Subfossil lemur
Subfossil lemurs are
Despite their size, the giant lemurs shared many features with living lemurs, including rapid development, poor day vision, relatively small brains, and female-dominated hierarchies. They also had many distinct traits among lemurs, including a tendency to rely on
Subfossil remains were first discovered on Madagascar in the 1860s, but giant lemur species were not formally described until the 1890s. The
Diversity
Extinct giant lemurs
Until recently, giant lemurs existed in Madagascar. Although they are only represented by
All but one species, the
Characteristics
All of the extinct subfossil lemurs, including the smallest species (
These traits are shared among both living and extinct lemurs, but are uncommon among primates in general. Two prevailing hypotheses to explain these unique adaptations are the energy frugality hypothesis by
![A lemur skull, seen from the right.](http://upload.wikimedia.org/wikipedia/commons/thumb/6/68/Pachylemur_insignis_skull_001.jpg/220px-Pachylemur_insignis_skull_001.jpg)
Despite the similarities, subfossil lemurs had several distinct differences from their lemur relatives. In addition to being larger, the subfossil lemurs were more dependent on leaves and seeds in their diet, rather than fruit. They utilized slow climbing, hanging, and terrestrial quadrupedalism for locomotion, rather than vertical clinging and leaping and arboreal quadrupedalism. Also, all but one of them—the giant aye-aye—are assumed to have been diurnal (due to their body size and small orbits), whereas many small lemurs are nocturnal and medium-sized are cathemeral.[6][9]
Their skeletons suggest that most subfossil lemurs were tree-dwellers, adapted for living in forests and possibly limited to such habitats.
Types
![](http://upload.wikimedia.org/wikipedia/commons/thumb/b/b5/Archaeoindris_fontoynonti.jpg/220px-Archaeoindris_fontoynonti.jpg)
The sloth lemurs (
- Koala lemurs
The koala lemurs of the family Megaladapidae most closely resemble marsupial koalas from Australia. According to genetic evidence they were most closely related to the family Lemuridae, although for many years they were paired with the sportive lemurs of the family Lepilemuridae due to similarities in their skulls and molar teeth.[12] They were slow climbers and had long forelimbs and powerful grasping feet, possibly using them for suspension.[8][12] Koala lemurs ranged in size from an estimated 45 to 85 kg (99 to 187 lb),[12]. They had poor day vision, short tails, lacked permanent upper incisors, and had a reduced toothcomb.[8] Their diet generally consisted of leaves,[8][9] with some species being specialized folivores and others having a broader diet, possibly including tough seeds.[14]
Monkey lemurs, or baboon lemurs, share similarities with macaques; they have also been compared to baboons.[9][15] Members of the family Archaeolemuridae, they were the most terrestrial of the lemurs,[9][12] with short, robust forelimbs and relatively flat digits. They spent time on the ground, and were semi-terrestrial, spending time in trees to feed and sleep. They were heavy-bodied and ranged in size from approximately 13 to 35 kg (29 to 77 lb).[8][12] They had relatively good day vision and large brains compared with other lemurs.[8] Their robust jaws and specialized teeth suggest a diet of hard objects, such as nuts and seeds, yet other evidence, including fecal pellets, suggests they may have had a more varied diet, including leaves, fruit, and animal matter (omnivory).[8][9][12] Dental wear analysis has shed some light on this dietary mystery, suggesting that monkey lemurs had a more eclectic diet, while using tough seeds as a fall-back food item.[14] Within the family, the genus Archaeolemur was the most widespread in distribution, resulting in hundreds of subfossil specimens, and may have been one of the last subfossil lemurs to die out.[16]
An extinct, giant relative of the living aye-aye, the giant aye-aye shared at least two of the aye-aye's bizarre traits: ever-growing central incisors and an elongated, skinny middle finger.[8] These shared features suggest a similar lifestyle and diet, focused on percussive foraging (tapping with the skinny digit and listening for reverberation from hollow spots) of defended resources, such as hard nuts and invertebrate larvae concealed inside decaying wood. Weighing as much as 14 kg (31 lb), it was between two-and-half and five times the size of living aye-aye.[7][12] Alive when humans came to Madagascar, its teeth were collected and drilled to make necklaces.[9]
