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Majungasaurus

January 01, 1970

Majungasaurus (/məˌʌŋɡəˈsɔːrəs/; lit.'Mahajanga lizard') is a genus of abelisaurid theropod dinosaur that lived in Madagascar from 70 to 66 million years ago, at the end of the Cretaceous Period, making it one of the last-known non-avian dinosaurs that went extinct during the Cretaceous–Paleogene extinction event. The genus contains a single species, Majungasaurus crenatissimus. This dinosaur is also called Majungatholus, a name which is considered a junior synonym of Majungasaurus.

Majungasaurus
Temporal range: Late Cretaceous (Maastrichtian), 70–66 Ma
Mounted Skeleton, Stony Brook University
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Clade: Dinosauria
Clade: Saurischia
Clade: Theropoda
Clade: Abelisauria
Family: Abelisauridae
Subfamily: Majungasaurinae
Genus: Majungasaurus
Lavocat, 1955
Species:
M. crenatissimus
Binomial name
Majungasaurus crenatissimus
(Depéret, 1896) [originally Megalosaurus]
Synonyms
  • Megalosaurus crenatissimus
    Depéret, 1896
  • Majungatholus atopus
    Sues & Taquet, 1979

Like other abelisaurids, Majungasaurus was a bipedal predator with a short snout. Although the forelimbs are not completely known, they were very short, while the hind limbs were longer and very stocky. It can be distinguished from other abelisaurids by its wider skull, the very rough texture and thickened bone on the top of its snout, and the single rounded horn on the roof of its skull, which was originally mistaken for the dome of a pachycephalosaur. It also had more teeth in both upper and lower jaws than most abelisaurids.

The genus is one of the first abelisaurs to be discovered, first being found in 1896 (although it was thought to be a species of Megalosaurus) and being named in 1955. Known from several well-preserved skulls and abundant skeletal material, Majungasaurus has recently become one of the best-studied theropod dinosaurs from the Southern Hemisphere. It appears to be most closely related to abelisaurids from India rather than South America or continental Africa, a fact that has important biogeographical implications. Majungasaurus was the apex predator in its ecosystem, mainly preying on sauropods like Rapetosaurus, and is also one of the few dinosaurs for which there is direct evidence of cannibalism.

Discovery and naming edit

 
Original material described in 1896

French paleontologist Charles Depéret described the first theropod remains from northwestern Madagascar in 1896. These included two teeth, a claw, and some vertebrae discovered along the Betsiboka River by a French army officer and deposited in the collection of what is now the Université Claude Bernard Lyon 1. Depéret referred these fossils to the genus Megalosaurus, which at the time was a wastebasket taxon containing any number of unrelated large theropods, as the new species M. crenatissimus.[1] This name is derived from the Latin word crenatus ("notched") and the suffix -issimus ("most"), in reference to the numerous serrations on both front and rear edges of the teeth.[2] Depéret later reassigned the species to the North American genus Dryptosaurus, another poorly known taxon.[3]

 
Neotype specimen of M. crenatissimus (MNHN.MAJ 1), the right dentary of a subadult individual – Muséum national d'histoire naturelle, Paris

Numerous fragmentary remains from Mahajanga Province in northwestern Madagascar were recovered by French collectors over the next 100 years, many of which were deposited in the Muséum National d'Histoire Naturelle in Paris.[2] In 1955, René Lavocat described a theropod dentary (MNHN.MAJ 1) with teeth from the Maevarano Formation in the same region where the original material was found. The teeth matched those first described by Depéret, but the strongly curved jaw bone was very different from both Megalosaurus and Dryptosaurus. Based on this dentary, Lavocat created the new genus Majungasaurus, using an older spelling of Mahajanga as well as the Greek word σαυρος sauros (meaning "lizard").[4] Hans-Dieter Sues and Philippe Taquet described a dome-shaped skull fragment (MNHN.MAJ 4) as a new genus of pachycephalosaur (Majungatholus atopus) in 1979. This was the first report of a pachycephalosaur in the Southern Hemisphere.[5]

In 1993, scientists from the State University of New York at Stony Brook and the University of Antananarivo began the Mahajanga Basin Project, a series of expeditions to examine the fossils and geology of the Late Cretaceous sediments near the village of Berivotra, in Mahajanga Province.[2] Among these scientists was paleontologist David W. Krause of Stony Brook. The first expedition turned up hundreds of theropod teeth identical to those of Majungasaurus, some of which were attached to an isolated premaxilla that was described in 1996.[6] The following seven expeditions would turn up tens of thousands of fossils, many of which belonged to species new to science. The Mahajanga Basin Project claims credit for quintupling the known diversity of fossil taxa in the region.[2]

 
Type specimen of Majungatholus atopus: a Majungasaurus frontal horn misidentified as a pachycephalosaur dome (MNHN.MAJ 1)

Fieldwork in 1996 turned up a spectacularly complete theropod skull preserved in exquisite detail (FMNH PR 2100). On top of this skull was a dome-shaped swelling nearly identical to the one described by Sues and Taquet as Majungatholus atopus. Majungatholus was redescribed as an abelisaurid rather than a pachycephalosaur in 1998. Although the name Majungasaurus crenatissimus was older than Majungatholus atopus, the authors judged the type dentary of Majungasaurus too fragmentary to confidently assign to the same species as the skull.[7] Further fieldwork over the next decade turned up a series of less complete skulls, as well as dozens of partial skeletons of individuals ranging from juveniles to adults. Project members also collected hundreds of isolated bones and thousands of shed Majungasaurus teeth. Taken together, these remains represent nearly all the bones of the skeleton, although most of the forelimbs, most of the pelvis and the tip of the tail are still unknown.[2] This fieldwork culminated in a 2007 monograph consisting of seven scientific papers on all aspects of the animal's biology, published in the Society of Vertebrate Paleontology Memoirs. The papers are in English, although each has an abstract written in Malagasy.[8] In this volume, the dentary described by Lavocat was re-evaluated and determined to be diagnostic for this species. Therefore, the name Majungatholus was replaced by the older name Majungasaurus. Although the monograph is comprehensive, the editors noted that it describes only material recovered from 1993 through 2001. A significant quantity of specimens, some very complete, were excavated in 2003 and 2005 and await preparation and description in future publications.[2] The dentary was made the neotype specimen after a 2009 petition to the ICZN.[9][10]

Description edit

 
Majungasaurus compared in size to a human

Majungasaurus was a medium-sized theropod that typically reached 5.6–7 m (18–23 ft) in length and weighed 750–1,100 kg (1,650–2,430 lb).[2][11][12][13] Fragmentary remains of larger individuals indicate that some adults could have been similar in size to its relative Carnotaurus, possibly exceeding 8 m (26 ft) in length.[13]

The skull of Majungasaurus is exceptionally well known compared to most theropods and generally similar to that of other abelisaurids. Like other abelisaurid skulls, its length was proportionally short for its height, although not as short as in Carnotaurus. The skulls of large individuals measured 60–70 centimeters (24–28 in) long. The tall premaxilla (frontmost upper jaw bone), which made the tip of the snout very blunt, was also typical of the family. However, the skull of Majungasaurus was markedly wider than in other abelisaurids. All abelisaurids had a rough, sculptured texture on the outside faces of the skull bones, and Majungasaurus was no exception. This was carried to an extreme on the nasal bones of Majungasaurus, which were extremely thick and fused together, with a low central ridge running along the half of the bone closest to the nostrils. A distinctive dome-like horn protruded from the fused frontal bones on top of the skull as well. In life, these structures would have been covered with some sort of integument, possibly made of keratin. Computed tomography (CT scanning) of the skull shows that both the nasal structure and the frontal horn contained hollow sinus cavities, perhaps to reduce weight.[13] The teeth were typical of abelisaurids in having short crowns, although Majungasaurus bore seventeen teeth in both the maxilla of the upper jaw and the dentary of the lower jaw, more than in any other abelisaurid except Rugops.[14]

