|Cast of a Diprotodon skeleton, MNHN, Paris|
Diprotodon, meaning in Greek "two forward teeth", is an extinct genus of diprotodontid marsupial native to Australia during the Pleistocene epoch. The genus is currently considered monotypic, only containing Diprotodon opatum, the largest known marsupial to have ever existed. It is considered one of the core species of the "Australian megafauna", which ranged throught the continent during the Pleistocene. Diprotodon existed from about 1.6 million years ago until extinction some 44,000 years ago
Diprotodon species fossils have been found in sites across mainland Australia,[n 1] including complete skulls and skeletons, and foot impressions.[better source needed] Female skeletons have been found with babies located where the mother's pouch would have been.[better source needed] The largest specimens were hippopotamus-sized: about 3 m (9.8 ft) from nose to tail, standing 2 m (6.6 ft) tall at the shoulder and weighing about 2,790 kg (6,150 lb).[n 2] Diprotodonts may have been depicted on Aboriginal rock art images in Quinkan traditional country (Queensland, Australia). They inhabited open forest, woodland, and grassland, possibly staying close to water, and eating leaves, shrubs, and some grasses. Diprotodon became extinct sometime after 44,000 years ago, after the initial settlement of the continent, the role of human and climactic factors in its extinction are uncertain and contested.
The closest surviving relatives of Diprotodon are the wombats and the koala, and Diprotodon have sometimes been referred to as "giant wombats" in the popular press. Diprotodonts are suggested to have inspired legends of the bunyip, as some Aboriginal tribes identify Diprotodon bones as those of "bunyips".
The first recorded Diprotodon remains were discovered in a cave near Wellington, New South Wales, in the early 1830s by bushman George Ranken and Major Thomas Mitchell; the latter sent them to England for study by Sir Richard Owen. In the 1840s, Ludwig Leichhardt discovered many Diprotodon bones eroding from the banks of creeks in the Darling Downs of Queensland, and when reporting the find to Owen, commented that the remains were so well preserved, he expected to find living examples in the then-unexplored central regions of Australia.
The majority of fossil finds are of demographic groups indicative of diprotodonts dying in drought conditions. For example, hundreds of individuals were found in Lake Callabonna with well-preserved lower bodies, but crushed and distorted heads. Several family groups are thought to have sunk in mud while crossing the drying lake bed. Other finds consist of age groupings of young or old animals, which are first to die during a drought.
Diprotodon was named by Owen (1838). It was assigned to the Diprotodontidae by McKenna and Bell (1997). The historical classification of Diprotodon consisted of eight species (D. optatum Owen, 1838; D. australis Owen, 1844; D. annextans McCoy, 1861; D. minor Huxley, 1862; D. longiceps McCoy 1865; D. loderi Krefft, 1873a; D. bennettii Krefft, 1873b (nec D. bennettii Owen, 1877); and D. bennettii Owen, 1877 (nec D. bennettii Krefft, 1873b); based on size or slight morphological differences of single specimens collected from isolated geographic regions. Bimodal dental sizes, rather than a continuum of tooth sizes, and identical male and female dental morphology, indicate sexual dimorphism instead of separate species, thus providing strong evidence that the eight species are synonyms for D. optatum. Diprotodon is ultimately thought to have evolved from Euryzygoma dunensis, a smaller diprotodontid known from the Pliocene of eastern Australia, and a smaller form of Diprotodon, labelled D. ?opatum, intermediate in size between the two taxa, is known from the Early Pleistocene (1.77–0.78 Ma) in Nelson Bay near Portland, Victoria
Diprotodon superficially resembled a rhinoceros without a horn. Its feet turned inwards like a wombat’s, giving it a pigeon-toed appearance. It had strong claws on the front feet and its pouch opening faced backwards. Its footprints have been found showing a covering of hair, which indicates it had a coat similar to a modern wombat.
Until recently, how many species of Diprotodon had existed was unknown. Eight species are described, although many researchers believed these actually represented only three at most, while some estimated about 20 in total could exist.
John Walter Gregory collected stories of mystical creatures in Aboriginal myths and legends and considered the possible connections between them and extinct species. He reported a story of a "big, heavy land animal, with a single horn on its forehead" as a possible reference to Diprotodon; the presence of a horn on the rostrum of the species is not scientifically acknowledged.