The only extinct member of the family Lemuridae, the genus Pachylemur contains two species that closely resembled living ruffed lemurs. Sometimes referred to as "giant ruffed lemurs", they were approximately three times larger than ruffed lemurs,[9] weighing between 10 and 13 kg (22 and 29 lb).[12] Despite their size, they were arboreal quadrupeds, possibly utilizing more suspensory behavior and cautious climbing than their sister taxon.[7][12][15] Their skull and teeth were similar to those of ruffed lemurs, suggesting a diet high in fruit and possibly some leaves. The rest of its skeleton (postcrania) was much more robust and their vertebrae had distinctly different features.[8][9]
Phylogeny
Determining the phylogeny of subfossil lemurs has been problematic because studies of morphology, developmental biology, and molecular phylogenetics have sometimes yielded conflicting results. All studies agree that the family Daubentoniidae (including the giant aye-aye) diverged first from the other lemurs at least 60 million years ago. The relationship between the remaining families has been less clear. Morphological, developmental, and molecular studies have offered support for lumping the four sloth lemur genera of the family Palaeopropithecidae with the family Indriidae (including the indri, sifakas, and woolly lemurs).[17] The placement of family Megaladapidae has been more controversial, with similarities in teeth and skull features suggesting a close relationship with family Lepilemuridae (sportive lemurs).[17][8] Molecular data, instead, indicate a closer relationship to family Lemuridae.[17] Likewise, a relationship between family Archaeolemuridae and family Lemuridae has been suggested, based on morphological and developmental traits, yet molar morphology, the number of teeth in the specialized toothcomb, and molecular analysis support a closer relationship with the indriid–sloth lemur clade.[17] Other subfossil lemurs, including the giant aye-aye and Pachylemur, are more easily placed due to strong similarities with existing lemurs (the aye-aye and ruffed lemurs, respectively).[8]
Subfossil lemur phylogeny[8][18][19] | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
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Living species
Subfossil sites in Madagascar have yielded the remains of more than just extinct lemurs. Extant lemur remains have also been found, and radiocarbon dating has demonstrated that both types of lemur lived at the same time. In some cases living species are
In addition to previously having expanded geographic ranges, extant subfossil lemurs exhibited significant variation in size.
Ecology
As a group, the lemurs of Madagascar are extremely diverse, having evolved in isolation and
![A giant lemur hangs from a tree limb by all four feet like a slow-moving sloth. The tail is short, and the arms are slightly longer than the legs.](http://upload.wikimedia.org/wikipedia/commons/thumb/a/ad/Babakotia_radofilai.jpg/220px-Babakotia_radofilai.jpg)
Although anatomical evidence suggests that even the large, extinct species were adapted to tree-climbing, some habitats, including gallery forests and the spiny forests of southern Madagascar, in which they occurred would not have allowed them to be strictly arboreal. Even today, most lemur species will visit the ground to cross open areas, suggesting that the extinct species did the same. Monkey lemurs (family Archaeolemuridae), including Archaeolemur majori and Hadropithecus stenognathus, have been reconstructed as being primarily terrestrial.[25] In contrast, the sloth lemurs (family Palaeopropithecidae) were highly arboreal despite the large size of some species.[26]
Species of both extinct and living (extant) lemur vary in size based on habitat conditions, despite their differences in niche preference. Within
Diet