 
Life restoration

The postcranial skeleton of Majungasaurus closely resembles those of Carnotaurus and Aucasaurus, the only other abelisaurid genera for which complete skeletal material is known. Majungasaurus was bipedal, with a long tail to balance out the head and torso, putting the center of gravity over the hips. Although the cervical (neck) vertebrae had numerous cavities and excavations (pleurocoels) to reduce their weight, they were robust, with exaggerated muscle attachment sites and ribs that interlocked for strength. Ossified tendons attached to the cervical ribs, giving them a forked appearance, as seen in Carnotaurus. All of these features resulted in a very strong and muscular neck. Uniquely, the cervical ribs of Majungasaurus had long depressions along the sides for weight reduction.[15] The humerus (upper arm bone) was short and curved, closely resembling those of Aucasaurus and Carnotaurus. Also like related dinosaurs, Majungasaurus had very short forelimbs with four extremely reduced digits, first reported with only two very short external fingers and no claws.[16] The hand and finger bones of Majungasaurus, like other majungasaurines, lacked the characteristic pits and grooves where claws and tendons would normally attach, and its finger bones were fused together, indicating that the hand was immobile.[17] In 2012, a better specimen was described, showing that the lower arm was robust, though short, and that the hand contained four metatarsals and four, probably inflexible and very reduced, fingers, possibly with no claws. The minimum phalanx formula was 1-2-1-1.[18]

Like other abelisaurids, the hindlimbs were stocky and short compared to body length. The tibia (lower leg bone) of Majungasaurus was even stockier than that of its relative Carnotaurus, with a prominent crest on the knee. The astragalus and calcaneum (ankle bones) were fused together, and the feet bore three functional digits, with a smaller first digit that did not contact the ground.[19]

Classification and systematics edit

Majungasaurus is classified as a member of the theropod clade Abelisauridae, which is considered a family in Linnaean taxonomy. Along with the family Noasauridae, abelisaurids are included in the superfamily Abelisauroidea, which is in turn a subdivision of the infraorder Ceratosauria.[2][20] Abelisaurids are known for their tall skulls with blunt snouts, extensive sculpturing on the outer surfaces of the facial bones (convergent with carcharodontosaurids), very reduced (atrophied) forelimbs (convergent with tyrannosaurids), and stocky hindlimb proportions, among other features.[21]

As with many dinosaur families, the systematics (evolutionary relationships) within the family Abelisauridae are confused. Several cladistic studies have indicated that Majungasaurus shares a close relationship with Carnotaurus from South America,[20][21] while others were unable to firmly place it in the phylogeny.[22] The most recent analysis, using the most complete information, instead recovered Majungasaurus in a clade with Rajasaurus and Indosaurus from India, but excluding South American genera like Carnotaurus, Ilokelesia, Ekrixinatosaurus, Aucasaurus and Abelisaurus, as well as Rugops from mainland Africa. This leaves open the possibility of separate clades of abelisaurids in western and eastern Gondwana.[2]

 
Skeletal restoration showing known elements of two specimens

A cladogram by Tortosa et al. 2013 places Majungasaurus in a new subfamily, Majungasaurinae. A simplified version showing the taxa within the group is shown below.[23]

Majungasaurinae

Pourcieux abelisaurid

Arcovenator  

Majungasaurus  

Indosaurus

Rahiolisaurus

Rajasaurus  

Paleobiology edit

Skull ornamentation edit

 
Skull cast of FMNH PR 2100

Majungasaurus is perhaps most distinctive for its skull ornamentation, including the swollen and fused nasals and the frontal horn. Other ceratosaurs, including Carnotaurus, Rajasaurus, and Ceratosaurus itself bore crests on the head. These structures are likely to have played a role in intraspecific competition, although their exact function within that context is unknown. The hollow cavity inside the frontal horn of Majungasaurus would have weakened the structure and probably precluded its use in direct physical combat, although the horn may have served a display purpose.[21] While there is variation in the ornamentation of Majungasaurus individuals, there is no evidence for sexual dimorphism.[13]

Feeding edit

 
Restoration of two Majungasaurus chasing a Rapetosaurus

Scientists have suggested that the unique skull shape of Majungasaurus and other abelisaurids indicate different predatory habits than other theropods. Whereas most theropods were characterized by long, low skulls of narrow width, abelisaurid skulls were taller and wider, and often shorter in length as well.[13] The narrow skulls of other theropods were well equipped to withstand the vertical stress of a powerful bite, but not as good at withstanding torsion (twisting).[24] In comparison to modern mammalian predators, most theropods may have used a strategy similar in some ways to that of long- and narrow-snouted canids, with the delivery of many bites weakening the prey animal.[25]

Abelisaurids, especially Majungasaurus, may instead have been adapted for a feeding strategy more similar to modern felids, with short and broad snouts, that bite once and hold on until the prey is subdued. Majungasaurus had an even broader snout than other abelisaurids, and other aspects of its anatomy may also support the bite-and-hold hypothesis. The neck was strengthened, with robust vertebrae, interlocking ribs and ossified tendons, as well as reinforced muscle attachment sites on the vertebrae and the back of the skull. These muscles would have been able to hold the head steady despite the struggles of its prey.

Abelisaurid skulls were also strengthened in many areas by bone mineralized out of the skin, creating the characteristic rough texture of the bones. This is particularly true of Majungasaurus, where the nasal bones were fused and thickened for strength. On the other hand, the lower jaw of Majungasaurus sported a large fenestra (opening) on each side, as seen in other ceratosaurs, as well as synovial joints between certain bones that allowed a high degree of flexibility in the lower jaw, although not to the extent seen in snakes. This may have been an adaptation to prevent the fracture of the lower jaw when holding onto a struggling prey animal. The front teeth of the upper jaw were more robust than the rest, to provide an anchor point for the bite, while the low crown height of Majungasaurus teeth prevented them from breaking off during a struggle. Finally, unlike the teeth of Allosaurus and most other theropods, which were curved on both the front and back, abelisaurids like Majungasaurus had teeth curved on the front edge but straighter on the back (cutting) edge. This structure may have served to prevent slicing, and instead holding the teeth in place when biting.[13] Examination of the teeth of Majungasaurus indicates that the theropod replaced its teeth anywhere from 2 to 13 times faster than other theropods, replacing the entire set within a span of two months. Gnawing on bone may have been a significant reason for such rapid tooth replacement.[26]

 
Mounted skeletons of Majungasaurus and Rapetosaurus

Majungasaurus was the largest predator in its environment, while the only known large herbivores at the time were sauropods like Rapetosaurus. Scientists have suggested that Majungasaurus, and perhaps other abelisaurids, specialized on hunting sauropods. Adaptations to strengthen the head and neck for a bite-and-hold type of attack might have been very useful against sauropods, which would have been tremendously powerful animals. This hypothesis may also be supported by the hindlegs of Majungasaurus, which were short and stocky, as opposed to the longer and more slender legs of most other theropods. While Majungasaurus would not have moved as fast as other similar-sized theropods, it would have had no trouble keeping up with slow-moving sauropods. The robust hindlimb bones suggest very powerful legs, and their shorter length would have lowered the animal's center of gravity. Thus Majungasaurus may have sacrificed speed for power.[13] Majungasaurus tooth marks on Rapetosaurus bones confirm that it at least fed on these sauropods, whether or not it actually killed them.[27]

Cannibalism edit

Although sauropods may have been the prey of choice for Majungasaurus, discoveries published in 2007 detail finds in Madagascar that indicate the presence of other Majungasaurus in their diet. Numerous bones of Majungasaurus have been discovered bearing tooth marks identical to those found on sauropod bones from the same localities. These marks have the same spacing as teeth in Majungasaurus jaws, are of the same size as Majungasaurus teeth, and contain smaller notches consistent with the serrations on those teeth. As Majungasaurus is the only large theropod known from the area, the simplest explanation is that it was feeding on other members of its own species.[27] Suggestions that the Triassic Coelophysis was a cannibal have been recently disproven, leaving Majungasaurus as the only non-avian theropod with confirmed cannibalistic tendencies,[28] although there is some evidence that cannibalism may have occurred in other species as well.[29]

