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Mesosaur

Mesosaurs were an extinct group of small to medium-sized, semi-aquatic parareptiles from the family Mesosauridae that lived during the Early Permian epoch, approximately 299 to 270 million years ago.^[1] The group includes several genera, such as Mesosaurus, Stereosternum, and Brazilosaurus. Known primarily from the Irati and Mangrullo Formations, their fossils have been recovered from what are now eastern South America (Brazil and Uruguay) and southern Africa (Namibia and South Africa), where they inhabited shallow, brackish to hypersaline aquatic environments within the ancient Gondwanan rift basins.^[2] Reaching a total length of about 1 to 2 meters, with recent discoveries (as of January 2025) indicating some specimens exceeded 2 meters, mesosaurs possessed a slender, streamlined body with an elongated skull featuring numerous needle-like teeth suited for grasping small prey, a long laterally compressed tail for propulsion, and paddle-like limbs with webbed digits for swimming.^[3]^[4] These features, including pachyostotic ribs and osteosclerotic limb bones for buoyancy control, mark them as one of the earliest known amniotes to secondarily adopt an aquatic lifestyle, predating later marine reptiles by tens of millions of years.^[2] The discovery of mesosaur fossils on continents now separated by the Atlantic Ocean provided pivotal evidence for Alfred Wegener's theory of continental drift, demonstrating that South America and Africa were once joined as part of the supercontinent Pangaea during the Permian.^[3] Ecologically, mesosaurs exhibited ontogenetic shifts: juveniles were likely active predators in coastal shallows, feeding on small invertebrates like crustaceans using their sharp dentition, while adults may have transitioned to filter-feeding in more open, anoxic waters, possibly consuming pygocephalomorph crustaceans or even scavenging conspecifics.^[2] Adaptations such as inferred viviparity or ovoviviparity further supported their fully aquatic reproduction, though recent analyses suggest adults could have been semi-aquatic, venturing onto land.^[3] As basally branching reptiles, mesosaurs illuminate the early diversification of amniotes and the evolutionary pathways toward marine tetrapod radiations in the Mesozoic.^[2]

Taxonomy and Phylogeny

Nomenclature and Classification

Mesosauria is recognized as an order or clade comprising small, secondarily aquatic reptiles that inhabited coastal lagoons during the Early Permian (Cisuralian epoch, approximately 299–270 million years ago).^[5] The group is unified under the family Mesosauridae, which traditionally includes the type genus Mesosaurus along with Stereosternum and Brazilosaurus, though recent taxonomic revisions have challenged the distinctiveness of the latter two.^[2] These reptiles are characterized by their elongate skulls and specialized aquatic adaptations, but nomenclature focuses on their foundational taxonomic placement within Reptilia.^[3] The genus Mesosaurus was established by French paleontologist Paul Gervais in 1865, based on fossils from South Africa, with the type species Mesosaurus tenuidens (meaning "middle lizard" from the Greek mesos, "middle," and sauros, "lizard," referring to its intermediate position between amphibians and later reptiles).^[6] Gervais's description highlighted the slender jaws and needle-like teeth, distinguishing it from contemporaneous terrestrial reptiles.^[7] Subsequent synonyms include Mesosaurus brasiliensis (named in 1881), now regarded as a junior synonym of M. tenuidens due to overlapping morphology and lack of diagnostic differences.^[5] In the Linnaean hierarchy, Mesosauria is classified as follows: Kingdom Animalia, Phylum Chordata, Class Reptilia, Order Mesosauria (established by Harry Govier Seeley in 1892), Family Mesosauridae.^[6] The clade's monophyly is supported by shared synapomorphies such as a short anterior process of the quadrate and a large posttemporal fenestra, with current consensus affirming it as a monophyletic group basal to other sauropsids, though early debates questioned its unity with parareptiles.^[5] Only one species, Mesosaurus tenuidens, is considered valid today, as analyses of over 300 specimens indicate that purported differences in Stereosternum tumidum (Cope, 1886) and Brazilosaurus sanpauloensis (Shikama & Ozaki, 1966) reflect ontogenetic variation, taphonomic artifacts, or intraspecific polymorphism rather than distinct taxa, rendering them junior synonyms.^[8]^[9] This revision emphasizes a single, variable species across the Paraná and Karoo basins.^[10]