The skull of Diprotodon has large endocranial sinus cavities, which separate the relatively small cranial vault from the outer part of the skull. These significantly lighten the skull while providing large areas for muscle attachment and reduce load stress.
Recent research compared the variation between all of the described Diprotodon species with the variation in one of Australia’s largest living marsupials, the eastern grey kangaroo, and found the range was comparable, with a near continent-wide distribution. This left only two possible Diprotodon species differing only in size with the smaller being around half the size of the larger. According to Gause’s "competitive exclusion principle", no two species with identical ecological requirements can coexist in a stable environment. However, both the small and large diprotodonts coexisted throughout the Pleistocene and the size difference is similar to other sexually dimorphic living marsupials. Further evidence is the battle damage common in competing males found on the larger specimens, but absent from the smaller. Dental morphology also supports sexual dimorphism, with highly sexually dimorphic marsupials, such as the grey kangaroo, having different tooth sizes between males and females, but both sexes having the same dental morphology. An identical dental morphology occurs in the large and small Diprotodon. The taxonomic implication is that Owen’s original Diprotodon optatum is the only valid species.
A single sexually dimorphic species allows behavioural interpretations. All sexually dimorphic species of over 5 kg (11 lb) exhibit a polygynous breeding strategy. A modern example of this is the gender segregation of elephants, where females and the young form family groups, while lone males fight for the right to mate with all the females of the group. This behaviour is consistent with fossil finds where adult/juvenile fossil assemblages usually contain only female adult remains.
Cyclic variations in the strontium isotope ratios within the tooth enamel of a 300,000-year-old fossil imply that a population of Diprotodon undertook regular, seasonal migrations across the Darling Downs, making it the only known extinct or extant metatherian known to migrate annually. The carbon-13 enamel content was found to have little variation, suggesting a relatively consistent diet through the course of a year containing a mix of both C3 and C4 plants. A finite element method analysis of the skull estimated it had a bite force of around 4500 Newtons at the first molar to over 11,000 N at the fourth molar, values which were described as "exceptionally high", suggesting that Diprotodon was capable of processing tough, fibrous food.
Some modern researchers, including Richard Roberts and Tim Flannery, argue that diprotodonts, along with a wide range of other Australian megafauna, became extinct shortly after humans arrived in Australia about 50,000 years ago. Others, including Steve Wroe, note that records in the Australian Pleistocene are rare, and there is not enough data to definitively determine the time of extinction of many of the species, with many of the species having no confirmed record within the last 100,000 years. They suggest that many of the extinctions had been staggered over the course of the late Middle Pleistocene and early Late Pleistocene, prior to human arrival, due to climactic stress. Diprotodon is one of several species with confirmed dates post-dating human arrival on the continent, with the latest high-reliability date being around 44 kyr BP.
Some older researchers, including Richard Wright, argue on the contrary that diprotodont remains from several sites, such as Tambar Springs and Trinkey and Lime Springs suggest that Diprotodon survived much longer, into the Holocene. Other more recent researchers, including Lesley Head and Judith Field, favour an extinction date of 28,000 to 30,000 years ago, which would mean that humans coexisted with Diprotodon for some 20,000 years. However, opponents of "late extinction" theories have interpreted such late dates based on indirect dating methods as artifacts resulting from redeposition of skeletal material into more recent strata, and recent direct dating results obtained with new technologies have tended to confirm this interpretation.
Three theories have been advanced to explain the mass extinction.
Australia, as with many other areas of the globe, underwent significant ecological change from predomiantly forests to open landscapes during the late Neogene, in correlation with increased cooling. There has been considerable aridification of the Australian interior since the Late Miocene. The recent ice ages produced no significant glaciation in mainland Australia, but long periods of cold and increased aridification. These climactic changes have been suggested as a contributing factor in extinction.
Critics[who?] point out a number of problems with this theory. First, large diprotodonts had already survived a long series of similar ice ages, and no particular reason is apparent that the most recent one should have achieved what all the previous ice ages had failed to do. Also, climate change apparently peaked 25,000 years after the extinctions. Finally, even during climatic extremes, some parts of the continent always remain relatively exempt; for example, the tropical north stays fairly warm and wet in all climatic circumstances, while alpine valleys are less affected by drought, and so on.