It is unknown if Majungasaurus actively hunted their own kind or only scavenged their carcasses.[27] However, some researchers have noted that modern Komodo monitors sometimes kill each other when competing for access to carcasses. The lizards will then proceed to cannibalize the remains of their rivals, which may suggest similar behavior in Majungasaurus and other theropods.[29]

Respiratory system edit

 
Comparison between the air sacs of Majungasaurus and a modern bird

Scientists have reconstructed the respiratory system of Majungasaurus based on a superbly preserved series of vertebrae (UA 8678) recovered from the Maevarano Formation. Most of these vertebrae and some of the ribs contained cavities (pneumatic foramina) that may have resulted from the infiltration of avian-style lungs and air sacs. In birds, the neck vertebrae and ribs are hollowed out by the cervical air sac, the upper back vertebrae by the lung, and the lower back and sacral (hip) vertebrae by the abdominal air sac. Similar features in Majungasaurus vertebrae imply the presence of these air sacs. These air sacs may have allowed for a basic form of avian-style 'flow-through ventilation,' where air flow through the lungs is one-way, so that oxygen-rich air inhaled from outside the body is never mixed with exhaled air laden with carbon dioxide. This method of respiration, while complicated, is highly efficient.[30]

The recognition of pneumatic foramina in Majungasaurus, besides providing an understanding of its respiratory biology, also has larger-scale implications for evolutionary biology. The split between the ceratosaur line, which led to Majungasaurus, and the tetanuran line, to which birds belong, occurred very early in the history of theropods. The avian respiratory system, present in both lines, must therefore have evolved before the split, and well before the evolution of birds themselves. This provides further evidence of the dinosaurian origin of birds.[30]

Brain and inner ear structure edit

 
Head and neck of specimen FMNH PR 2836

Computed tomography, also known as CT scanning, of a complete Majungasaurus skull (FMNH PR 2100) allowed a rough reconstruction of its brain and inner ear structure. Overall, the brain was very small relative to body size, but otherwise similar to many other non-coelurosaurian theropods, with a very conservative form closer to modern crocodilians than to birds. One difference between Majungasaurus and other theropods was its smaller flocculus, a region of the cerebellum that helps to coordinate movements of the eye with movements of the head. This suggests that Majungasaurus and other abelisaurids like Indosaurus, which also had a small flocculus, did not rely on quick head movements to sight and capture prey.[13]

Inferences about behavior can also be drawn from examination of the inner ear. The semicircular canals within the inner ear aid in balance, and the lateral semicircular canal is usually parallel to the ground when the animal holds its head in an alert posture. When the skull of Majungasaurus is rotated so that its lateral canal is parallel to the ground, the entire skull is nearly horizontal. This contrasts with many other theropods, where the head was more strongly downturned when in the alert position. The lateral canal is also significantly longer in Majungasaurus than in its more basal relative Ceratosaurus, indicating a greater sensitivity to side-to-side motions of the head.[13]

Pathology edit

A 2007 report described pathologies in the bones of Majungasaurus. Scientists examined the remains of at least 21 individuals and discovered four with noticeable pathologies.[31] While pathology had been studied in large tetanuran theropods like allosaurids and tyrannosaurids,[32] this was the first time an abelisauroid had been examined in this manner. No wounds were found on any skull elements, in contrast to tyrannosaurids where sometimes gruesome facial bites were common. One of the specimens was a phalanx (toe bone) of the foot, which had apparently been broken and subsequently healed.[31]

Most of the pathologies occurred on the vertebrae. For example, a dorsal (back) vertebra from a juvenile animal showed an exostosis (bony growth) on its underside. The growth probably resulted from the conversion of cartilage or a ligament to bone during development, but the cause of the ossification was not determined. Hypervitaminosis A and bone spurs were ruled out, and an osteoma (benign bone tumor) was deemed unlikely. Another specimen, a small caudal (tail) vertebra, was also found to have an abnormal growth, this time on the top of its neural spine, which projects upwards from the vertebrae, allowing muscle attachment.[31] Similar growths from the neural spine have been found in specimens of Allosaurus[33] and Masiakasaurus, probably resulting from the ossification of a ligament running either between the neural spines (interspinal ligament) or along their tops (supraspinal ligament).[31]

The most serious pathology discovered was in a series of five large tail vertebrae. The first two vertebrae showed only minor abnormalities with the exception of a large groove that extended along the left side of both bones. However, the next three vertebrae were completely fused together at many different points, forming a solid bony mass. There is no sign of any other vertebrae after the fifth in the series, indicating that the tail ended there prematurely. From the size of the last vertebrae, scientists judged that about ten vertebrae were lost. One explanation for this pathology is severe physical trauma resulting in the loss of the tail tip, followed by osteomyelitis (infection) of the last remaining vertebrae. Alternatively, the infection may have come first and led to the end of the tail becoming necrotic and falling off. This is the first example of tail truncation known in a non-avian theropod dinosaur.[31]

The small number of specimens preserved with pathologies in Majungasaurus suggest that the multitude of injuries that occurred were obtained over the course of the lives of the individuals studied. Furthermore, the small number of injured Majungasaurus specimens observed amongst those recovered indicates most well preserved individuals generally lack observable pathologies, while a few select individuals were shown to have possessed multiple pathologies, a general pattern also noted in other large, nonavian theropods. Such patterns may be the result of a snowball effect where one injury or an infection increased the likelihood of additional maladies and injuries due to functional impairment or compromised immune systems in individuals once an initial injury had occurred.[34]

Ontogeny and growth edit

 
Restoration of an adult

Majungasaurus, being known from many well-preserved specimens of different ages, is well studied in regards to its growth and development. Throughout ontogeny, the skull of Majungasaurus (more specifically, the jugal, postorbital, and quadratojugal) seems to have become taller and more robust; additionally, the skull bones became more fused and the eye sockets became proportionally smaller. This indicates a shift in dietary preferences between juveniles and adults.[35]

Research by Michael D'Emic et al indicates that it was among the slowest-growing theropods. Based on studies of the lines of arrested growth in several bones, it was found that Majungasaurus took twenty years to reach maturity, which may have been a result of the harsh environment in which it lived. However, other abelisaurids have also been found to have comparably slow growth rates.[36]

Paleoecology edit

 
All Majungasaurus fossils have been found in the Mahajanga Province of Madagascar, most within 50 kilometers (31 mi) to the southeast of the provincial capital, Mahajanga (marked with a red dot on the map).

All specimens of Majungasaurus have been recovered from the Maevarano Formation in the Mahajanga Province in northwestern Madagascar. Most of these, including all of the most complete material, came from the Anembalemba Member, although Majungasaurus teeth have also been found in the underlying Masorobe Member and the overlying Miadana Member. While these sediments have not been dated radiometrically, evidence from biostratigraphy and paleomagnetism suggest that they were deposited during the Maastrichtian stage, which lasted from 70 to 66 Ma (million years ago). Majungasaurus teeth are found up until the very end of the Maastrichtian, when all non-avian dinosaurs became extinct.[37]

Then as now, Madagascar was an island, having separated from the Indian subcontinent less than 20 million years earlier. It was drifting northwards but still 10 to 15 degrees more southerly in latitude than it is today. The prevailing climate of the time was semi-arid, with pronounced seasonality in temperature and rainfall. Majungasaurus inhabited a coastal flood plain cut by many sandy river channels.[37] Strong geological evidence suggests the occurrence of periodic debris flows through these channels at the beginning of the wet season, burying the carcasses of organisms killed during the preceding dry season and providing for their exceptional preservation as fossils.[38] Sea levels in the area were rising throughout the Maastrichtian, and would continue to do so into the Paleocene Epoch, so Majungasaurus may have roamed coastal environments like tidal flats as well. The neighboring Berivotra Formation represents the contemporaneous marine environment.[37]

