Lamniformes
Lamniformes, commonly known as mackerel sharks, is an order of sharks encompassing seven families and fifteen extant species characterized by two dorsal fins without spines, an anal fin, five gill slits, the absence of nictitating membranes, and mouths extending behind the eyes.[1][2][3] These sharks exhibit diverse feeding strategies, from active predation by species such as the great white shark (Carcharodon carcharias) and shortfin mako (Isurus oxyrinchus) to filter-feeding in the basking shark (Cetorhinus maximus), the second-largest living fish, which sieves plankton through gill rakers.[4][5][6] Members of Lamniformes display specialized anatomical adaptations, including regional endothermy in some lamnids that enables sustained high-speed pursuits, and elongated upper caudal lobes in threshers (Alopias spp.) for stunning prey with tail whips.[7] The order's fossil record extends to the Jurassic period, with diversification during the Cretaceous, including extinct giants like the megalodon (Otodus megalodon), once the largest predator to have lived.[8][9] Ecologically, lamniforms occupy apex or mid-level trophic roles in pelagic and coastal marine environments worldwide, though many species face population declines due to overfishing and bycatch.[10][11]Taxonomy and Phylogeny
Classification and Families
The order Lamniformes, commonly known as mackerel sharks, is classified within the subclass Elasmobranchii of the class Chondrichthyes, under the superorder Selachimorpha (modern sharks and rays).[12] This placement reflects shared apomorphies such as clasper grooves in males and other neoselachian traits distinguishing them from basal shark lineages.[13] Lamniformes comprises seven extant families, 10 genera, and 15 species, representing a relatively small but morphologically diverse group compared to other shark orders like Carcharhiniformes.[14] [13] These families are monophyletic based on both molecular and morphological evidence, including traits like the absence of a subocular shelf and specific vertebral calcification patterns.[13] The classification has remained stable since the late 20th century, with minor revisions primarily affecting generic boundaries rather than family-level delimitations.[7] The families are as follows:- Alopiidae (thresher sharks): Includes three species in the genus Alopias, characterized by elongated upper caudal lobes.[15]
- Cetorhinidae (basking sharks): Monotypic family with Cetorhinus maximus, the second-largest extant shark species.[16]
- Lamnidae (mackerel sharks): Contains five species across three genera (Carcharodon, Isurus, Lamna), including the great white shark (Carcharodon carcharias).[17]
- Megachasmidae (megamouth sharks): Monotypic with Megachasma pelagios, known from deep-sea specimens since its discovery in 1976.[18]
- Mitsukurinidae (goblin sharks): Monotypic family featuring Mitsukurina owstoni, a deep-water species with protrusible jaws.[19]
- Odontaspididae (sand tiger sharks): Encompasses four species in two genera (Carcharias, Odontaspis), notable for their coastal habits and multiple embryo development.[20]
- Pseudocarchariidae (crocodile sharks): Monotypic with Pseudocarcharias kamoharai, a small deep-sea shark distinguished by its blunt snout.[21]
Evolutionary Relationships
Lamniformes constitutes one of four orders within the superorder Galeomorphii, a major clade of neoselachian sharks that diverged from the sister superorder Squalomorphii during the Mesozoic era, as corroborated by molecular phylogenies incorporating mitochondrial and nuclear genes across 229 shark species.[23] Within Galeomorphii, Lamniformes forms a monophyletic group, typically positioned as sister to Carcharhiniformes (ground sharks) in a subclade excluding the basal Heterodontiformes (bullhead sharks) and Orectolobiformes (carpet sharks), based on analyses of four mitochondrial (COI, Cytb, 16S, NADH-2) and one nuclear (Rag-1) loci.[24] This arrangement aligns with shared morphological traits such as the absence of certain cranial features and is supported by Bayesian inference, though resolution among galeomorph orders remains partially unresolved due to limited taxon sampling in early molecular datasets.[14] Internally, the order's phylogeny reveals a basal position for Mitsukurinidae (goblin shark), followed by a clade comprising Odontaspididae (sand tigers, including Carcharias and Odontaspis), Pseudocarchariidae (crocodile shark), and Megachasmidae (megamouth shark), as inferred from 42 parsimony characters emphasizing dental morphology such as tooth serration, root structure, and crown height.[25] More derived families include Alopiidae (thresher sharks), Cetorhinidae (basking shark), and Lamnidae (mackerel sharks, with Isurus and Carcharodon forming a subclade sister to Lamna), reflecting evolutionary trends toward elongated caudal fins, filter-feeding specializations, and reduced tooth row counts linked to dietary shifts from macrophagy to planktivory.