Research on subfossil lemur diets, particularly in southern and southwestern Madagascar, has indicated that ecological communities have been significantly affected by their recent extinction.[25] Many extinct subfossil lemurs were large-bodied leaf-eaters (folivores), seed predators, or both. Today, leaf-eating along with seed predation is only seen in mid-sized lemurs, and is far less common than it was in the past. Strict folivory is also less common, now found primarily in small lemurs.[8] In certain cases, subfossil lemurs, such as the sloth lemurs and koala lemurs, may have used leaves as an important fallback food, whereas other species, such as the monkey lemurs and the giant aye-aye, specialized on structurally defended resources, such as hard seeds and wood-boring insect larvae. Last, Pachylemur was primarily a fruit eater (frugivorous).[9] Subfossil lemur diets have been reconstructed using analytical tools, including techniques to compare tooth anatomy, structure, and wear; biogeochemistry (analysis of isotope levels, like carbon-13); and the dissection of fecal pellets associated with subfossil remains.[8][25]
The diets of most subfossil lemurs, most notably Palaeopropithecus and Megaladapis, consisted primarily of C3 plants, which use a form of photosynthesis that results in higher water loss through transpiration. Other subfossil lemurs, such as Hadropithecus and Mesopropithecus, fed on CAM and C4 plants, which use more water-efficient forms of photosynthesis. Fruit and animal matter was more common in the diets of subfossil lemurs including Pachylemur, Archaeolemur, and the giant aye-aye. In southern and southwestern Madagascar, the subfossil lemurs of the spiny forests generally favored the C3 plants over the more abundant CAM plants, although closely related sympatric species may have fed upon the two types of plants in different ratios, allowing each to divide resources and coexist. Since plants produce defenses against leaf-eating animals, the extensive use of spines by plants in the spiny forests suggest that they evolved to cope with leaf-eating lemurs, large and small.[25]
Seed dispersal
Giant subfossil lemurs are thought to have also played a significant role in
Seed size may be a limiting factor for some plant species, since their seeds are too large for living (
Discovery and research
The writings of French colonial governor Étienne de Flacourt in the mid-17th century introduced the existence of giant Malagasy mammals to Western science with recorded eye-witness accounts from the local people of dangerous animals, hornless "water cows", and a large lemur-like creature referred to locally as the tretretretre or tratratratra.[26][28] Today, the latter is thought to have been a species of Palaeopropithecus[17] or possibly Megaladapis.[28] Flacourt described it as:
An animal as big as a two-year-old calf, with a round head and a human face: the front feet are monkeylike, and the rear ones as well. It has frizzy hair, a short tail, and humanlike ears. ... One has been seen near Lake Lipomami, around which it lives. It is a very solitary animal; the local people fear it greatly and flee from it as it does from them.
— Étienne de Flacourt, Histoire de la Grande Isle Madagascar, 1658[28]
Local tales of a song'aomby (Malagasy for 'cow that is not a cow'), or pygmy hippopotamus, led French naturalist Alfred Grandidier to follow a village headman to a marsh in southwestern Madagascar, a site called Ambolisatra, which became the first known subfossil site in Madagascar. In 1868, Grandidier uncovered the first subfossil remains of lemurs—a humerus from Palaeopropithecus and a tibia of a sifaka. The Palaeopropithecus remains were not described for several decades, and it took decades more for the remains to be correctly paired with other sloth lemur remains.[26] It was not until 1893 that giant lemur species were formally described, when Charles Immanuel Forsyth Major discovered and described a long, narrow skull of Megaladapis madagascariensis in a marsh.[15] His discoveries in various marshes of central and southwestern Madagascar sparked paleontological interest,[12] resulting in an overabundance of taxonomic names and confused assemblages of bones from numerous species, including non-primates. Specimens were distributed between European museums and Madagascar, often resulting in the loss of field data that went with the specimens, if the data had been recorded at all.[15]