Besides Majungasaurus, fossil taxa recovered from the Maevarano include fish, frogs, lizards, snakes,[37] seven distinct species of crocodylomorphs,[39] five or six species of mammals,[39] Vorona[40] and several other birds,[37] the possibly flighted dromaeosaurid Rahonavis,[41][42] the noasaurid Masiakasaurus[43] and two titanosaurian sauropods, including Rapetosaurus.[44] Majungasaurus was by far the largest carnivore and probably the dominant predator on land, although large crocodylomorphs like Mahajangasuchus and Trematochampsa might have competed with it closer to water.[37]

See also edit

References edit

  1. ^ Depéret, Charles (1896). "Note sur les Dinosauriens Sauropodes et Théropodes du Crétacé supérieur de Madagascar" [Note on the Dinosaurs Sauropods and Theropods of the Upper Cretaceous of Madagascar]. Bulletin de la Société Géologique de France (in French). 21: 176–194.
  2. ^ a b c d e f g h i Krause, David W.; Sampson, Scott D.; Carrano, Matthew T.; O'Connor, Patrick M. (2007). "Overview of the history of discovery, taxonomy, phylogeny, and biogeography of Majungasaurus crenatissimus (Theropoda: Abelisauridae) from the Late Cretaceous of Madagascar". In Sampson, Scott D.; Krause, David W. (eds.). Majungasaurus crenatissimus (Theropoda: Abelisauridae) from the Late Cretaceous of Madagascar. Society of Vertebrate Paleontology Memoir 8. Vol. 27. Journal of Vertebrate Paleontology. pp. 1–20. doi:10.1671/0272-4634(2007)27[1:OOTHOD]2.0.CO;2. S2CID 13274054.
  3. ^ Depéret, Charles; Savornin, Justin (1928). "La faune de Reptiles et de Poissons albiens de Timimoun (Sahara algérien)" [The fauna of Reptiles and Albian Fish of Timimoun (Algerian Sahara)]. Bulletin de la Société Géologique de France (in French). 27: 257–265.
  4. ^ Lavocat, René (1955). "Sur une portion de mandibule de Théropode provenant du Crétacé supérieur de Madagascar" [On a portion of Theropod's mandible from the Upper Cretaceous of Madagascar]. Bulletin du Muséum National d'Histoire Naturelle (in French). 27: 256–259.
  5. ^ Sues, Hans-Dieter; Taquet, Phillipe (1979). "A pachycephalosaurid dinosaur from Madagascar and a Laurasia−Gondwanaland connection in the Cretaceous". Nature. 279 (5714): 633–635. Bibcode:1979Natur.279..633S. doi:10.1038/279633a0. S2CID 4345348.
  6. ^ Sampson, Scott D.; Krause, David W.; Dodson, Peter; Forster, Catherine A. (1996). . Journal of Vertebrate Paleontology. 16 (4): 601–605. Bibcode:1996JVPal..16..601S. doi:10.1080/02724634.1996.10011350. Archived from the original on September 27, 2007.
  7. ^ Sampson, S. D. (May 15, 1998). "Predatory Dinosaur Remains from Madagascar: Implications for the Cretaceous Biogeography of Gondwana". Science. 280 (5366): 1048–1051. Bibcode:1998Sci...280.1048S. doi:10.1126/science.280.5366.1048. PMID 9582112. S2CID 22449613.
  8. ^ Sampson, Scott D.; Krause, David W., eds. (2007). "Majungasaurus crenatissimus (Theropoda:Abelisauridae) from the late Cretaceous of Madagascar". Journal of Vertebrate Paleontology. 27 (Supplement 2). Society of Vertebrate Paleontology: 1–184. doi:10.1671/0272-4634(2007)27[1:OOTHOD]2.0.CO;2. OCLC 1026511658. S2CID 13274054.
  9. ^ Carrano, Matthew T.; Krause, David W.; O'Connor, Patrick M.; Sampson, Scott D. (September 2009). "Case 3487: Megalosaurus crenatissimus Depéret, 1896 (currently Majungasaurus crenatissimus; Dinosauria, Theropoda): proposed replacement of the holotype by a neotype". The Bulletin of Zoological Nomenclature. 66 (3): 261–264. doi:10.21805/bzn.v66i3.a7. S2CID 83535309.
  10. ^ "Opinion 2269 (Case 3487): Megalosaurus crenatissimus Depéret, 1896 (currently Majungasaurus crenatissimus; Dinosauria, Theropoda): designation of a neotype". The Bulletin of Zoological Nomenclature. 68 (1): 89–90. March 2011. doi:10.21805/bzn.v68i1.a7. S2CID 87394881.
  11. ^ Grillo, O.N.; Delcourt, R. (2016). "Allometry and body length of abelisauroid theropods: Pycnonemosaurus nevesi is the new king". Cretaceous Research. 69: 71–89. doi:10.1016/j.cretres.2016.09.001.
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External links edit