[25] Molecular approaches yield broadly congruent topologies but highlight discrepancies, such as the placement of Megachasma pelagios nearer to basal odontaspids rather than filter-feeders like Cetorhinus, potentially indicating convergent evolution in jaw and gill raker adaptations for suspension feeding.[24] Combined morphological-molecular analyses reinforce Lamniformes monophyly via synapomorphies including spine-less dorsal fins and heterocercal tail modifications, while underscoring dental characters' utility despite homoplasy in serration patterns.[26] These relationships underscore Lamniformes' adaptive radiation within Galeomorphii, with basal taxa retaining plesiomorphic narrow-crowned teeth suited to soft-bodied prey, evolving toward robust, triangular dentition in apex predators like the great white shark (Carcharodon carcharias), driven by ecological pressures rather than uniform morphological divergence.[25] Disagreements between datasets, such as dental-based clustering of Carcharias with odontaspids versus molecular signals of deeper divergence, likely stem from incomplete fossil calibration and gene tree incongruence, necessitating expanded genomic sampling for resolution.[24] Overall, the order exemplifies chondrichthyan evolutionary stability, with core lineages persisting since the Early Cretaceous amid shifts in body size and thermoregulation.[13]Fossil Record and Origins
The order Lamniformes likely originated in the early Middle Jurassic around 166 million years ago as small, benthic coastal sharks, inferred from ancestral state reconstructions and comparative analyses of dental morphology and histology.[27] Micro-computed tomography of teeth from the Jurassic genus Palaeocarcharias reveals a unique mineralization pattern shared with modern lamniforms, supporting its position as a stem-group representative and pushing the group's origins into the Bathonian stage.[13] The earliest unambiguous lamniform fossils, however, appear in the Valanginian stage of the Early Cretaceous approximately 140 million years ago, including taxa like Scapanorhynchus lewisii preserved in three-dimensional body fossils.[13][28] During the Cretaceous, Lamniformes experienced a major adaptive radiation, coinciding with global oceanic changes and the diversification of marine ecosystems.[29] Key early representatives include Cretoxyrhina mantelli, a fast-swimming apex predator from the Turonian stage (~90 million years ago) that reached lengths of 6-7 meters and is known from articulated skeletons in the Western Interior Seaway deposits.[28] Other significant Cretaceous genera, such as Squalicorax and Johnlongia, exhibit durophagous adaptations for crushing shelled prey, highlighting early ecological specialization within the order.[30] This period saw the emergence of larger body sizes and varied feeding strategies, setting the stage for Cenozoic giants like Otodus megalodon.[31] The fossil record of Lamniformes is primarily based on isolated teeth and vertebrae due to the perishable nature of shark cartilage, with rarer articulated skeletons providing insights into body form and locomotion.[32] Post-Cretaceous diversification included the evolution of filter-feeding forms like early cetorhinids and the persistence of macropredatory lineages, though many Cretaceous taxa went extinct at the K-Pg boundary.[29] Overall, the group's evolutionary history spans over 135 million years, with ongoing discoveries refining the Jurassic-Cretaceous transition.[31]Morphology and Adaptations
Body Form and Structures
Lamniform sharks exhibit a fusiform body shape, spindle-like and tapered at both ends, which minimizes drag and enables efficient thunniform propulsion through rapid caudal oscillations.[33] This morphology supports sustained high-speed cruising in open ocean habitats, with a conical snout reducing frontal resistance and large pectoral fins providing lift and maneuverability. The body is typically heavy anteriorly, transitioning to a narrow caudal peduncle reinforced by lateral keels and precaudal pits that enhance stability during acceleration.[34] Diagnostic fin structures include two dorsal fins, the anterior one prominent and triangular with its origin over or behind the pectoral fin base, and a smaller posterior dorsal fin; an anal fin is also present, unlike in some other shark orders.[10] The caudal fin varies but often features a lunate or crescent shape with a well-developed ventral lobe, contributing to thrust; in basal forms, it retains heterocercal asymmetry with a dorsally arched vertebral column.[35] Five large gill slits extend laterally without encircling the head, adapted for high-volume water flow in active species, though gill rakers are absent in macrophagous forms.[34] Head structures emphasize predatory efficiency, with a mouth extending posterior to the eyes and lacking a nictitating membrane, exposing the cornea during strikes.[2] Jaws are robust and protrusible in some taxa, armed with triangular, often serrated teeth suited for cutting flesh; dermal denticles cover the skin, providing abrasion resistance and hydrodynamic benefits. Morphological diversity is evident across families: Alopiidae (thresher sharks) possess an elongated upper caudal lobe approaching body length for prey herding, while Cetorhinidae (basking sharks) feature expanded gill slits and pharyngeal structures for filter-feeding.[10] Such variations reflect ecological specializations within the order's shared skeletal framework.[36]Physiological Specializations