In 1905, Alfred Grandidier's son, Guillaume Grandidier, reviewed subfossil lemur taxonomy and determined that too many names had been created. His review established most of the presently known family and genera names for the extinct lemurs.[12] Despite the taxonomic clarification, subfossil postcrania from different genera, particularly Megaladapis, Palaeopropithecus and Hadropithecus, continued to be incorrectly paired and sometimes assigned to non-primates.[15] Since subfossil remains were often dredged from marshes one by one, pairing skulls with other bones was often guesswork based on size-matching, and was not very accurate as a consequence.[12] Even as late as the 1950s, bones of non-primates were attributed to subfossil lemurs.[15] One reconstruction of the confounded subfossil remains by paleontologist Herbert F. Standing depicted Palaeopropithecus as an aquatic animal that swam near the surface, keeping its eyes, ears, and nostrils slightly above water. Postcranial remains of Palaeopropithecus had previously been paired with Megaladapis by Guillaume Grandidier, who viewed it as a giant tree sloth, which he named Bradytherium. Standing's aquatic theory was supported by Italian paleontologist Giuseppe Sera, who reconstructed Palaeopropithecus as an "arboreal-aquatic acrobat" that not only swam in water but climbed trees and dove from there into the water. Sera took the aquatic theory further in 1938 by including other extinct lemurs, including Megaladapis, which he viewed as a thin ray-like swimmer that fed on mollusks and crustaceans while concealed underwater. It was primarily the paleontologist Charles Lamberton who correctly paired many of the confused subfossils, although others had also helped address problems of association and taxonomic synonyms. Lamberton also refuted Guillaume Grandidier's sloth theory for Megaladapis, as well as the aquatic lemur theory of Standing and Sera.[26]
Excavations during the early 20th century by researchers like Lamberton failed to unearth any new extinct lemur genera.
A new genus of sloth lemur,
The number of Malagasy subfossil sites containing subfossil lemurs has increased significantly since the mid-20th century. At that time, subfossil lemurs had only been found in the center, south, and southwest of the island.
Extinction
At least 17 species of giant subfossil lemur vanished during the Holocene, with all or most extinctions happening after the colonization of Madagascar by humans around 2,000 years ago.
![](http://upload.wikimedia.org/wikipedia/commons/thumb/c/c3/Subfossil_lemur_C14_ranges.svg/500px-Subfossil_lemur_C14_ranges.svg.png)
By region, the Central Highlands lost the greatest number of lemur species.
Comparisons of species counts from subfossil deposits and remnant populations in neighboring
As with the extinctions that occurred on other land masses during the late Pleistocene and Holocene (known as the
The extinction of Madagascar's megafauna, including the giant lemurs, was one of the most recent in history,[17] with large lemur species like Palaeopropithecus ingens surviving until approximately 500 years ago[37] and one bone of the extinct Hippopotamus laloumena radiocarbon dated to about 100 years BP.[34] An even wider extinction window for the subfossil lemurs, ranging up until the 20th century, may be possible if reports of unidentified animals are true.[22] As recently as the early 17th century, dwindling populations of subfossil lemurs may have persisted in coastal regions where tree-cutting and uncontrolled fires had less of an impact. By that date, the Central Highlands' forests were mostly gone, with the exception of scattered forest fragments and strips.[15] Along the northwest coast, forms such as Archaeolemur may have survived for more than a millennium after the arrival of humans.[38] This is supported by radiocarbon dates for Archaeolemur from the Ankarana Massif dating to 975 ± 50 CE[22] as well as archaeological data that show there was little human activity in the area until a few centuries ago, with low human population density along the northwest coast until nearly 1500 CE.[38]
Hypotheses
In the 20th century, six hypotheses for explaining the extinction of the giant subfossil lemurs have been proposed and tested. They are known as the "Great Fire", "Great Drought", "Blitzkrieg", "Biological Invasion", "Hypervirulent Disease", and "Synergy" hypotheses.