Phylogenetic Position

Mesosaurs have undergone several reclassifications in the phylogenetic literature since their initial description. Early analyses positioned them within Parareptilia as the sister group to all other parareptiles, based on shared primitive amniote features and exclusion from diapsid-like clades. Subsequent studies shifted this view, placing mesosaurs as basal members of crown-group Reptilia (Sauropsida excluding synapsids), supported by cladistic analyses emphasizing their position outside traditional parareptile groupings but within a broader sauropsid radiation.^[11]^[12] A pivotal advancement came with the 2012 redescription of mesosaur cranial morphology, which identified a lower temporal fenestra in Mesosaurus tenuidens—a feature typically associated with synapsids but interpreted here as potentially homologous to the amniote condition, complicating affinities and suggesting possible synapsid-like traits amid predominantly diapsid characteristics.^[13] However, mesosaurs retain overall diapsid-like skull architecture, while traits such as pachyostosis (bone thickening) and aquatic adaptations are considered derived specializations that do not strongly influence basal positioning. These features have been incorporated into cladistic matrices, where mesosaurs emerge either as the sister group to all other diapsids or within total-group Amniota, depending on character weighting.^[5] The most comprehensive recent analysis, employing over 100 morphological characters across early amniotes, firmly places Mesosauridae outside Parareptilia and as the basalmost sauropsids, challenging prior parareptile assignments and highlighting a surprising reconfiguration of early amniote interrelationships.^[5] This phylogeny underscores mesosaurs' role as a stem sauropsid lineage, with their monophyly supported by shared cranial features like elongate snouts and needle-like teeth, though debates persist on the exact delimitation of Mesosauridae based on subtle variations in these traits across genera.^[14] From 2023 to 2025, no substantial phylogenetic revisions have emerged for mesosaurs; instead, integrations into larger amniote datasets have reinforced their basal sauropsid status without altering core relationships.^[15]

Description

Cranial Anatomy

The skull of Mesosaurus tenuidens exhibits a distinctive elongate morphology adapted for an aquatic lifestyle, featuring a long, narrow snout that constitutes a significant portion of the overall cranial length. In large specimens, the snout can measure up to 20 cm, with the nasal bone extending nearly as long as the premaxilla to the anterior end of the maxilla. The external nares are positioned dorsally on the snout, enabling efficient surface respiration while minimizing disturbance to the aquatic environment. The temporal region includes a relatively large lower temporal fenestra, bounded by the jugal, postorbital, squamosal, and quadratojugal bones, a feature confirmed through detailed reconstructions of well-preserved Uruguayan specimens.^[16] Dentition in Mesosaurus is specialized for capturing small, mobile prey, with numerous slender, conical, needle-like teeth lining the jaws; these teeth are slightly recurved and angled outward, particularly anteriorly, to form a basket-like trap for nektonic organisms such as crustaceans. The marginal teeth vary in length, with the largest spanning the equivalent of four to five tooth positions, and there is no indication of structures for filter-feeding, emphasizing instead a grasping function suited to piscivory or crustacean predation in shallow marine or lacustrine settings. Tooth replacement occurs periodically, with developing teeth visible in resorption pits, further supporting an active predatory ecology. Cranial bones are notably thin and delicate, lacking the pachyostosis observed in the postcranial skeleton that enhances overall buoyancy, which reflects a balance between lightweight construction for maneuverability and structural integrity in water. Mesosaurus retains primitive reptilian traits, including a basal amniote-like skull configuration, though specific shoulder girdle elements such as the cleithrum underscore its early evolutionary position within sauropsids. Ontogenetic variation is evident, with juvenile skulls much smaller than adults, scaling proportionally to adult sizes without disproportionate changes in proportions.^[16]^[4] Excavations in 2024–2025 from the Mangrullo Formation in Uruguay have yielded fragmentary but significant cranial remains, including skulls estimated at 15–20 cm long from mature individuals, representing the largest known Mesosaurus specimens and extending total body lengths to 1.5–2.5 m. These finds demonstrate isometric growth, maintaining consistent cranial proportions across ontogeny without the emergence of novel specializations, and highlight environmental preservation in this Konservat-Lagerstätte that captures delicate bone textures.^[17]^[4]