Several families within Lamniformes exhibit regional endothermy, a physiological adaptation enabling elevated temperatures in specific tissues such as red swimming muscles, cranial regions, eyes, and viscera, independent of ambient water temperature. This trait is documented in Lamnidae (e.g., great white shark Carcharodon carcharias, shortfin mako Isurus oxyrinchus), Alopiidae (thresher sharks), and recently in Cetorhinidae (basking shark Cetorhinus maximus), affecting approximately seven of the 15 extant species.[37][38] Regional endothermy supports higher metabolic rates and sustained aerobic performance, with endothermic lamniforms demonstrating routine metabolic rates up to twice those of ectothermic counterparts at equivalent temperatures, such as 507 mg O₂ kg⁻¹ h⁻¹ in shortfin mako at 16°C.[39][40] Heat generation primarily arises from continuous aerobic metabolism in centralized red muscle fibers, which constitute 6–30% of axial musculature in endothermic species and produce excess metabolic heat during sustained swimming. Retention occurs via specialized vascular counter-current heat exchangers known as retia mirabilia, including orbital retia for cranial warming (elevating eye and brain temperatures by 10–25°C above water), suprahepatic retia for viscera (maintaining stomach temperatures up to 12°C excess), and caudal retia for locomotor muscles. These networks achieve heat conservation efficiencies exceeding 97%, minimizing conductive losses to seawater.[41][42][43] In Alopiidae, orbital retia are absent, yet brain and eye warming may occur through alternative vascular arrangements derived from hyoidean and pseudobranchial arteries.[44] This endothermy facilitates ecological advantages, including faster cruising speeds (up to 20–25% higher than ectotherms after temperature correction), extended migrations into colder waters, and enhanced predatory efficiency through improved neuromuscular function and visual acuity.[45][46] Ontogenetic development influences its expression, with juvenile great white sharks showing less pronounced cranial warming that matures with size.[47] Like other elasmobranchs, lamniforms maintain osmotic balance via elevated plasma urea (approximately 400 mM) and trimethylamine N-oxide (TMAO, 200 mM) levels, supplemented by rectal gland NaCl secretion, which TMAO counteracts to stabilize proteins against urea's denaturing effects; however, endothermy imposes additional energetic costs that elevate overall urea turnover.[48][49]Sensory and Locomotory Features
Lamniform sharks exhibit advanced sensory capabilities, including electroreception via the ampullae of Lorenzini, a network of jelly-filled pores distributed across the head that detect bioelectric fields from prey muscle contractions and heartbeats at distances up to several body lengths.[50] This system is particularly dense in the hyoid and mandibular regions, aiding precise prey localization during hunting, as documented in species like the basking shark (Cetorhinus maximus), where pore abundance correlates with filter-feeding behaviors near plankton patches.[51] Olfaction is highly developed, with enlarged olfactory bulbs processing chemical cues; for instance, the great white shark (Carcharodon carcharias) possesses an exceptional olfactory bulb relative to brain size, enabling detection of blood traces in seawater at concentrations as low as one part per million.[14] Vision adaptations vary, but many lamnids feature retinas specialized for diurnal conditions, with high rod and cone densities supporting contrast detection in well-lit coastal waters.[14] The lateral line system complements these by sensing water pressure changes and vibrations, facilitating navigation and prey tracking in dynamic oceanic environments. Locomotory features in Lamniformes emphasize sustained high-performance swimming, achieved through morphological and physiological specializations. Many taxa, particularly in Lamnidae and Alopiidae, display regional endothermy, where vascular counter-current heat exchangers retain metabolic heat in axial red muscle, elevating tissue temperatures by 10–21°C above ambient seawater to support continuous cruising speeds exceeding 10 body lengths per second.