January 01, 1970
majungasaurus, ɔː, mahajanga, lizard, genus, abelisaurid, theropod, dinosaur, that, lived, madagascar, from, million, years, cretaceous, period, making, last, known, avian, dinosaurs, that, went, extinct, during, cretaceous, paleogene, extinction, event, genus. Majungasaurus m e ˌ dʒ ʌ ŋ ɡ e ˈ s ɔː r e s lit Mahajanga lizard is a genus of abelisaurid theropod dinosaur that lived in Madagascar from 70 to 66 million years ago at the end of the Cretaceous Period making it one of the last known non avian dinosaurs that went extinct during the Cretaceous Paleogene extinction event The genus contains a single species Majungasaurus crenatissimus This dinosaur is also called Majungatholus a name which is considered a junior synonym of Majungasaurus MajungasaurusTemporal range Late Cretaceous Maastrichtian 70 66 Ma PreꞒ Ꞓ O S D C P T J K Pg N Mounted Skeleton Stony Brook University Scientific classification Domain Eukaryota Kingdom Animalia Phylum Chordata Clade Dinosauria Clade Saurischia Clade Theropoda Clade Abelisauria Family Abelisauridae Subfamily Majungasaurinae Genus MajungasaurusLavocat 1955 Species M crenatissimus Binomial name Majungasaurus crenatissimus Deperet 1896 originally Megalosaurus Synonyms Megalosaurus crenatissimusDeperet 1896 Majungatholus atopusSues amp Taquet 1979 Like other abelisaurids Majungasaurus was a bipedal predator with a short snout Although the forelimbs are not completely known they were very short while the hind limbs were longer and very stocky It can be distinguished from other abelisaurids by its wider skull the very rough texture and thickened bone on the top of its snout and the single rounded horn on the roof of its skull which was originally mistaken for the dome of a pachycephalosaur It also had more teeth in both upper and lower jaws than most abelisaurids The genus is one of the first abelisaurs to be discovered first being found in 1896 although it was thought to be a species of Megalosaurus and being named in 1955 Known from several well preserved skulls and abundant skeletal material Majungasaurus has recently become one of the best studied theropod dinosaurs from the Southern Hemisphere It appears to be most closely related to abelisaurids from India rather than South America or continental Africa a fact that has important biogeographical implications Majungasaurus was the apex predator in its ecosystem mainly preying on sauropods like Rapetosaurus and is also one of the few dinosaurs for which there is direct evidence of cannibalism Contents 1 Discovery and naming 2 Description 3 Classification and systematics 4 Paleobiology 4 1 Skull ornamentation 4 2 Feeding 4 3 Cannibalism 4 4 Respiratory system 4 5 Brain and inner ear structure 4 6 Pathology 4 7 Ontogeny and growth 5 Paleoecology 6 See also 7 References 8 External linksDiscovery and naming edit nbsp Original material described in 1896 French paleontologist Charles Deperet described the first theropod remains from northwestern Madagascar in 1896 These included two teeth a claw and some vertebrae discovered along the Betsiboka River by a French army officer and deposited in the collection of what is now the Universite Claude Bernard Lyon 1 Deperet referred these fossils to the genus Megalosaurus which at the time was a wastebasket taxon containing any number of unrelated large theropods as the new species M crenatissimus 1 This name is derived from the Latin word crenatus notched and the suffix issimus most in reference to the numerous serrations on both front and rear edges of the teeth 2 Deperet later reassigned the species to the North American genus Dryptosaurus another poorly known taxon 3 nbsp Neotype specimen of M crenatissimus MNHN MAJ 1 the right dentary of a subadult individual Museum national d histoire naturelle Paris Numerous fragmentary remains from Mahajanga Province in northwestern Madagascar were recovered by French collectors over the next 100 years many of which were deposited in the Museum National d Histoire Naturelle in Paris 2 In 1955 Rene Lavocat described a theropod dentary MNHN MAJ 1 with teeth from the Maevarano Formation in the same region where the original material was found The teeth matched those first described by Deperet but the strongly curved jaw bone was very different from both Megalosaurus and Dryptosaurus Based on this dentary Lavocat created the new genus Majungasaurus using an older spelling of Mahajanga as well as the Greek word sayros sauros meaning lizard 4 Hans Dieter Sues and Philippe Taquet described a dome shaped skull fragment MNHN MAJ 4 as a new genus of pachycephalosaur Majungatholus atopus in 1979 This was the first report of a pachycephalosaur in the Southern Hemisphere 5 In 1993 scientists from the State University of New York at Stony Brook and the University of Antananarivo began the Mahajanga Basin Project a series of expeditions to examine the fossils and geology of the Late Cretaceous sediments near the village of Berivotra in Mahajanga Province 2 Among these scientists was paleontologist David W Krause of Stony Brook The first expedition turned up hundreds of theropod teeth identical to those of Majungasaurus some of which were attached to an isolated premaxilla that was described in 1996 6 The following seven expeditions would turn up tens of thousands of fossils many of which belonged to species new to science The Mahajanga Basin Project claims credit for quintupling the known diversity of fossil taxa in the region 2 nbsp Type specimen of Majungatholus atopus a Majungasaurus frontal horn misidentified as a pachycephalosaur dome MNHN MAJ 1 Fieldwork in 1996 turned up a spectacularly complete theropod skull preserved in exquisite detail FMNH PR 2100 On top of this skull was a dome shaped swelling nearly identical to the one described by Sues and Taquet as Majungatholus atopus Majungatholus was redescribed as an abelisaurid rather than a pachycephalosaur in 1998 Although the name Majungasaurus crenatissimus was older than Majungatholus atopus the authors judged the type dentary of Majungasaurus too fragmentary to confidently assign to the same species as the skull 7 Further fieldwork over the next decade turned up a series of less complete skulls as well as dozens of partial skeletons of individuals ranging from juveniles to adults Project members also collected hundreds of isolated bones and thousands of shed Majungasaurus teeth Taken together these remains represent nearly all the bones of the skeleton although most of the forelimbs most of the pelvis and the tip of the tail are still unknown 2 This fieldwork culminated in a 2007 monograph consisting of seven scientific papers on all aspects of the animal s biology published in the Society of Vertebrate Paleontology Memoirs The papers are in English although each has an abstract written in Malagasy 8 In this volume the dentary described by Lavocat was re evaluated and determined to be diagnostic for this species Therefore the name Majungatholus was replaced by the older name Majungasaurus Although the monograph is comprehensive the editors noted that it describes only material recovered from 1993 through 2001 A significant quantity of specimens some very complete were excavated in 2003 and 2005 and await preparation and description in future publications 2 The dentary was made the neotype specimen after a 2009 petition to the ICZN 9 10 Description edit nbsp Majungasaurus compared in size to a human Majungasaurus was a medium sized theropod that typically reached 5 6 7 m 18 23 ft in length and weighed 750 1 100 kg 1 650 2 430 lb 2 11 12 13 Fragmentary remains of larger individuals indicate that some adults could have been similar in size to its relative Carnotaurus possibly exceeding 8 m 26 ft in length 13 The skull of Majungasaurus is exceptionally well known compared to most theropods and generally similar to that of other abelisaurids Like other abelisaurid skulls its length was proportionally short for its height although not as short as in Carnotaurus The skulls of large individuals measured 60 70 centimeters 24 28 in long The tall premaxilla frontmost upper jaw bone which made the tip of the snout very blunt was also typical of the family However the skull of Majungasaurus was markedly wider than in other abelisaurids All abelisaurids had a rough sculptured texture on the outside faces of the skull bones and Majungasaurus was no exception This was carried to an extreme on the nasal bones of Majungasaurus which were extremely thick and fused together with a low central ridge running along the half of the bone closest to the nostrils A distinctive dome like horn protruded from the fused frontal bones on top of the skull as well In life these structures would have been covered with some sort of integument possibly made of keratin Computed tomography CT scanning of the skull shows that both the nasal structure and the frontal horn contained hollow sinus cavities perhaps to reduce weight 13 The teeth were typical of abelisaurids in having short crowns although Majungasaurus bore seventeen teeth in both the maxilla of the upper jaw and the dentary of the lower jaw more than in any other abelisaurid except Rugops 14 nbsp Life restoration The postcranial skeleton of Majungasaurus closely resembles those of Carnotaurus and Aucasaurus the only other abelisaurid genera for which complete skeletal material is known Majungasaurus was bipedal with a long tail to balance out the head and torso putting the center of gravity over the hips Although the cervical neck vertebrae had numerous cavities and excavations pleurocoels to reduce their weight