Palaeoloxodon

Template:Short description Template:Distinguish Template:Automatic taxobox Palaeoloxodon is an extinct genus of elephant. It originated in Africa during the Early Pleistocene, and expanded into Eurasia at the beginning of the Middle Pleistocene. Palaeoloxodon contains the largest known species of elephants, with mature bulls over Template:Convert tall at the shoulders and over Template:Convert in weight, representing among the largest land mammals ever, including the African Palaeoloxodon recki, the European straight-tusked elephant (Palaeoloxodon antiquus) and the South Asian Palaeoloxodon namadicus. P. namadicus has been suggested to be the largest known land mammal by some authors based on extrapolation from fragmentary remains, though these estimates are highly speculative.<ref name="probos_mass">Template:Cite journal</ref> In contrast, the genus also contains many species of dwarf elephants that evolved via insular dwarfism on islands in the Mediterranean, some like Palaeoloxodon falconeri less than Template:Convert in shoulder height as fully grown adults, making them the smallest elephants known. The genus has a long and complex taxonomic history, and at various times, it has been considered to belong to Loxodonta or Elephas, but today is usually considered a valid and separate genus in its own right.

Remains of Palaeoloxodon species have probably been noted since ancient times where their remains like those of other fossil proboscideans were interpreted as those of giants or other mythical beings.<ref name=":3" /> In 1695, remains of a straight-tusked elephant were collected from travertine deposits near Burgtonna in what is now Thuringia, Germany. While these remains were originally declared by the Collegium Medicum in the nearby city of Gotha to be purely mineral in nature, Wilhelm Ernst Tentzel, a polymath in the employ of the ducal court of Saxe-Gotha-Altenburg, correctly recognised that they represented the remains of an elephant.<ref>Template:Cite journal</ref> Prior to 1845, the remains of Eurasian species of Palaeoloxodon were considered to be those of woolly mammoths. The earliest species of Palaeoloxodon to be described, the European straight-tusked elephant (Palaeoloxodon antiquus) and the South Asian Palaeoloxodon namadicus, were named by British paleontologists Hugh Falconer and Proby Cautley in 1846-47. Prior to the description of the genus, Palaeoloxodon species were initially placed in the genus Elephas (which includes the Asian elephant).<ref name=":21">Davies, Paul; (2002) The straight-tusked elephant (Palaeoloxodon antiquus) in Pleistocene Europe. Doctoral thesis (Ph.D), UCL (University College London).</ref> In 1924, Matsumoto Hikoshichirō coined Palaeoloxodon, and circumscribed it as a subgenus of Loxodonta (which include the living species of African elephants). It included the "E. antiquus—namadicus group", and he designated the Japanese "E. namadicus naumanni Mak." as its type species.<ref name="Matsumoto, 1924">Template:Cite journal</ref> Also in 1924, American paleontologist Henry Fairfield Osborn named the genera Sivalika and Pilgrimia, with the former covering the Asian species and the latter covering the African and Mediterranean island dwarf species of Paleoloxodon. In 1931 Osborn named the genus Hesperoloxodon to include Palaeoloxodon antiquus. In a 1942 posthumous publication, Osborn recognised Sivalika and Pilgrimia as junior synonyms of Palaeoloxodon, while still recognising Hesperoloxodon as valid.<ref name=":3" /> This publication was the first to consider Palaeoloxodon a valid genus in its own right, an opinion followed by later authors such as Emiliano Aguirre in 1969.<ref name=":1" /> Later authors have considered Hesperoloxodon another synonym of Palaeoloxodon. Vincent J. Maglio in a 1973 publication controversially synonymised Palaeoloxodon with Elephas based on morphological similarities between the two genera.<ref name=":3" /> Later authors either considered Palaeoloxodon a valid genus or a subgenus of Elephas. Cladistic analyses finding Elephas and Palaeoloxodon to not be each other's closest relatives led to the placement of Palaeoloxodon species within Elephas to be questioned by other authors.<ref name="relat2007" /><ref name=":3" /> By the 2010s Palaeoloxodon was widely regarded as a valid genus separate from Elephas.<ref name=":3" />