[52] [37] This endothermy, widespread across the order including in Odontaspididae and Cetorhinidae, originates from centralized red muscle masses near the vertebral column, enhancing contractile efficiency and oxygen delivery during prolonged activity.[37] Caudal fins are typically heterocercal, with elongated upper lobes generating thrust via powerful lateral undulations, as seen in lamnids achieving burst speeds over 15 m/s through tuna-like stiff-bodied propulsion that minimizes drag.[53] [8] Pectoral fins provide lift and maneuverability, while streamlined fusiform bodies reduce resistance, adaptations convergent with scombrid fishes for pelagic endurance. In thresher sharks (Alopias spp.), the exceptionally long upper caudal lobe doubles as a propulsion aid and hunting tool, whipping to stun schooling prey at velocities up to 24 km/h.[54] These traits collectively enable exploitation of open-ocean niches, though ectothermic basal lamniforms like goblin sharks (Mitsukurina owstoni) rely more on ambush propulsion with protrusible jaws.[38]Species Diversity
Extant Species
The order Lamniformes includes 15 extant species across seven families, representing a diverse array of sharks ranging from large filter-feeders to active predators.[14] These species exhibit specialized adaptations such as regional endothermy in some lamnids and elongated tails in thresher sharks, enabling varied ecological roles from coastal to pelagic habitats.[22] The family Lamnidae, or mackerel sharks, contains five species noted for their streamlined bodies, powerful propulsion, and ability to maintain elevated body temperatures: the great white shark (Carcharodon carcharias), shortfin mako shark (Isurus oxyrinchus), longfin mako shark (Isurus paucus), porbeagle (Lamna nasus), and salmon shark (Lamna ditropis). These sharks are primarily open-ocean predators, with the great white reaching lengths up to 6 meters and preying on marine mammals, while makos are among the fastest swimming sharks, attaining speeds over 70 km/h.[17] The Cetorhinidae family consists of a single species, the basking shark (Cetorhinus maximus), the second-largest fish alive, growing to over 8 meters and feeding via passive ram filtration on plankton.[55] Similarly, the Megachasmidae includes only the megamouth shark (Megachasma pelagios), a deep-water filter-feeder discovered in 1976, characterized by its large mouth and bioluminescent capabilities, with fewer than 300 individuals documented.[56] Alopiidae, the thresher sharks, encompasses three species—common thresher (Alopias vulpinus), pelagic thresher (Alopias pelagicus), and bigeye thresher (Alopias superciliosus)—distinguished by their elongated upper caudal lobes exceeding half their body length, used in prey herding and stunning. These sharks inhabit epipelagic waters and are vulnerable due to bycatch.[57] The Odontaspididae, or sand tiger sharks, features three species: the sand tiger (Carcharias taurus), smalltooth sand tiger (Odontaspis ferox), and bigeye sand tiger (Odontaspis noronhai), all with protrusible jaws and a preference for coastal or deep reefs, where they ambush prey; the sand tiger is notable for internal gestation involving oophagy.[58] Pseudocarchariidae adds the crocodile shark (Pseudocarcharias kamoharai), a small (up to 1.1 meters), deep-sea species with photophores and a diet of squid and fish.[59] Finally, the Mitsukurinidae family has one species, the goblin shark (Mitsukurina owstoni), a deep-water benthopelagic shark with a protrusible jaw and nail-like teeth, rarely exceeding 3 meters and scavenging or ambushing prey in depths up to 1,300 meters.[60]| Family | Number of Extant Species | Representative Species |
|---|---|---|
| Lamnidae | 5 | Carcharodon carcharias |
| Cetorhinidae | 1 | Cetorhinus maximus |
| Megachasmidae | 1 | Megachasma pelagios |
| Alopiidae | 3 | Alopias vulpinus |
| Odontaspididae | 3 | Carcharias taurus |
| Pseudocarchariidae | 1 | Pseudocarcharias kamoharai |
| Mitsukurinidae | 1 | Mitsukurina owstoni |
Extinct and Fossil Taxa
The fossil record of Lamniformes documents an evolutionary history spanning approximately 135 million years, from the Early Cretaceous to the present, with early records indicating the onset of large body sizes among these sharks.[31] Extinct taxa are predominantly known from isolated teeth and vertebral elements, reflecting a peak in diversity during the Cretaceous and subsequent decline through the Cenozoic, influenced by factors such as climate cooling and clade competition.[29] Prominent among extinct families is Otodontidae, which includes the genus Otodus with species such as O. megalodon, a Miocene-Pliocene predator reaching estimated lengths of 15-18 meters and characterized by massive, serrated teeth adapted for bone-crushing.