Since all extinct lemurs were larger than the ones that currently survive, and the remaining large forests still support large populations of smaller lemurs, large size appears to have conveyed some distinct disadvantages.[12][45] Large-bodied animals require larger habitats in order to maintain viable populations, and are most strongly impacted by habitat loss and fragmentation.[6][9][12] Large folivores typically have slower reproductive rates, live in smaller groups, and have low dispersal rates (vagility), making them especially vulnerable to habitat loss, hunting pressure, and possibly disease.[6][12][33] Large, slow-moving animals are often easier to hunt and provide a larger amount of food than smaller prey.[45] Leaf-eating, large-bodied slow climbers, and semiterrestrial seed predators and omnivores disappeared completely, suggesting an extinction pattern based on habitat use.[8]
Since the subfossil bones of extinct lemurs have been found alongside the remains of highly arboreal living lemur species, we know that much of Madagascar had been covered in forest prior to the arrival of humans; the forest coverage of the high plateau region has been debated. Humbert and other botanists suggested that the central plateau had once been blanketed in forest, later to be destroyed by fire for use by humans. Recent paleoenvironmental studies by Burney have shown that the grasslands of that region have fluctuated over the course of millennia and were not entirely created by humans.[12] Similarly, the role humans played in the aridification of the south and southwest has been questioned, since natural drying of the climate started before human arrival.[12][15] The marshes of the region (in which subfossil remains have been found) have dried up, subfossil sites have yielded a host of arboreal lemurs, and site names, such as Ankilitelo ('place of three kily or tamarind trees') suggest a recent wetter past.[15] Pollen studies have shown that the aridification process began nearly 3,000 years ago, and peaked 1,000 years prior to the time of the extinctions. No extinctions occurred prior to the arrival of humans, and the recent climatic changes have not been as severe as those prior to human arrival, suggesting that humans and their effect on the vegetation did play a role in the extinctions.[12][22][34] The central plateau lost more species than the dry south and southwest, suggesting that degraded habitats were more affected than arid habitats.[15]
Over-hunting by humans has been one of the most widely accepted hypotheses for the ultimate demise of the subfossil lemurs.[37] The extinctions and human hunting pressure are associated due to the synchronicity of human arrival and species decline, as well as the suspected naïveté of the Malagasy wildlife during the early encounters with human hunters. Despite the assumptions, evidence of butchery has been minimal until recently, although folk memories of rituals associated with the killing of megafauna have been reported. Archeological evidence for butchery of giant subfossil lemurs, including Palaeopropithecus ingens and Pachylemur insignis, was found on specimens from two sites in southwestern Madagascar, Taolambiby and Tsirave. The bones had been collected in the early 20th century and lacked stratigraphic records; one of the bones with tool marks had been dated to the time of the first arrival of humans. Tool-induced bone alterations, in the form of cuts and chop marks near joints and other characteristic cuts and fractures, indicated the early human settlers skinned, disarticulated, and filleted giant lemurs. Prior to these finds, only modified bones of dwarf hippos and elephant birds, as well as giant aye-aye teeth, had been found.[33]
Although there is evidence that habitat loss, hunting, and other factors played a role in the demise of the subfossil lemurs, prior to the synergy hypothesis, each had its own discrepancies. Humans may have hunted the giant lemurs for food, but no signs of game-dependent butchery have been found. Madagascar was colonized by Iron-age pastoralists, horticulturalists, and fishermen, not big-game hunters. The blitzkrieg hypothesis predicts extinction within 100 and 1,000 years as humans sweep across the island,[22][33] yet humans lived alongside the giant lemurs for more than 1,500 years. Alternatively, habitat loss and deforestation have been argued against because many giant lemurs were thought to be terrestrial, they are missing from undisturbed forested habitats, and their environment was not fully forested prior to the arrival of humans. Anthropologist Laurie Godfrey defended the effects of habitat loss by pointing out that most of the extinct lemurs have been shown to have been at least partly arboreal and dependent upon leaves and seeds for food, and also that these large-bodied specialists would be most vulnerable to habitat disturbance and fragmentation due to their low reproductive resilience and their need for large, undisturbed habitats.[15] Still, much of the island remained covered in forest, even into the 20th century.[46]
