coral bleaching events threaten reef-associated species such as the reef manta ray (Mobula alfredi), which rely on healthy reefs for cleaning stations that remove parasites and maintain skin health.[64][65][66]Boat strikes from increasing maritime traffic, including tourism vessels, represent a localized but severe threat in aggregation sites like Bahía de Banderas, Mexico, where seasonal migrations draw thousands of mobulid rays into narrow coastal channels. Collisions cause sublethal injuries such as propeller cuts and spinal damage in 31.7% of observed individuals in high-traffic areas, with recovery hindered by the species' slow healing rates. Pollution, particularly microplastics, compounds these risks as Mobula rays ingest debris mistaken for plankton, leading to internal blockages and toxin accumulation documented in gut contents from Indonesian and Maldivian populations.[67][68][69]
Protection Measures
All species within the genus Mobula are listed under Appendix II of the Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES), with manta rays (M. alfredi and M. birostris) added in 2014 and devil rays in 2016, effective from 2017, regulating international commercial trade to ensure sustainability across more than 180 parties. This listing has contributed to measurable reductions in gill plate exports in key markets, such as a slight decline in the availability of gill plates in Hong Kong's dried seafood market post-implementation, though illegal trade persists in some regions. In November 2025, at CITES CoP20, a proposal was discussed to uplist all Mobula species to Appendix I for stricter trade bans.[70] The International Union for Conservation of Nature (IUCN) assesses all Mobula species as Vulnerable, Endangered, or Critically Endangered, with recent 2025 uplistings elevating oceanic devil rays (M. mobular, M. tarapacana, and M. thurstoni) to Critically Endangered due to ongoing declines; for instance, M. birostris remains Endangered with population reductions of 30–50% over three generations in many areas.[21]Regional protections complement international efforts, including the European Union's 2005 ban on large-scale drift gillnets longer than 2.5 km, which targeted fisheries incidentally capturing Mobula species, alongside full retention bans for mobulids in EU waters under Regulation (EU) No 2019/1241. In Mexico, federal legislation in 2015 prohibited the capture, sale, and trade of all Mobula species nationwide, with Baja California Sur implementing state-level enforcement to safeguard aggregation sites in the Gulf of California. The Maldives extended full protection to all mobulid rays in 2015, building on earlier manta safeguards, and designated marine reserves such as Hanifaru Bay in Baa Atoll—a UNESCO Biosphere Reserve—where feeding and cleaning aggregations are monitored to prevent disturbance.[71]Research initiatives bolster these measures, with the Manta Trust employing photo-identification to catalog over 10,000 individual manta and devil rays globally, enabling population monitoring and migration mapping through satellite and acoustic tagging.[72] In 2025, genetic studies led by Nayara Bucair confirmed a third manta ray species (M. yarae) in the Atlantic via DNA analysis of over 100 specimens, providing critical data for species-specific conservation plans and highlighting hybridization risks; M. yarae has a restricted distribution in the western Atlantic, placing it at higher extinction risk, and has not yet been formally assessed by the IUCN but is expected to be classified as threatened.[73] Community-based programs, such as eco-tourism in Indonesia's Raja Ampat archipelago, have reduced poaching by integrating local patrols and diver guidelines, shifting economic incentives toward non-extractive activities and decreasing illegal captures by up to 90% in protected zones.[74] However, challenges remain, including weak enforcement in high-seas fisheries beyond national jurisdictions, where bycatch continues unabated despite CITES requirements for non-detriment findings.[75]