[61] The family Cretoxyrhinidae features Cretoxyrhina mantelli, a Late Cretaceous (Cenomanian-Turonian) lamniform up to 7 meters long, known for its near-complete skeletons revealing a streamlined body suited for fast predation on mosasaurs and other large prey.[62][63] Similarly, Anacoracidae encompasses genera like Squalicorax, durophagous sharks from the Cretaceous to Paleogene, with species such as S. kaupi exhibiting robust teeth for crushing shelled prey, and widespread in marine deposits globally.[64] Other notable extinct genera include Megalolamna (Otodontidae), recorded from the Late Oligocene to Middle Miocene across multiple continents, with teeth suggesting large-bodied macropredators intermediate in size between early otodontids and O. megalodon.[65] Mid-Cretaceous lamniforms, such as those in southern high-latitude assemblages, show morphological disparity in tooth form tied to niche partitioning, with increasing tooth sizes tracking oceanic warming events.[30] The order's fossil occurrences total over 2,000 at the genus level, underscoring a boom-and-bust pattern culminating in the modern low diversity of 15 extant species.[29]Ecology and Distribution
Habitats and Geographic Range
Lamniform sharks inhabit a broad spectrum of marine environments, including coastal, neritic, epipelagic, and mesopelagic zones, primarily in temperate and tropical waters across all major ocean basins.[66][14] Many species exhibit high mobility, with distributions influenced by temperature preferences ranging from surface waters to depths exceeding 1,000 meters.[66] Pelagic forms dominate the order, favoring open ocean habitats, while others frequent continental shelves and slopes.[14] The order's geographic range is circumglobal, encompassing the Atlantic, Pacific, Indian, and Southern Oceans, though individual species show varying extents. For instance, shortfin mako sharks (Isurus oxyrinchus) occur widely in upper oceanic layers from coastal nurseries to offshore pelagic zones in tropical and temperate seas.[5] White sharks (Carcharodon carcharias) prefer temperate coastal and offshore waters worldwide, with juveniles often in shallower nearshore areas.[11] Thresher sharks (Alopias spp.), highly pelagic, range across the Pacific from British Columbia to Chile in the east and similarly broad latitudes elsewhere.[67] Deep-water specialists like goblin sharks (Mitsukurina owstoni) are recorded from continental slopes and abyssal plains at depths of 250–1,300 meters, with sightings in the western Atlantic off Guyana and Surinam, eastern Atlantic near Madeira and Portugal, Indo-Pacific regions, and the western Pacific.[68] Basking sharks (Cetorhinus maximus) concentrate in temperate surface waters for plankton-rich feeding grounds, migrating seasonally across North Atlantic and North Pacific populations.[66] Salmon sharks (Lamna ditropis) are confined to the North Pacific, spanning subarctic to temperate coastal and pelagic habitats between 10°N and 70°N.[69] Overall, while most lamniforms avoid polar extremes, their adaptability supports extensive, often migratory distributions tied to prey availability and thermal tolerances.[14]Feeding Ecology
Lamniform sharks exhibit diverse feeding strategies adapted to their varied ecological niches, ranging from active predation on large prey to passive filtration of plankton. Predatory species in families such as Lamnidae and Odontaspididae typically employ ram ventilation combined with powerful bites to capture teleosts, cephalopods, and marine mammals, leveraging serrated teeth and robust jaw musculature for efficient prey processing.01268-9) For example, the great white shark (Carcharodon carcharias) functions as an opportunistic apex predator, consuming a broad diet including demersal fishes, pinnipeds, and cetaceans, with daily ration estimates of 1.5–1.9% of body mass indicating higher energetic demands than previously assumed.[70] [71] Specialized predatory tactics further distinguish certain lamniforms. Thresher sharks (Alopias spp.) use their elongated caudal fins to deliver high-velocity tail-slaps, stunning or herding schooling fishes such as jacks and lancetfish before consumption, enabling capture of multiple prey items per strike.[72] In contrast, the goblin shark (Mitsukurina owstoni) employs a unique "slingshot" mechanism, rapidly protruding its jaws at speeds exceeding those of other sharks to slash and ingest deep-sea teleosts and cephalopods, compensating for its sluggish swimming.[73] The shortfin mako (Isurus oxyrinchus), a fast cruiser, targets epipelagic bony fishes and squid through high-speed pursuits facilitated by regional endothermy.[74] Filter-feeding lamniforms, represented by the basking shark (Cetorhinus maximus) and megamouth shark (Megachasma pelagios), diverge markedly by sieving microscopic zooplankton. The basking shark passively filters copepods and other plankton via gill rakers during slow, open-mouthed cruises, processing vast water volumes through ram-jet ventilation without active pumping.[75] [76] Similarly, megamouth sharks target euphausiids using modified buccal structures for cross-flow filtration in low-light mesopelagic zones.[77] These strategies underscore the order's evolutionary specialization, with dietary partitioning linked to morphological innovations like elongated tails or protrusible jaws.01268-9.pdf)Behavioral Patterns