Postcranial Skeleton

The postcranial skeleton of Mesosaurus tenuidens exhibits adaptations consistent with a semiaquatic lifestyle, including pachyostosis—a thickening of the bones that increases overall density—and modifications to the limbs and tail that suggest enhanced aquatic capabilities.^[3] The axial and appendicular elements are elongated and robust, with the trunk and tail comprising the majority of the body length.^[1] The axial skeleton features an elongated trunk supported by 29 to 33 presacral vertebrae, including 11 to 12 cervicals and the remainder dorsal.^[1] Ribs are holocephalous and pachyostotic, with banana-shaped dorsal ribs achieving diameters up to 80% of vertebral length; this thickening contributes to increased bone density, aiding buoyancy control in shallow waters.^[1]^[3] The tail is notably long, comprising approximately 60 to 65 caudal vertebrae and exceeding half the total body length, with tall neural spines and V- or wishbone-shaped chevron bones (hemal arches) that fuse in larger individuals, providing structural support along the caudal series.^[1] The appendicular skeleton includes short limbs adapted for paddling, with the forelimbs shorter than the hindlimbs; the humerus measures up to 72 mm in length in larger specimens, featuring a slender shaft and a postaxially angled distal end.^[18] Phalangeal formulas of 2-3-4-4-3 in the manus and variable 2-3-4-5-5 in the pes, combined with impressions of soft tissue in some fossils, indicate webbing between digits.^[1]^[19] A cleithrum, a primitive amniote dermal bone overlying the scapula, is present and rests on the clavicle, representing a retained feature from early tetrapod ancestors.^[1] Typical adult Mesosaurus individuals reached 0.7 to 1 m in total length, but recent analyses of fossils from the Mangrullo Formation in Uruguay reveal evidence for larger specimens up to 2.5 m, based on dorsal vertebrae with centrum lengths of approximately 14 mm and humeri exceeding 70 mm.^[18] Growth patterns in Mesosaurus are documented through ontogenetic series of postcranial elements, including vertebrae, ribs, humeri, and femora; these show progressive pachyosteosclerosis—increased bone density—indicating determinate growth and early adaptations for an aquatic lifestyle.^[20]

Paleobiology

Locomotion and Habitat

Mesosaurs were primarily aquatic swimmers, employing carangiform locomotion characterized by lateral undulation of the body and tail for propulsion, supplemented by paddling of their webbed limbs for steering and stability.^[21] This mode is inferred from their elongated, laterally compressed tail and the lateral positioning of their paddle-like limbs, with pachyostosis in the ribs and vertebrae enhancing buoyancy to maintain position in the water column.^[22] Biomechanical models based on body proportions and skeletal reconstructions estimate their optimal swimming speeds at 0.15–0.86 m/s, varying with salinity levels from normal (5%) to hypersaline (39%), consistent with pursuit of slow-moving prey in shallow waters.^[23] While predominantly aquatic, mesosaurs may have engaged in brief terrestrial movements akin to modern sea turtles, particularly as mature individuals, though limited by their heavy, pachyosteosclerotic skeleton.^[21] Their habitats consisted of shallow brackish to hypersaline lagoons or coastal ponds within the Early Permian Paraná Basin of Gondwana, as indicated by the absence of typical marine invertebrates in fossil assemblages and the presence of associated brackish-water taxa like pygocephalomorph crustaceans.^[24] Taphonomic evidence from laminated black shales and limestones reveals deposition in low-oxygen, stratified waters with hypersaline bottom conditions that inhibited decay and bioturbation, favoring exceptional preservation of soft tissues.^[24] These environments fluctuated between brackish and hypersaline states, supporting a low-diversity ecosystem under stressful, lagoon-like settings.^[24] Ontogenetic shifts influenced habitat use, with juveniles hatching fully aquatic and inhabiting shallow coastal zones where active swimming with limb involvement was prominent.^[9] As adults, mesosaurs likely shifted to deeper, more pelagic parts of these stratified lagoons, relying more on tail-driven locomotion and exhibiting potentially greater amphibious capabilities due to stronger limb proportions and vertebral adaptations for semi-terrestrial support.^[21]^[9] Mesosaurs demonstrated tolerances to brackish and hypersaline conditions through osteological adaptations like pachyosteosclerosis, which aided neutral buoyancy in variable salinities. Mass mortality events in the Mangrullo Formation are linked to gradual environmental stressors, including drought-induced aridity and volcanic ash inputs from the Choiyoi magmatism, which altered water chemistry and oxygen levels, leading to die-offs preserved in konservat-lagerstätten.^[24]^[18]