they were robust with exaggerated muscle attachment sites and ribs that interlocked for strength Ossified tendons attached to the cervical ribs giving them a forked appearance as seen in Carnotaurus All of these features resulted in a very strong and muscular neck Uniquely the cervical ribs of Majungasaurus had long depressions along the sides for weight reduction 15 The humerus upper arm bone was short and curved closely resembling those of Aucasaurus and Carnotaurus Also like related dinosaurs Majungasaurus had very short forelimbs with four extremely reduced digits first reported with only two very short external fingers and no claws 16 The hand and finger bones of Majungasaurus like other majungasaurines lacked the characteristic pits and grooves where claws and tendons would normally attach and its finger bones were fused together indicating that the hand was immobile 17 In 2012 a better specimen was described showing that the lower arm was robust though short and that the hand contained four metatarsals and four probably inflexible and very reduced fingers possibly with no claws The minimum phalanx formula was 1 2 1 1 18 Like other abelisaurids the hindlimbs were stocky and short compared to body length The tibia lower leg bone of Majungasaurus was even stockier than that of its relative Carnotaurus with a prominent crest on the knee The astragalus and calcaneum ankle bones were fused together and the feet bore three functional digits with a smaller first digit that did not contact the ground 19 Classification and systematics editMajungasaurus is classified as a member of the theropod clade Abelisauridae which is considered a family in Linnaean taxonomy Along with the family Noasauridae abelisaurids are included in the superfamily Abelisauroidea which is in turn a subdivision of the infraorder Ceratosauria 2 20 Abelisaurids are known for their tall skulls with blunt snouts extensive sculpturing on the outer surfaces of the facial bones convergent with carcharodontosaurids very reduced atrophied forelimbs convergent with tyrannosaurids and stocky hindlimb proportions among other features 21 As with many dinosaur families the systematics evolutionary relationships within the family Abelisauridae are confused Several cladistic studies have indicated that Majungasaurus shares a close relationship with Carnotaurus from South America 20 21 while others were unable to firmly place it in the phylogeny 22 The most recent analysis using the most complete information instead recovered Majungasaurus in a clade with Rajasaurus and Indosaurus from India but excluding South American genera like Carnotaurus Ilokelesia Ekrixinatosaurus Aucasaurus and Abelisaurus as well as Rugops from mainland Africa This leaves open the possibility of separate clades of abelisaurids in western and eastern Gondwana 2 nbsp Skeletal restoration showing known elements of two specimens A cladogram by Tortosa et al 2013 places Majungasaurus in a new subfamily Majungasaurinae A simplified version showing the taxa within the group is shown below 23 Majungasaurinae Pourcieux abelisaurid Arcovenator nbsp Majungasaurus nbsp Indosaurus Rahiolisaurus Rajasaurus nbsp Paleobiology editSkull ornamentation edit nbsp Skull cast of FMNH PR 2100 Majungasaurus is perhaps most distinctive for its skull ornamentation including the swollen and fused nasals and the frontal horn Other ceratosaurs including Carnotaurus Rajasaurus and Ceratosaurus itself bore crests on the head These structures are likely to have played a role in intraspecific competition although their exact function within that context is unknown The hollow cavity inside the frontal horn of Majungasaurus would have weakened the structure and probably precluded its use in direct physical combat although the horn may have served a display purpose 21 While there is variation in the ornamentation of Majungasaurus individuals there is no evidence for sexual dimorphism 13 Feeding edit nbsp Restoration of two Majungasaurus chasing a Rapetosaurus Scientists have suggested that the unique skull shape of Majungasaurus and other abelisaurids indicate different predatory habits than other theropods Whereas most theropods were characterized by long low skulls of narrow width abelisaurid skulls were taller and wider and often shorter in length as well 13 The narrow skulls of other theropods were well equipped to withstand the vertical stress of a powerful bite but not as good at withstanding torsion twisting 24 In comparison to modern mammalian predators most theropods may have used a strategy similar in some ways to that of long and narrow snouted canids with the delivery of many bites weakening the prey animal 25 Abelisaurids especially Majungasaurus may instead have been adapted for a feeding strategy more similar to modern felids with short and broad snouts that bite once and hold on until the prey is subdued Majungasaurus had an even broader snout than other abelisaurids and other aspects of its anatomy may also support the bite and hold hypothesis The neck was strengthened with robust vertebrae interlocking ribs and ossified tendons as well as reinforced muscle attachment sites on the vertebrae and the back of the skull These muscles would have been able to hold the head steady despite the struggles of its prey Abelisaurid skulls were also strengthened in many areas by bone mineralized out of the skin creating the characteristic rough texture of the bones This is particularly true of Majungasaurus where the nasal bones were fused and thickened for strength On the other hand the lower jaw of Majungasaurus sported a large fenestra opening on each side as seen in other ceratosaurs as well as synovial joints between certain bones that allowed a high degree of flexibility in the lower jaw although not to the extent seen in snakes This may have been an adaptation to prevent the fracture of the lower jaw when holding onto a struggling prey animal The front teeth of the upper jaw were more robust than the rest to provide an anchor point for the bite while the low crown height of Majungasaurus teeth prevented them from breaking off during a struggle Finally unlike the teeth of Allosaurus and most other theropods which were curved on both the front and back abelisaurids like Majungasaurus had teeth curved on the front edge but straighter on the back cutting edge This structure may have served to prevent slicing and instead holding the teeth in place when biting 13 Examination of the teeth of Majungasaurus indicates that the theropod replaced its teeth anywhere from 2 to 13 times faster than other theropods replacing the entire set within a span of two months Gnawing on bone may have been a significant reason for such rapid tooth replacement 26 nbsp Mounted skeletons of Majungasaurus and Rapetosaurus Majungasaurus was the largest predator in its environment while the only known large herbivores at the time were sauropods like Rapetosaurus Scientists have suggested that Majungasaurus and perhaps other abelisaurids specialized on hunting sauropods Adaptations to strengthen the head and neck for a bite and hold type of attack might have been very useful against sauropods which would have been tremendously powerful animals This hypothesis may also be supported by the hindlegs of Majungasaurus which were short and stocky as opposed to the longer and more slender legs of most other theropods While Majungasaurus would not have moved as fast as other similar sized theropods it would have had no trouble keeping up with slow moving sauropods The robust hindlimb bones suggest very powerful legs and their shorter length would have lowered the animal s center of gravity Thus Majungasaurus may have sacrificed speed for power 13 Majungasaurus tooth marks on Rapetosaurus bones confirm that it at least fed on these sauropods whether or not it actually killed them 27 Cannibalism edit Although sauropods may have been the prey of choice for Majungasaurus discoveries published in 2007 detail finds in Madagascar that indicate the presence of other Majungasaurus in their diet Numerous bones of Majungasaurus have been discovered bearing tooth marks identical to those found on sauropod bones from the same localities These marks have the same spacing as teeth in Majungasaurus jaws are of the same size as Majungasaurus teeth and contain smaller notches consistent with the serrations on those teeth As Majungasaurus is the only large theropod known from the area the simplest explanation is that it was feeding on other members of its own species 27 Suggestions that the Triassic Coelophysis was a cannibal have been recently disproven leaving Majungasaurus as the only non avian theropod with confirmed cannibalistic tendencies 28 although there is some evidence that cannibalism may have occurred in other species as well 29 It is unknown if Majungasaurus actively hunted their own kind or only scavenged their carcasses 27 However some researchers have noted that modern Komodo monitors sometimes kill each other when competing for access to carcasses The lizards will then proceed to cannibalize the remains of their rivals which may suggest similar behavior in Majungasaurus and other theropods 29 Respiratory system edit nbsp Comparison between the air sacs of Majungasaurus and a modern bird Scientists have reconstructed the respiratory system of Majungasaurus based on a superbly preserved series of vertebrae UA 8678 recovered from the Maevarano Formation Most of these vertebrae and some of the ribs contained cavities pneumatic foramina that may have resulted from the infiltration of avian style lungs and