Lamniform sharks display a spectrum of behavioral strategies adapted to their predatory or planktivorous lifestyles, with active hunters employing burst locomotion and sensory-driven ambushes, while filter feeders rely on sustained, low-energy cruising. In the family Lamnidae, species such as the great white shark (Carcharodon carcharias) utilize high-speed breaches to capture surface prey like pinnipeds, propelling their bodies up to 6 meters out of the water at speeds exceeding 40 km/h, as documented through biologging data revealing rapid tail-beat frequencies and precise prey targeting during ascent. This behavior facilitates surprise attacks from below, minimizing energy expenditure on prolonged chases and leveraging the shark's regional endothermy for enhanced muscle performance in cooler waters.[42] Thresher sharks (Alopias spp.) exhibit a specialized hunting tactic involving overhead tail whips to stun schools of small pelagic fish, such as sardines, with strikes reaching velocities of up to 23 m/s and generating hydrodynamic forces sufficient to disorient multiple prey items simultaneously.[78] Underwater footage confirms the sequence: the shark positions perpendicular to the school, coils its elongate upper caudal lobe, and unleashes a lateral sweep, followed by a recovery phase to collect dazed victims, enabling efficient foraging on aggregated bait balls.[79] This tail-mediated predation contrasts with jaw-centric strategies in other lamniforms and underscores the order's morphological diversity in prey capture. Filter-feeding lamniforms, including basking sharks (Cetorhinus maximus), engage in ram ventilation during slow, continuous swimming at 2-4 km/h, parting their mouths to sieve zooplankton via gill rakers while detecting plankton patches through olfactory cues.[80] Surface-oriented feeding, often misinterpreted as basking, correlates with seasonal plankton blooms, with tagged individuals aggregating in nutrient-rich coastal zones for hours-long bouts.[81] Many lamniform species, particularly lamnids, undertake extensive migrations spanning thousands of kilometers, tracked via satellite tags showing vertical dives to 1000 m and horizontal transits between foraging grounds, driven by prey availability and thermal preferences rather than fixed breeding cycles.[82] Social interactions remain minimal, with most taxa solitary, though transient aggregations occur at pinniped colonies or cleaning stations without evidence of hierarchical structures.[83]Reproduction and Life History
Reproductive Strategies
Lamniformes exhibit aplacental viviparity as their predominant reproductive mode, characterized by internal development of embryos nourished initially by yolk sacs and subsequently by oophagy, wherein developing young consume unfertilized eggs produced by the mother.[84][85] This strategy, observed across families such as Lamnidae and Odontaspididae, supports the production of larger, precocial offspring capable of immediate predatory independence upon birth, with litter sizes typically ranging from 2 to 17 pups depending on species.[86] Gestation periods are extended, often exceeding 12 months; for instance, in the porbeagle shark (Lamna nasus), embryonic development spans approximately 8-9 months, though full-term data remain limited for many taxa.[87] In several lamniform species, oophagy is supplemented or replaced by intrauterine cannibalism, including adelphophagy (sibling consumption), which further enhances embryonic growth by eliminating competition and providing substantial nutrient intake. The sand tiger shark (Carcharias taurus) exemplifies this, with the first-hatched embryos developing enlarged yolk stomachs to prey on subsequent siblings and unfertilized eggs, resulting in typically 1-2 surviving pups per uterus despite initial litters of up to 20-30.[88] Similarly, the goblin shark (Mitsukurina owstoni) and megamouth shark (Megachasma pelagios) display oophagic traits, though detailed observations are scarce due to rarity.[84] The great white shark (Carcharodon carcharias) demonstrates a hybrid nutritional strategy, beginning with lipid histotrophy—embryos absorbing nutrient-rich secretions from the uterine epithelium during early gestation—before transitioning to oophagy, enabling pups to reach birth sizes of 1.2-1.5 meters.[89] This maternal investment correlates with low fecundity (2-10 pups per litter) and biennial or triennial reproductive cycles, as females require recovery periods post-parturition.