Diet and Reproduction

Mesosaurs were specialized predators of small nektonic organisms in shallow aquatic environments, with their diet primarily consisting of pygocephalomorph crustaceans, shrimp-like forms no larger than 20 mm.^[25] Their elongate, needle-like teeth, arranged in interlocking rows along the jaws and palate, were adapted for grasping and retaining slippery prey such as these crustaceans, facilitating capture without mastication.^[25] Fossil evidence from gastric contents and coprolites in the Brazilian Iratí Formation reveals fragments of crustacean carapaces, alongside small bones of juvenile mesosaurs, indicating conspecific cannibalism likely as a response to food scarcity or opportunistic scavenging.^[25] Early interpretations proposed a filter-feeding lifestyle based on dental morphology, rejected for juveniles due to the absence of specialized baleen-like structures and the presence of robust, grasping dentition suited for active prey capture, but a 2022 study suggests adults may have filter-fed on small planktonic prey using elongated teeth.^[25]^[2] Instead, feeding likely involved rapid snapping of the jaws to seize prey in shallow waters, possibly augmented by limited suction generated by buccal expansion, as inferred from cranial kinematics and comparisons to related aquatic amniotes.^[25] A 2022 analysis of 270 specimens indicates ontogenetic shifts: juveniles, with shorter snouts and limbs, were active predators in shallow coastal zones, while adults, with elongated snouts and teeth, likely filter-fed on small pygocephalomorph larvae in deeper, pelagic parts of stratified lagoons.^[2] Reproductive biology in mesosaurs points to viviparity or ovoviviparity, marking an early evolutionary adaptation for aquatic life among amniotes. Exceptional fossil preservation includes embryos preserved in utero within adult females from the Early Permian Mangrullo Formation of Uruguay and the Iratí Formation of Brazil, dated to approximately 280 million years ago. These specimens, described in studies from 2012 to 2015, reveal coiled embryos about 10-15% the size of adults, lacking eggshells and providing the oldest direct evidence of live birth in amniotes; females typically carried one embryo, with rare cases of two.^[26] Ontogenetic growth patterns indicate slow, isometric development, with hatchlings measuring 0.1-0.12 m and reaching maturity around 0.7 m in length, as evidenced by bone histology showing parallel-fibered tissue and cyclical growth marks.^[20] Recent analyses of large specimens from the Mangrullo Formation, including skulls up to 0.21 m long, suggest maximum body lengths of 2.5 m, implying either prolonged lifespans beyond typical maturity or possible sexual dimorphism in size.^[18]

Fossil Record

Discovery History

The holotype of Mesosaurus tenuidens (MNHN 1865-77), nicknamed the "Griqua Mesosaurus," was discovered around 1830 in Griqualand West, South Africa, where local Griqua people used the fossil slab as a pot lid in a dwelling before it was identified as a vertebrate remain and sent to Europe.^[27] This specimen, consisting of a partial skull and mandible, was formally described and named by French paleontologist Paul Gervais in 1865 based on its slender, needle-like teeth, marking the initial recognition of mesosaurs as a distinct group of early aquatic reptiles.^[13] The first mesosaur fossils from South America were reported in 1908 from black shales of the Irati Formation in Paraná, Brazil, where Scottish geologist John Henderson MacGregor identified them as a new species, Mesosaurus brasiliensis, based on fragmentary remains including vertebrae and limb bones.^[28] Subsequent collections in the 1920s from the same formation yielded more complete material, such as nearly intact skulls and postcrania, which helped establish the close similarity to African specimens and led to the synonymization of M. brasiliensis with M. tenuidens in later revisions.^[29] Key early specimens include numerous articulated skeletons from the Whitehill Formation in South Africa's Karoo Basin, first systematically collected in the late 19th and early 20th centuries, which preserved near-complete individuals up to 1 meter in length and facilitated initial reconstructions of mesosaur posture and locomotion.^[30] A major advance came in 2012 when Graciela Piñeiro and colleagues described 26 adult specimens associated with embryos or neonates from the Mangrullo Formation in Uruguay and equivalent strata in Brazil, revealing the oldest known amniotic reptile embryos and suggesting viviparous reproduction.^[31] Recent discoveries have expanded knowledge of mesosaur size variation, with Piñeiro, Pablo Núñez Demarco, and Michel Laurin reporting in 2025 fragmentary but significant remains from the Mangrullo Formation at Picada de Cuello and El Barón localities in northern Uruguay, including large skulls (FC-DPV 3622, 3623) measuring 150–200 mm and associated bones (FC-DPV 3620–3621, 2396–2397) indicating mature individuals up to 2.5 meters long—substantially larger than the typical 0.7-meter average.^[18] Research milestones from the 1980s to 2010s included taxonomic revisions synonymizing multiple species under M. tenuidens (e.g., Oelofsen 1987) and taphonomic studies elucidating preservation in anoxic lagoons, as detailed in analyses of Whitehill and Irati deposits.^[30]^[32] From 2017 onward, focus shifted to growth series, with studies confirming isometric scaling in ontogeny through bone microstructure and morphometric analyses of specimens spanning juvenile to adult stages.^[3]^[33]^[20]