air sacs In birds the neck vertebrae and ribs are hollowed out by the cervical air sac the upper back vertebrae by the lung and the lower back and sacral hip vertebrae by the abdominal air sac Similar features in Majungasaurus vertebrae imply the presence of these air sacs These air sacs may have allowed for a basic form of avian style flow through ventilation where air flow through the lungs is one way so that oxygen rich air inhaled from outside the body is never mixed with exhaled air laden with carbon dioxide This method of respiration while complicated is highly efficient 30 The recognition of pneumatic foramina in Majungasaurus besides providing an understanding of its respiratory biology also has larger scale implications for evolutionary biology The split between the ceratosaur line which led to Majungasaurus and the tetanuran line to which birds belong occurred very early in the history of theropods The avian respiratory system present in both lines must therefore have evolved before the split and well before the evolution of birds themselves This provides further evidence of the dinosaurian origin of birds 30 Brain and inner ear structure edit nbsp Head and neck of specimen FMNH PR 2836 Computed tomography also known as CT scanning of a complete Majungasaurus skull FMNH PR 2100 allowed a rough reconstruction of its brain and inner ear structure Overall the brain was very small relative to body size but otherwise similar to many other non coelurosaurian theropods with a very conservative form closer to modern crocodilians than to birds One difference between Majungasaurus and other theropods was its smaller flocculus a region of the cerebellum that helps to coordinate movements of the eye with movements of the head This suggests that Majungasaurus and other abelisaurids like Indosaurus which also had a small flocculus did not rely on quick head movements to sight and capture prey 13 Inferences about behavior can also be drawn from examination of the inner ear The semicircular canals within the inner ear aid in balance and the lateral semicircular canal is usually parallel to the ground when the animal holds its head in an alert posture When the skull of Majungasaurus is rotated so that its lateral canal is parallel to the ground the entire skull is nearly horizontal This contrasts with many other theropods where the head was more strongly downturned when in the alert position The lateral canal is also significantly longer in Majungasaurus than in its more basal relative Ceratosaurus indicating a greater sensitivity to side to side motions of the head 13 Pathology edit A 2007 report described pathologies in the bones of Majungasaurus Scientists examined the remains of at least 21 individuals and discovered four with noticeable pathologies 31 While pathology had been studied in large tetanuran theropods like allosaurids and tyrannosaurids 32 this was the first time an abelisauroid had been examined in this manner No wounds were found on any skull elements in contrast to tyrannosaurids where sometimes gruesome facial bites were common One of the specimens was a phalanx toe bone of the foot which had apparently been broken and subsequently healed 31 Most of the pathologies occurred on the vertebrae For example a dorsal back vertebra from a juvenile animal showed an exostosis bony growth on its underside The growth probably resulted from the conversion of cartilage or a ligament to bone during development but the cause of the ossification was not determined Hypervitaminosis A and bone spurs were ruled out and an osteoma benign bone tumor was deemed unlikely Another specimen a small caudal tail vertebra was also found to have an abnormal growth this time on the top of its neural spine which projects upwards from the vertebrae allowing muscle attachment 31 Similar growths from the neural spine have been found in specimens of Allosaurus 33 and Masiakasaurus probably resulting from the ossification of a ligament running either between the neural spines interspinal ligament or along their tops supraspinal ligament 31 The most serious pathology discovered was in a series of five large tail vertebrae The first two vertebrae showed only minor abnormalities with the exception of a large groove that extended along the left side of both bones However the next three vertebrae were completely fused together at many different points forming a solid bony mass There is no sign of any other vertebrae after the fifth in the series indicating that the tail ended there prematurely From the size of the last vertebrae scientists judged that about ten vertebrae were lost One explanation for this pathology is severe physical trauma resulting in the loss of the tail tip followed by osteomyelitis infection of the last remaining vertebrae Alternatively the infection may have come first and led to the end of the tail becoming necrotic and falling off This is the first example of tail truncation known in a non avian theropod dinosaur 31 The small number of specimens preserved with pathologies in Majungasaurus suggest that the multitude of injuries that occurred were obtained over the course of the lives of the individuals studied Furthermore the small number of injured Majungasaurus specimens observed amongst those recovered indicates most well preserved individuals generally lack observable pathologies while a few select individuals were shown to have possessed multiple pathologies a general pattern also noted in other large nonavian theropods Such patterns may be the result of a snowball effect where one injury or an infection increased the likelihood of additional maladies and injuries due to functional impairment or compromised immune systems in individuals once an initial injury had occurred 34 Ontogeny and growth edit nbsp Restoration of an adult Majungasaurus being known from many well preserved specimens of different ages is well studied in regards to its growth and development Throughout ontogeny the skull of Majungasaurus more specifically the jugal postorbital and quadratojugal seems to have become taller and more robust additionally the skull bones became more fused and the eye sockets became proportionally smaller This indicates a shift in dietary preferences between juveniles and adults 35 Research by Michael D Emic et al indicates that it was among the slowest growing theropods Based on studies of the lines of arrested growth in several bones it was found that Majungasaurus took twenty years to reach maturity which may have been a result of the harsh environment in which it lived However other abelisaurids have also been found to have comparably slow growth rates 36 Paleoecology edit nbsp All Majungasaurus fossils have been found in the Mahajanga Province of Madagascar most within 50 kilometers 31 mi to the southeast of the provincial capital Mahajanga marked with a red dot on the map All specimens of Majungasaurus have been recovered from the Maevarano Formation in the Mahajanga Province in northwestern Madagascar Most of these including all of the most complete material came from the Anembalemba Member although Majungasaurus teeth have also been found in the underlying Masorobe Member and the overlying Miadana Member While these sediments have not been dated radiometrically evidence from biostratigraphy and paleomagnetism suggest that they were deposited during the Maastrichtian stage which lasted from 70 to 66 Ma million years ago Majungasaurus teeth are found up until the very end of the Maastrichtian when all non avian dinosaurs became extinct 37 Then as now Madagascar was an island having separated from the Indian subcontinent less than 20 million years earlier It was drifting northwards but still 10 to 15 degrees more southerly in latitude than it is today The prevailing climate of the time was semi arid with pronounced seasonality in temperature and rainfall Majungasaurus inhabited a coastal flood plain cut by many sandy river channels 37 Strong geological evidence suggests the occurrence of periodic debris flows through these channels at the beginning of the wet season burying the carcasses of organisms killed during the preceding dry season and providing for their exceptional preservation as fossils 38 Sea levels in the area were rising throughout the Maastrichtian and would continue to do so into the Paleocene Epoch so Majungasaurus may have roamed coastal environments like tidal flats as well The neighboring Berivotra Formation represents the contemporaneous marine environment 37 Besides Majungasaurus fossil taxa recovered from the Maevarano include fish frogs lizards snakes 37 seven distinct species of crocodylomorphs 39 five or six species of mammals 39 Vorona 40 and several other birds 37 the possibly flighted dromaeosaurid Rahonavis 41 42 the noasaurid Masiakasaurus 43 and two titanosaurian sauropods including Rapetosaurus 44 Majungasaurus was by far the largest carnivore and probably the dominant predator on land although large crocodylomorphs like Mahajangasuchus and Trematochampsa might have competed with it closer to water 37 See also edit nbsp Dinosaurs portal nbsp Paleontology portal Timeline of ceratosaur research Evolution of dinosaursReferences edit Deperet Charles 1896 Note sur les Dinosauriens Sauropodes et Theropodes du Cretace superieur de Madagascar Note on the Dinosaurs Sauropods and Theropods of the Upper Cretaceous of Madagascar Bulletin de la Societe Geologique de France in French 21 176 194 a b c d e f g h i Krause David W Sampson Scott D Carrano Matthew T O Connor Patrick M 2007 Overview of the history of discovery taxonomy phylogeny