[4] Reproductive maturity is delayed, with females attaining it at lengths of 4.5-5 meters after 12-18 years, reflecting the high energetic costs of this mode.[90] For filter-feeding species like the basking shark (Cetorhinus maximus), reproduction remains poorly documented, with only a single historical record of a gravid female containing six embryos (five live, one stillborn) suggesting ovoviviparity without confirmed oophagy.[91] Presumed gestation exceeds 2-3 years, with litters of 1-6 pups and intermittent breeding cycles, underscoring knowledge gaps in planktivorous lamniforms.[92] Across the order, these strategies prioritize quality over quantity, aligning with apex or mid-trophic roles that demand robust juvenile survival amid sparse resources.[84]Growth and Maturity
Lamniform sharks are characterized by relatively slow somatic growth rates compared to many other elasmobranchs, with growth often modeled using von Bertalanffy functions derived from vertebral band counts or tag-recapture data.[93] This slow growth, coupled with late attainment of sexual maturity—typically after several years and at substantial body sizes—results in extended juvenile periods and low intrinsic population growth rates, rendering the order particularly susceptible to overfishing.[94] Females across species generally mature later and at larger sizes than males, reflecting sexual dimorphism in life history strategies.[95] In the white shark (Carcharodon carcharias), a prominent lamniform, males reach sexual maturity at lengths of 3.5–4 meters total length (TL) after approximately 26 years, while females mature at 4–5 meters TL around 33 years, based on revised aging analyses that indicate much slower growth than earlier estimates of 10 years or less.[96] Growth increments are minimal post-maturity, with annual increases of less than 10 cm after the first decade.[97] The basking shark (Cetorhinus maximus), the second-largest extant lamniform, exhibits even slower growth, with males maturing at 5–7 meters TL between 12 and 16 years of age, and females at 8–9.8 meters TL around 20 years.[98] Juveniles grow at rates supporting lifespans exceeding 50 years, emphasizing their K-selected traits.[80] Shortfin mako sharks (Isurus oxyrinchus) represent a faster-growing exception within the order, with rapid early growth of about 39 cm fork length (FL) in the first year, followed by deceleration; males mature at 7–9 years (around 180–200 cm FL), and females at 18–21 years (290–320 cm FL).[99] Maximum observed ages reach 29–32 years.[100] Thresher sharks (Alopias spp.), including the common thresher (A. vulpinus), grow slowly after an initial phase, with maturity around 5 years at 2.7–3 meters TL for both sexes, though females achieve larger asymptotic sizes; lifespans extend 19–50 years.[101] Salmon sharks (Lamna ditropis) show comparatively faster rates, with males maturing at 158 cm TL in 3–5 years and females at 205 cm TL in 6–9 years.[102] These interspecific variations highlight adaptive differences, but the predominant pattern of delayed maturity underscores conservation challenges for the order.[103]Population Dynamics
Lamniformes exhibit K-selected life history strategies characterized by slow growth, late maturity (often 10–30 years), low fecundity (typically 2–15 pups per litter), and long gestation periods (9–24 months), which result in low intrinsic population growth rates (r_max estimates of 0.02–0.10 per year) and extended recovery times from depletion, often exceeding 100 years for heavily exploited stocks.[104][105] These traits render populations particularly susceptible to overexploitation, with fisheries-induced declines observed across multiple families, though some regional recoveries have occurred under strict management.[106] Population trends vary by species and region, but many Lamniformes are assessed as Vulnerable or Endangered by the IUCN due to historical overfishing. For instance, the great white shark (Carcharodon carcharias) shows increasing abundances in the northeastern Pacific, with estimates of approximately 300 individuals in central California and evidence of population growth since the 1990s, attributed to reduced targeted fishing and ecosystem-based protections; however, global estimates range from 3,500 to 20,000 individuals, with an overall decreasing trend in some assessments.[11][107][108] The basking shark (Cetorhinus maximus) has experienced severe declines, with global populations at about 30% of historic levels and an effective breeding population size of around 8,000; in Atlantic Canada, current estimates are roughly 10,000 animals, reflecting partial recovery from 80% reductions since the 1950s following fishery closures.[109][110][92] Other lamniforms demonstrate pronounced declines: the porbeagle (Lamna nasus) in the northwest Atlantic is at 22–27% of 1961 levels, with Mediterranean populations reduced by over 99% since the mid-20th century, though southern hemisphere stocks show stability or increases; shortfin mako (Isurus oxyrinchus) populations have declined by a median of 46.6% (with 50–79% probability over 72–75 years) due to bycatch in pelagic fisheries.[111] Thresher sharks (Alopias spp.) are globally Vulnerable, with pelagic thresher populations reduced by 50–79% in some regions from finning pressures, though Pacific common thresher stocks are not currently overfished.[106][112][101] These dynamics underscore the order's vulnerability to human impacts, with recovery dependent on sustained reductions in mortality rates exceeding natural ones.[113]Human Interactions