Linking human colonization to a specific cause for extinction has been difficult since human activities have varied from region to region.[46] No single human activity can account for the extinction of the giant subfossil lemurs, but humans are still regarded as being primarily responsible. Each of the contributing human-caused factors played a role (having a synergistic effect) in varying degrees.[17][44] The most widespread and adaptable species, such as Archaeolemur, were able to survive despite hunting pressure and human-caused habitat change until human population growth and other factors reached a tipping point, cumulatively resulting in their extinction.[22]
Extinction timeline and the primary trigger
![](http://upload.wikimedia.org/wikipedia/commons/thumb/b/bc/Sloth_lemur_drawing.jpg/220px-Sloth_lemur_drawing.jpg)
While it is generally agreed that both human and natural factors contributed to the subfossil lemur extinction, studies of sediment cores have helped to clarify the general timeline and initial sequence of events. Spores of the coprophilous fungus, Sporormiella, found in sediment cores experienced a dramatic decline shortly after the arrival of humans. Since this fungus cannot complete its life cycle without dung from large animals, its decline also indicates a sharp decline in giant subfossil lemur populations, as well as other large herbivores,[9] starting around 230–410 cal yr CE. Following the decline of megafauna, the presence of charcoal particles increased significantly, starting in the southwest corner of the island, gradually spreading to the other coasts and the island's interior over the next 1,000 years.[34] The first evidence for the introduction of cattle to the island dates to 1,000 years after the initial decline of coprophilous fungal spores.[33]
The loss of grazers and browsers might have resulted in the accumulation of excessive plant material and litter, promoting more frequent and destructive wildfires, which would explain the rise in charcoal particles following the decline in coprophilous fungus spores.[34] This in turn resulted in ecological restructuring through the elimination of the wooded savannas and preferred arboreal habitats on which the giant subfossil lemurs depended. This left their populations at unsustainably low levels, and factors such as their slow reproduction, continued habitat degradation, increased competition with introduced species, and continued hunting (at lower levels, depending on the region) prevented them from recovering and gradually resulted in their extinction.[17]
Hunting is thought to have caused the initial rapid decline, referred to as the primary trigger, although other explanations may be plausible.[33] In theory, habitat loss should affect frugivores more than folivores, since leaves are more widely available. Both large-bodied frugivores and large-bodied folivores disappeared simultaneously, while smaller species remained. Other large non-primate grazers also disappeared around the same time. Consequently, large body size has been shown to have the strongest link to the extinctions—more so than activity patterns or diet. Since large animals are more attractive as prey, fungal spores associated with their dung declined rapidly with the arrival of humans, and butchery marks have been found on giant subfossil lemur remains, hunting appears to be a plausible explanation for the initial decline of the megafauna.[9][36]
By region, studies have revealed specific details that have helped outline the series of events that led to the extinction of the local megafauna. In the Central Highlands, dense forests existed until 1600 CE, with lingering patches persisting until the 19th and 20th centuries. Today, small fragments stand isolated among vast expanses of human-created savanna, despite an average annual rainfall that is sufficient to sustain the evergreen forests once found there. Deliberately set fires were the cause of the deforestation, and forest regrowth is restricted by soil erosion and the presence of fire-resistant, exotic grasses.[15] In the southeast, an extended drought dating to 950 cal yr BP led to fires and transition of open grasslands. The drought may also have pushed humans populations to rely more heavily on bushmeat. Had humans not been present, the subfossil lemur populations might have adjusted to the new conditions and recovered. Had the drought not reduced the population of the subfossil lemurs, the pressure from the small number of people living in the region at the time might not have been enough to cause the extinctions.[37] All of the factors that have played a role in past extinctions are still present and active today. As a result, the extinction event that claimed Madagascar's giant subfossil lemurs is still ongoing.[17]
Lingering populations and oral tradition