The overkill theory is that human hunters killed and ate the diprotodonts, causing their extinction. The extinctions appear to have coincided with the arrival of humans on the continent, and in broad terms, Diprotodon was the largest and least well-defended species that died out. Similar hunting-out happened with the megafauna of New Zealand, Madagascar, and many smaller islands around the world (such as New Caledonia, the Greater Antilles, ) probably within a thousand years or so. Recent finds of Diprotodon bones that appear to display butchering marks lend support to this theory. Critics of this theory regard it as simplistic, arguing that (unlike New Zealand and America), little direct evidence of hunting has been found, and the dates on which the theory rests are too uncertain to be reliable. However, the high-resolution chronology of the changes supports the hypothesis that human hunting alone eliminated the megafauna.
Human land management
The third theory says that humans indirectly caused the extinction of diprotodonts by destroying the ecosystem on which they depended. In particular, early Aboriginal people are thought to have been fire-stick farmers using fire regularly and persistently to drive game, open up dense thickets of vegetation, and create fresh green regrowth for both humans and game animals to eat. Evidence for the fire hypothesis is the sudden increase in widespread ash deposits at the time that people arrived in Australia, as well as land-management and hunting practices of modern Aboriginal people as recorded by the earliest European settlers. Evidence against the hypothesis is the fact that humans appear to have eliminated the megafauna of Tasmania without using fire to modify the environment there.
The above hypotheses are not necessarily mutually exclusive. Each of proposed mechanisms can potentially support the other two. For example, while burning an area of fairly thick forest and thus turning it into a more open, grassy environment might reduce the viability of a large browser (an animal that eats leaves and shoots rather than grasses), the reverse could also be true: removing the browsing animals within a few years produces a very thick undergrowth which, when a fire eventually starts through natural causes (as fires tend to do every few hundred years), burns with greater than usual ferocity. The burnt-out area is then repopulated with a greater proportion of fire-loving plant species (notably eucalypts, some acacias, and most of the native grasses) which are unsuitable habitat for most browsing animals. Either way, the trend is toward the modern Australian environment of highly flammable open sclerophyllous forests, woodlands and grasslands, none of which are suitable for large, slow-moving browsing animals—and either way, the changed microclimate produces substantially less rainfall.
An examination of swamp sediment cores spanning the last 130,000 years from Lynch's Crater in Queensland suggests that hunting may have been the primary cause of the extinction. Analysis of Sporormiella fungal spores (which derive mainly from the dung of megaherbivores) in the cores shows that the megafauna of that region virtually disappeared about 41,000 years ago, at a time when climate changes were minimal; the change was accompanied by an increase in charcoal, and was followed by a transition from rainforest to fire-tolerant sclerophyll vegetation. The high-resolution chronology of the changes indicates that fire increased about a century after the disappearance of browsing megafauna, probably due to accumulation of fuel. Grass increased over the next several centuries; sclerophyll vegetation increased following a lag of another century, and a sclerophyll forest developed about a thousand years later. Earlier increases in sclerophyll vegetation during shifts to cooler, drier conditions about 120,000 and 75,000 years ago did not have any obvious impact on megafaunal abundance. However, the use of Sporormiella as a megafaunal proxy has been criticised, noting that its presence depends on a variety of factors, often unrelated to megafaunal abundance, and that in Cuddie Springs, a well known megafaunal site, the densities of Sporomiella were consistently low.
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|Wikimedia Commons has media related to Diprotodon.|
|Wikispecies has information related to Diprotodon|
- Australia's lost kingdom on Diprotodon optatum
- BBC science and nature on Diprotodon optatum
- Regional Council of Goyder page on the genera
- Museum Victoria on the Diprotodontids
- Museum Victoria view of a Diprotodon skull
- South Australian Museum information
- Description of Price's research
- Danielle Clode (2009) Prehistoric giants: the megafauna of Australia. Museum Victoria.
- Barry Cox, Colin Harrison, R.J.G. Savage, and Brian Gardiner. (1999): The Simon & Schuster Encyclopedia of Dinosaurs and Prehistoric Creatures: A Visual Who's Who of Prehistoric Life. Simon & Schuster.
- Jayne Parsons. (2001): Dinosaur Encyclopedia. Dorling Kindersley.
- David Norman. (2001): The Big Book Of Dinosaurs. Welcome Books.
- Gilbert Price. (2005): Article in Memoirs of the Queensland Museum. Queensland Museum.