Distribution and Stratigraphy

Mesosaur fossils are confined to southern Gondwana, with no records from the Northern Hemisphere or other regions, underscoring their restricted paleobiogeographic range. In South America, specimens are primarily recovered from the Mangrullo Formation in northeastern Uruguay and the Irati Formation within the Paraná Basin of southern Brazil. In southern Africa, key localities include the Whitehill Formation in the main Karoo Basin of South Africa and the Dwyka Group in southern Namibia, where mesosaurs occur in the upper shaly members.^[34]^[35] Stratigraphically, mesosaurs characterize Early Permian deposits spanning the late Artinskian to early Kungurian stages, dated approximately 284 to 280 million years ago based on U-Pb radiometric ages from interbedded ash layers.^[36] These fossils are embedded in organic-rich black shales, mudstones, and siltstones, typically 20–50 meters thick, deposited in low-energy, anoxic lacustrine or restricted lagoonal environments within the expansive Mesosaurus Inland Sea. The sediments often include evaporitic features like gypsum rosettes and are overlain or interbedded with Glossopteris-bearing strata, linking mesosaur-bearing units to broader Gondwanan floral assemblages.^[35]^[34] Taphonomic evidence reveals exceptional preservation at these sites, qualifying them as Konservat-Lagerstätten due to rapid burial in oxygen-depleted, hypersaline waters that inhibited decay and scavengers. Mass death assemblages are common, with concentrations exceeding 1,000 articulated or disarticulated individuals per horizon in the Mangrullo Formation of Uruguay, including rare soft-tissue impressions sealed by bacterial films. Such accumulations suggest episodic die-offs tied to fluctuating salinity or anoxia events.^[34] Biostratigraphically, mesosaurs define a distinct zone in these non-marine sequences, co-occurring with low-diversity freshwater invertebrates such as ostracodes and conchostracans (including estheriids), alongside trace fossils like Chondrites and rare fish remains, which collectively affirm brackish to freshwater depositional settings rather than open marine conditions.^[34]^[35]

Significance

Evidence for Continental Drift

The discovery of identical Mesosaurus tenuidens fossils in both South America and southern Africa provided early evidence that these continents were once connected, as the reptile was a brackish- to hypersaline-water dweller incapable of crossing the modern Atlantic Ocean.^[2] Fossils of this species, the only valid mesosaurid, occur exclusively in Early Permian deposits of the Paraná Basin in Brazil and the Karoo Basin in South Africa, ruling out post-separation land migration after the Permian ended around 252 million years ago.^[2]^[37] These fossils are preserved in correlated geological formations—the Irati Formation in Brazil and the Whitehill Formation in South Africa—characterized by similar black shales, high organic carbon content (up to 24%), and sulfur-rich lithology indicative of anoxic marine conditions in a restricted epicontinental sea.^[38] Both units are dated to the Kungurian stage of the Early Permian, approximately 278 million years ago, predating the initial rifting of Pangea around 200 million years ago by over 70 million years.^[39]^[40] In the 1920s, Alfred Wegener cited Mesosaurus distribution as key support for his continental drift hypothesis, first proposed in 1912, highlighting how the reptile served as an index fossil demonstrating the unity of Gondwana in the Early Permian before continental separation.^[41] This evidence underscored that such transatlantic fossil matches could only result from former adjacency of the continents, challenging fixed-landmass models prevalent at the time.^[41] Modern plate tectonics confirms this through paleomagnetic data, which reconstructs the Early Permian positions of the fossil sites at approximately 30–40° south paleolatitude, aligning South America and Africa in a continuous landmass within southern Gondwana.^[42] Stratigraphic correlations further validate the shared depositional environment, reinforcing Mesosaurus as a biogeographic marker for pre-rift Gondwanan connectivity.^[40]