Recent radiocarbon dates from accelerator mass spectrometry 14C dating, such as 630 ± 50 BP for Megaladapis remains and 510 ± 80 BP for Palaeopropithecus remains, indicate that the giant lemurs survived into modern times. It is likely that memories of these creatures persist in the oral traditions of some Malagasy cultural groups. Some recent stories from around Belo sur Mer in southwestern Madagascar might even suggest that some of the giant subfossil lemurs still survive in remote forests.[47]
Flacourt's 1658 description of the tretretretre or tratratratra was the first mention of the now extinct giant lemurs in Western culture, but it is unclear if he saw it.[28] The creature Flacourt described has traditionally been interpreted as a species of Megaladapis. The size may have been exaggerated, and the "round head and a human face" would not match Megaladapis, which had an enlarged snout and the least forward-facing eyes of all primates. The facial description, and the mention of a short tail, solitary habits, and other traits better match the most recent interpretation — Palaeopropithecus.[7] Malagasy tales recorded by the 19th-century folklorist Gabriel Ferrand describing a large animal with a flat human-like face that was unable to negotiate smooth rock outcrops also best match Palaeopropithecus, which would also have had difficulty on flat smooth surfaces.[26]
In 1995, a research team led by David Burney and Ramilisonina performed interviews in and around Belo sur Mer, including Ambararata and Antsira, to find subfossil megafaunal sites used early in the century by other paleontologists. During carefully controlled interviews, the team recorded stories of recent sightings of dwarf hippos (called kilopilopitsofy) and of a large lemur-like creature known as kidoky; a report of the interviews was published in 1998 with encouragement from primatologist Alison Jolly and anthropologist Laurie Godfrey. In one interview, an 85-year-old man named Jean Noelson Pascou recounted seeing the rare kidoky up close in 1952. Pascou said that the animal looks similar to a sifaka, but had a human-like face, and was "the size of a seven-year-old girl". It had dark fur and a discernible white spot both on the forehead and below the mouth. According to Pascou, it was a shy animal that fled on the ground instead of in the trees. Burney interpreted the old man as saying that it moved in "a series of leaps",[48] but Godfrey later claimed that "a series of bounds" was a better translation — a description that would closely match the foot anatomy of monkey lemurs, such as Hadropithecus and Archaeolemur.[47] Pascou could also imitate its call, a long single "whoop", and said that kidoky would come closer and continue calling if he imitated the call correctly. The call Pascou imitated was comparable to that of a short call for an indri, which lives on the other side of Madagascar. When shown a picture of an indri, Pascou said kidoky did not look like that, and that it had a rounder face, more similar to a sifaka. Pascou also speculated that kidoky could stand on two legs and that it was a solitary animal.[48]
Another interviewee, François, a middle-aged woodcutter who spent time in the forests inland (east) from the main road between Morondava and Belo sur Mer, and five of his friends, reported seeing kidoky recently. Their description of the animal and François's imitation of its long call were virtually identical to Pascou's. One of the young men insisted that its fur had a lot of white in it, but the other men could not confirm that. François and his friends reported that it had never climbed a tree in their presence, and that it flees on the ground in short leaps or bounds. When Burney imitated the sideways leaping of a sifaka moving on the ground, one of the men corrected him, pointing out that he was imitating a sifaka. The man's imitation of the gallop kidoky used was very baboon-like. The men also reported that imitating its call can draw the animal closer and cause it to continue calling.[48]
Burney and Ramilisonina admitted that the most parsimonious explanation for the sightings was that kidoky was a misidentified sifaka or other larger living lemur species. The authors did not feel comfortable with such a dismissal because of their careful quizzing and use of unlabeled color plates during the interviews and because of the competence demonstrated by the interviewees in regards to local wildlife and lemur habits. The possibility of a wild introduced baboon surviving in the forests could not be dismissed. The descriptions of kidoky, with its terrestrial baboon-like gait, make Hadropithecus and Archaeolemur the most plausible candidates among the giant subfossil lemurs. At the very least, the stories support a wider extinction window for the giant subfossil lemurs, suggesting that their extinction was recent enough for such vivid stories to survive in the oral traditions of the Malagasy people.[48]
See also
Subfossil lemurs at Wikibooks
Primates portal
Madagascar portal
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- Books cited
- Burney, D.A. (1999). "Rates, Patterns, and Processes of Landscape Transformation and Extinction in Madagascar". In MacPhee, R.D.E.; Sues, H.-D. (eds.). Extinctions in Near Time. Springer. pp. 145–164. ISBN 978-0-306-46092-0.