and biogeography of Majungasaurus crenatissimus Theropoda Abelisauridae from the Late Cretaceous of Madagascar In Sampson Scott D Krause David W eds Majungasaurus crenatissimus Theropoda Abelisauridae from the Late Cretaceous of Madagascar Society of Vertebrate Paleontology Memoir 8 Vol 27 Journal of Vertebrate Paleontology pp 1 20 doi 10 1671 0272 4634 2007 27 1 OOTHOD 2 0 CO 2 S2CID 13274054 Deperet Charles Savornin Justin 1928 La faune de Reptiles et de Poissons albiens de Timimoun Sahara algerien The fauna of Reptiles and Albian Fish of Timimoun Algerian Sahara Bulletin de la Societe Geologique de France in French 27 257 265 Lavocat Rene 1955 Sur une portion de mandibule de Theropode provenant du Cretace superieur de Madagascar On a portion of Theropod s mandible from the Upper Cretaceous of Madagascar Bulletin du Museum National d Histoire Naturelle in French 27 256 259 Sues Hans Dieter Taquet Phillipe 1979 A pachycephalosaurid dinosaur from Madagascar and a Laurasia Gondwanaland connection in the Cretaceous Nature 279 5714 633 635 Bibcode 1979Natur 279 633S doi 10 1038 279633a0 S2CID 4345348 Sampson Scott D Krause David W Dodson Peter Forster Catherine A 1996 The premaxilla of Majungasaurus Dinosauria Theropoda with implications for Gondwanan paleobiogeography 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21805 bzn v66i3 a7 S2CID 83535309 Opinion 2269 Case 3487 Megalosaurus crenatissimus Deperet 1896 currently Majungasaurus crenatissimus Dinosauria Theropoda designation of a neotype The Bulletin of Zoological Nomenclature 68 1 89 90 March 2011 doi 10 21805 bzn v68i1 a7 S2CID 87394881 Grillo O N Delcourt R 2016 Allometry and body length of abelisauroid theropods Pycnonemosaurus nevesi is the new king Cretaceous Research 69 71 89 doi 10 1016 j cretres 2016 09 001 Paul Gregory S 2016 The Princeton Field Guide to Dinosaurs Princeton University Press p 85 ISBN 978 1 78684 190 2 OCLC 985402380 a b c d e f g h i Sampson Scott D Witmer Lawrence M 2007 Craniofacial anatomy of Majungasaurus crenatissimus Theropoda Abelisauridae from the Late Cretaceous of Madagascar PDF In Sampson Scott D Krause David W eds Majungasaurus crenatissimus Theropoda Abelisauridae from the Late Cretaceous of Madagascar Society of Vertebrate Paleontology Memoir 8 Vol 27 Journal of Vertebrate Paleontology pp 32 102 doi 10 1671 0272 4634 2007 27 32 CAOMCT 2 0 CO 2 S2CID 129240095 Smith Joshua B 2007 Dental morphology and variation in Majungasaurus crenatissimus Theropoda Abelisauridae from the Late Cretaceous of Madagascar In Sampson Scott D Krause David W eds Majungasaurus crenatissimus Theropoda Abelisauridae from the Late Cretaceous of Madagascar Society of Vertebrate Paleontology Memoir 8 Vol 27 Journal of Vertebrate Paleontology pp 103 126 doi 10 1671 0272 4634 2007 27 103 DMAVIM 2 0 CO 2 S2CID 85729335 O Connor Patrick M 2007 The postcranial axial skeleton of Majungasaurus crenatissimus Theropoda Abelisauridae from the Late Cretaceous of Madagascar In Sampson Scott D Krause David W eds Majungasaurus crenatissimus Theropoda Abelisauridae from the Late Cretaceous of Madagascar Society of Vertebrate Paleontology Memoir 8 Vol 27 Journal of Vertebrate Paleontology pp 127 162 doi 10 1671 0272 4634 2007 27 127 TPASOM 2 0 CO 2 S2CID 131213722 Burch S Carrano M 2008 Abelisaurid forelimb evolution New evidence from Majungasaurus crenatissimus Abelisauridae Theropoda from the late Cretaceous of Madagascar Journal of Vertebrate Paleontology 28 58A doi 10 1080 02724634 2008 10010459 Agnolin Federico L Chiarelli Pablo 2009 The position of the claws in Noasauridae Dinosauria Abelisauroidea and its implications for abelisauroid manus evolution Palaontologische Zeitschrift 84 2 293 300 doi 10 1007 s12542 009 0044 2 S2CID 84491924 Burch S H Carrano M T 2012 An articulated pectoral girdle and forelimb of the abelisaurid theropod Majungasaurus crenatissimus from the Late Cretaceous of Madagascar Journal of Vertebrate Paleontology 32 1 1 16 Bibcode 2012JVPal 32 1B doi 10 1080 02724634 2012 622027 S2CID 86430531 Carrano Matthew T 2007 The appendicular skeleton of Majungasaurus crenatissimus Theropoda Abelisauridae from the Late Cretaceous of Madagascar In Sampson Scott D Krause David W eds Majungasaurus crenatissimus Theropoda Abelisauridae from the Late Cretaceous of Madagascar Society of 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515R doi 10 1038 nature01532 PMID 12673249 S2CID 4389583 Nesbitt Sterling J Turner Alan H Erickson Gregory M Norell Mark A 2006 Prey choice and cannibalistic behaviour in the theropod Coelophysis Biology Letters 2 4 611 614 doi 10 1098 rsbl 2006 0524 PMC 1834007 PMID 17148302 a b Roach Brian T Brinkman Daniel T 2007 A reevaluation of cooperative pack hunting and gregariousness in Deinonychus antirrhopus and other non avian theropod dinosaurs Bulletin of the Peabody Museum of Natural History 48 1 103 138 doi 10 3374 0079 032X 2007 48 103 AROCPH 2 0 CO 2 S2CID 84175628 Archived from the original on August 10 2007 a b O Connor Patrick M Claessens Leon P A M 2006 Basic avian pulmonary design and flow through ventilation in non avian theropod dinosaurs Nature 436 7048 253 256 Bibcode 2005Natur 436 253O doi 10 1038 nature03716 PMID 16015329 S2CID 4390587 a b c d e Farke Andrew A O Connor Patrick M 2007 Pathology in Majungasaurus crenatissimus Theropoda Abelisauridae from the Late Cretaceous of Madagascar In Sampson Scott D Krause David W eds Majungasaurus crenatissimus Theropoda Abelisauridae from the Late Cretaceous of Madagascar Society of Vertebrate Paleontology Memoir 8 Vol 27 Journal of Vertebrate Paleontology pp 180 184 doi 10 1671 0272 4634 2007 27 180 PIMCTA 2 0 CO 2 S2CID 13873519 Rothschild Bruce Tanke Darren H 2005 Theropod paleopathology state of the art review In Carpenter K ed The Carnivorous Dinosaurs Bloomington Indiana University Press pp 351 365 ISBN 978 0 253 34539 4 Hanna Rebecca R 2002 Multiple injury and infection in a sub adult theropod dinosaur Allosaurus fragilis with comparisons to allosaur pathology in the Cleveland Lloyd Dinosaur Quarry collection Journal of Vertebrate Paleontology 22 1 76 90 doi 10 1671 0272 4634 2002 022 0076 MIAIIA 2 0 CO 2 S2CID 85654858 Archived from the original on September 27 2007 Retrieved August 3 2007 Gutherz Samuel B Groenke Joseph R Sertich Joseph J W Burch Sara H O Connor Patrick M July 2 2020 Paleopathology in a nearly complete skeleton of Majungasaurus crenatissimus Theropoda Abelisauridae Cretaceous Research 115 104553 Bibcode 2020CrRes 11504553G doi 10 1016 j cretres 2020 104553 O Connor Patrick Ratsimbaholison Nirina Felice Ryan 2016 Ontogenetic changes in the craniomandibular skeleton of abelisaurid dinosaur Majungasaurus crenatissimus from the Late Cretaceous of Madagascar Acta Palaeontologica Polonica 61 doi 10 4202 app 00132 2014 D Emic Michael Curry Rogers Kristina O Connor Patrick M October 2016 Bone histology reveals unusual life history in the theropod dinosaur Majungasaurus crenatissimus from the Latest Cretaceous of Madagascar PDF Journal of Vertebrate Paleontology 36 124 a b c d e f Rogers Raymond R Krause David W Curry Rogers Kristina Rasoamiaramanana Armand H Rahantarisoa Lydia 2007 Paleoenvironment and Paleoecology of Majungasaurus crenatissimus Theropoda Abelisauridae from the Late Cretaceous of Madagascar In Sampson Scott D Krause David W eds Majungasaurus crenatissimus Theropoda Abelisauridae from the Late Cretaceous of Madagascar Society of Vertebrate Paleontology Memoir 8 Vol 27 Journal of Vertebrate Paleontology pp 21 31 doi 10 1671 0272 4634 2007 27 21 PAPOMC 2 0 CO 2 S2CID 130262308 Rogers Raymond R 2005 Fine grained debris flows and extraordinary vertebrate burials in the Late Cretaceous of Madagascar Geology 33 4 297 300 Bibcode 2005Geo 33 297R doi 10 1130 G21036 1 a b Krause David W O Connor Patrick M Rogers Kristina Curry Sampson Scott D Buckley Gregory A Rogers Raymond R August 23 2006 Late Cretaceous terrestrial vertebrates from Madagascar implications for Latin American biogeography Annals of the Missouri Botanical Garden 93 2 178 208 doi 10 3417 0026 6493 2006 93 178 LCTVFM 2 0 CO 2 S2CID 9166607 Forster Catherine A Chiappe Luis M Krause David W Sampson Scott D 1996 The first Cretaceous bird from Madagascar Nature 382 6591 532 534 Bibcode 1996Natur 382 532F doi 10 1038 382532a0 S2CID 4364184 Forster Catherine Sampson Scott D Chiappe Luis M Krause David W 1998 The theropod ancestry of birds new evidence from the Late Cretaceous of Madagascar Science 279 5358 1915 1919 Bibcode 1998Sci 279 1915F doi 10 1126 science 279 5358 1915 PMID 9506938 Makovicky Peter J Apesteguia Sebastian Agnolin Federico L 2005 The earliest dromaeosaurid theropod from South America Nature 437 7061 1007 1011 Bibcode 2005Natur 437 1007M doi 10 1038 nature03996 PMID 16222297 S2CID 27078534 Sampson Scott D Carrano Matthew T Forster Catherine A 2001 A bizarre predatory dinosaur from the Late Cretaceous of Madagascar Nature 409 6819 504 506 Bibcode 2001Natur 409 504S doi 10 1038 35054046 PMID 11206544 S2CID 205013285 Curry Rogers Kristina Forster Catherine A 2001 The last of the dinosaur titans a new sauropod from Madagascar Nature 412 6846 530 534 Bibcode 2001Natur 412 530C doi 10 1038 35087566 PMID 11484051 S2CID 4347583 External links edit nbsp Media related to Majungasaurus at Wikimedia Commons Press release Archived May 20 2006 at the Wayback Machine about the Majungasaurus mount erected in 2006 at Stony Brook University Retrieved from https en wikipedia org w index php title Majungasaurus amp oldid 1219869612, wikipedia, wiki, book, books, library,

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