Evolutionary Role

Mesosaurs represent the earliest known fully aquatic amniotes, dating to the mid-Early Permian around 280 million years ago, and thus played a pivotal role in bridging the gap between terrestrial reptiles and later marine forms by demonstrating early experimentation with aquatic lifestyles among sauropsids.^[2]^[3]^[13] As basal sauropsids, they illustrate the initial diversification of amniotes into marginal aquatic environments, with adaptations that foreshadowed more extreme marine specializations in subsequent lineages. Their position at the base of sauropsid phylogeny, supported by recent analyses, underscores their importance in understanding the radiation of reptiles from land to water during the late Paleozoic.^[43]^[44] Key innovations in mesosaurs include evidence of viviparity, an early reproductive strategy in sauropsids that predates similar traits in Triassic marine reptiles and likely facilitated their aquatic transition by eliminating the need for terrestrial egg-laying.^[45] Skeletal adaptations such as pervasive pachyostosis—increased bone density for buoyancy control—and partial limb reduction, particularly in the forelimbs relative to hindlimbs, represent preliminary steps toward the streamlined bodies and paddle-like appendages seen in later groups like ichthyosaurs and mosasaurs.^[3]^[30]^[2] Recent discoveries of larger specimens, reaching up to 2.5 meters in total length—including a January 2025 report from Uruguay's Mangrullo Formation—challenge earlier hypotheses positing small-bodied ancestors for aquatic reptiles, as proposed by Carroll, and suggest greater size variability and ecological flexibility in early sauropsid evolution.^[18]^[4]^[46] Mesosaurs became extinct by the close of the Early Permian, approximately 280 million years ago, leaving no direct descendants but contributing significantly to our knowledge of basal reptile diversity and the selective pressures on early amniote lineages.^[47] Their disappearance coincides with environmental shifts in Gondwanan coastal and lagoonal habitats, potentially exacerbated by increasing aridity and salinity fluctuations, though specific causal mechanisms remain debated.^[48] Post-2020 studies have updated understandings of their maximum size and affirmed their basal sauropsid position over outdated parareptile affiliations, resolving long-standing phylogenetic uncertainties and highlighting gaps in earlier reconstructions of early reptile evolution.^[18]^[3]

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Jan 1, 1987 · A comparison is drawn between the biostratigraphy of the Whitehall Shale Formation of the Karoo basin and that of the Irati Shale Formation of the Paraná basin.
[42]
[PDF] Untitled - ResearchGate
paleomagnetic data for this time. As can be seen ... the Permian reptile Mesosaurus ... latitude location during the Mid to Late Paleozoic is indicated, but.
[43]
[PDF] A Reassessment of the Taxonomic Position of Mesosaurs ... - HAL
Nov 16, 2020 · The lower temporal fenestra (character 32), considered to have been absent in Laurin and Reisz (1995) is now considered present. (Piñeiro et al.
[44]
Evolutionary assembly of crown reptile anatomy clarified by late ...
Aug 28, 2025 · These historical observations were based on anatomical features suggesting the loss of an upper temporal fenestra and the presence of a tympanic ...<|separator|>
[45]
Extended embryo retention and viviparity in the first amniotes - Nature
Jun 12, 2023 · ... viviparity and oviparity occurred in a single species as in the basalmost sauropsid Mesosaurus tenuidens and few extant squamates.
[46]
The Largest Mesosaurs Ever Known: Evidence from Scanty Records
Dec 26, 2024 · Herein, we describe large, poorly preserved and incomplete skulls, as well as axial and appendicular bones, from the Mangrullo Formation ...
[47]
Mesosaurus | Permian Period, Gondwana, Aquatic Reptile - Britannica
Mesosaurus lived in freshwater lakes and ponds. Elongated and slim, it measured about 1 metre (3.3 feet) long. The skull and tail were both long and narrow, and ...
[48]
Tales of the Continental Divide: The Adventures of Mesosaurus
Sep 15, 2016 · Mesosaurus was an unusual reptile. It looked kind of like crocodiles do today, with a long, thin body, eyes located on top of the skull, webbed feet, and an ...