- Goodman, S.M.; Benstead, J.P., eds. (2003). The Natural History of Madagascar. University of Chicago Press. ISBN 0-226-30306-3.
- Dewar, R. E. (2003). Relationship between Human Ecological Pressure and the Vertebrate Extinctions. pp. 119–122.
- Goodman, S.M.; Ganzhorn, J.U.; Rakotondravony, D. (2003). Introduction to the Mammals. pp. 1159–1186.
- Godfrey, L.R.; Jungers, W.L. (2003). Subfossil Lemurs. pp. 1247–1252.
- Goodman, S.M.; Patterson, B.D., eds. (1997). Natural Change and Human Impact in Madagascar. Smithsonian Institution Press. ISBN 978-1-56098-682-9.
- Simons, E.L. (1997). Chapter 6: Lemurs: Old and New. pp. 142–166.
- MacPhee, R.D.E.; Marx, P.A. (1997). Chapter 7: The 40,000-year plague: humans, hypervirulent diseases, and first-contact extinctions. pp. 169–217.
- Godfrey, L.R.; Jungers, W.L.; Reed, K.E.; Simons, E.L.; Chatrath, P.S. (1997). Chapter 8: Subfossil Lemurs. pp. 218–256.
- Godfrey, L.R.; Jungers, W.L.; Burney, D.A. (2010). "Chapter 21: Subfossil Lemurs of Madagascar". In Werdelin, L.; Sanders, W.J (eds.). Cenozoic Mammals of Africa. University of California Press. pp. 351–367. ISBN 978-0-520-25721-4.
- Godfrey, L.R.; Jungers, W.L.; Schwartz, G.T. (2006). "Chapter 3: Ecology and Extinction of Madagascar's Subfossil Lemurs". In Gould, L.; Sauther, M.L. (eds.). Lemurs: Ecology and Adaptation. Springer. pp. 41–64. ISBN 978-0-387-34585-7.
- Godfrey, L.R.; Jungers, W.L. (2002). "Chapter 7: Quaternary fossil lemurs". In Hartwig, W.C. (ed.). The Primate Fossil Record. Cambridge University Press. pp. 97–121. ISBN 0-521-66315-6.
- Jungers, W.L.; Demes, B.; Godfrey, L.R. (2008). "How Big were the "Giant" Extinct Lemurs of Madagascar?". In Fleagle, J.G.; Gilbert, C.C. (eds.). Elwyn Simons: A Search for Origins. Developments in Primatology: Progress and Prospects. Springer. pp. 343–360. ISBN 978-0-387-73895-6.
- Martin, P.S.; Klein, R.G., eds. (1984). Quaternary Extinctions: A Prehistoric Revolution. University of Arizona Press. ISBN 978-0-8165-0812-9.
- Martin, P.S. (1984). Prehistoric overkill: the global model. University of Arizona Press. pp. 354–403. ISBN 9780816511006.
- Dewar, R. (1984). Extinctions in Madagascar: the loss of the subfossil fauna. pp. 574–593.
- Martin, P.S. (1984). Prehistoric overkill: the global model. University of Arizona Press. pp. 354–403.
- OCLC 883321520.
- Preston-Mafham, K. (1991). Madagascar: A Natural History. Facts on File. ISBN 978-0-8160-2403-2.
- Sussman, R.W. (2003). Primate Ecology and Social Structure. Pearson Custom Publishing. ISBN 978-0-536-74363-3.
External links
Media related to Category:Subfossil lemurs at Wikimedia Commons