Fisheries and Utilization
Several species within Lamniformes are targeted or caught as bycatch in commercial fisheries, primarily for their meat, fins, and historically liver oil, though utilization has declined due to regulatory restrictions and low population recoveries. The porbeagle shark (Lamna nasus) has been commercially harvested mainly in the North Atlantic for its meat, which is marketed as fresh, frozen, or processed fillets suitable for human consumption. In Atlantic Canada, fisheries management established non-restrictive catch guidelines of 1,500 metric tons annually for porbeagle prior to 1997, reflecting directed longline and gillnet operations.[114][115] Shortfin mako sharks (Isurus oxyrinchus) are primarily encountered as bycatch in pelagic longline fisheries targeting tunas and swordfish, with their meat utilized for steaks or fillets and fins entering the international shark fin trade. U.S. commercial landings of Pacific shortfin mako totaled 28,000 pounds (valued at $30,000) in 2023, predominantly from Hawaiian longline vessels, where the species contributes to incidental catch rather than directed effort.[116] Thresher sharks (Alopias spp.), particularly the common thresher (A. superciliosus), are harvested off the U.S. West Coast via drift gillnet fisheries for their firm, mild-flavored meat, which is processed into fillets or steaks, with federal regulations prohibiting finning to prioritize whole-animal utilization.[117][118] Historically, the basking shark (Cetorhinus maximus) supported targeted fisheries for its massive liver, which yields high volumes of oil rich in squalene and vitamin A, used in lubricants, cosmetics, and pharmaceuticals from the 1940s to 1950s. In the northeastern Pacific, U.S. operations in the 1950s extracted liver oil from basking sharks for industrial applications, though such exploitation ceased amid population declines and subsequent protections.[92][119] Overall, Lamniformes contribute modestly to global shark fisheries statistics under FAO's Lamnidae grouping, with contemporary catches emphasizing sustainable meat markets over high-value fin products due to species-specific quotas and international management measures.[120]Conservation Assessments
The International Union for Conservation of Nature (IUCN) Red List evaluates Lamniformes species as among the most threatened elasmobranch groups, driven primarily by overfishing for meat, fins, and other products, compounded by their K-selected life histories featuring slow growth, late maturity, and low fecundity.[121] Approximately two-thirds of the order's 15 extant species qualify as threatened (Vulnerable, Endangered, or Critically Endangered), reflecting global population declines of 30-80% in many cases over generational spans.[29] Assessments highlight disproportionate risks for larger, migratory species in the families Lamnidae and Alopiidae, where targeted fisheries and bycatch have not been sufficiently curtailed despite international regulations.[122] Key species assessments demonstrate this vulnerability:| Species | Scientific Name | IUCN Status (Global) | Primary Rationale |
|---|---|---|---|
| Great white shark | Carcharodon carcharias | Vulnerable | Overexploitation, historical targeted fisheries, and regional declines exceeding 30% in some populations.[123] |
| Basking shark | Cetorhinus maximus | Endangered | Past finning and targeted fishing leading to >90% declines in Northeast Atlantic stocks; slow recovery projected over centuries.[124][109] |
| Porbeagle | Lamna nasus | Vulnerable | Intensive commercial fisheries causing multi-decadal declines, with subpopulations in the North Atlantic reduced by 80-90%.[125] |
| Shortfin mako | Isurus oxyrinchus | Endangered | High bycatch in tuna longline fisheries and directed harvest, with global declines of ~50% over three generations; uplisted from Vulnerable in 2019.[126][127] |
| Bigeye thresher | Alopias superciliosus | Vulnerable | Exploitation for fins in driftnet and longline fisheries, with inferred declines of >50% in Atlantic and Indian Ocean populations.[128] |
| Pelagic thresher | Alopias pelagicus | Endangered | Intense finning pressure and bycatch, resulting in up to 80% declines in some regions; all thresher species face similar threats.[129] |