During the 19th and 20th centuries, species of Palaeoloxodon were subject to numerous phylogenetic hypotheses regarding their relationship to other elephantids. Some scholars like Hans Pohlig in 1891 and Osborn in 1935 considered the species of Palaeoloxodon to be closely related to African elephants, while others like Wolfgang Soergel in 1915 considered them to be closely related to mammoths.<ref name=":7">Zhang, Steven "The Rise and Fall of The Straight-Tusked Elephants" June 2021 East Tennessee State University Natural History Museum & Gray Fossil Site Paleotalks Episode 49. Relevant content begins around 12:20</ref> From the late 20th century to the first decade of the 21st century, Palaeoloxodon was usually considered to be closely related the Asian elephant and other members of the genus Elephas.<ref name=":1" /><ref name=":7" /> In 2016, a study of the straight-tusked elephant (P. antiquus) mitochondrial genome and part of the nuclear genome found that the mitochondrial sequences were nested within the diversity of those of the African forest elephant, Loxodonta cyclotis, with the partial nuclear genome supporting P. antiquus as more closely related to L. cyclotis than the African bush elephant, L. africana.<ref>Template:Cite journal</ref> A later study published in 2018 by the same authors based on the complete nuclear genome revised these results, and suggested P. antiquus resulted from reticulate evolution and had a complex hybridization history, with the majority (~60%) of its nuclear genome coming from a lineage more closely related to modern African elephants than to Asian elephants and mammoths, but which diverged before the split between the two living species, with significant introgressed ancestry from African forest elephants (~36%) and to a lesser extent mammoths (~6%). The ancestry from L. cyclotis was more closely related to modern West African populations of the forest elephant than to other forest elephant populations, while the mammoth ancestry was basal to the split between woolly and Columbian mammoths, probably from shortly after the split between the ancestors of mammoths and Asian elephants. The hybridisation probably took place in Africa, where Palaeoloxodon was dominant for most of the Early Pleistocene, with the mammoth hybridisation suggested to have taken place earlier than the hybridisation with forest elephants.<ref name=":5">Template:Cite journal</ref>

Analysis of mitochondrial genomes, including Palaeoloxodon individuals from Northern China indicates Palaeoloxodon individuals harboured multiple separate mitochondrial genome lineages derived from African forest elephants, some being more closely related to some West African forest elephant groups than to others. It is unclear as to whether this is the result of multiple hybridisation events, or whether multiple mitochondrial lineages were introgressed in a single event. It has been found that mitochondrial genome of Chinese Palaeoloxodon specimens clustered with a P. antiquus individual from western Europe, which belonged to a separate clade than other sampled European P. antiquus specimens. The relatively low divergence between the mitochondrial genomes of the European P. antiquus individual and the Chinese Palaeoloxodon specimens may indicate that the populations of Palaeoloxodon across Eurasia maintained gene flow with each other, but this is uncertain.<ref name=":4">Template:Cite journal</ref>

Diagram of the relationships of elephant mitochondrial genomes, after Lin et al. 2023:<ref name=":4" /> (note:mitochondrial genomes are only a single genetic locus and in contrast to the nuclear genome, do not necessarily accurately reflect true ancestral history)Template:Clade

• P. recki (Synonym: Elephas recki) (East Africa), the oldest species and ancestor of all later species
• P. jolensis (Synonym: Elephas iolensis) the last (late Middle-Late Pleistocene) representative of Palaeoloxodon in Africa
• P. antiquus (Synonym: Elephas antiquus) (Straight tusked elephant) (Europe, Western Asia)
• P. huaihoensis (China)
• P. namadicus (Synonym: Elephas namadicus)<ref>Kevrekidis, C., & Mol, D. (2016). A new partial skeleton of Elephas (Palaeoloxodon) antiquus Falconer and Cautley, 1847 (Proboscidea, Elephantidae) from Amyntaio, Macedonia, Greece. Quaternary International, 406, 35–56. https://doi.org/10.1016/j.quaint.2015.11.110</ref> (Indian subcontinent, possibly also elsewhere in Asia), the largest in its genus, and possibly the largest terrestrial mammal ever
• P. naumanni (Synonym: E. namadicus naumanni) (Naumann's elephant) (Japan, possibly also China and Korea)<ref>Template:Cite book</ref>
• P. turkmenicus known from a specimen found in the Middle Pleistocene of Turkmenistan in Central Asia, as well as a specimen from the Kashmir Valley in the northwest Indian subcontinent.

These Mediterranean insular dwarf elephant species are almost certainly descended from P. antiquus

• P. creutzburgi (Crete)
• P. xylophagou (Cyprus)
• P. cypriotes (Cyprus)
• P. lomolinoi (Naxos)
• P. tiliensis (Tilos)
• P. mnaidriensis (Sicily and Malta)
• P. falconeri (Sicily and Malta)

Other indeterminate dwarf Palaeoloxodon species are known from other Greek islands, including Rhodes and Kasos.<ref name=":6" />

Template:See also Many species of Palaeoloxodon are noted for the distinctive parieto-occipital crest, a bone growth at the top of the skull above the nasal opening which projects forwards and overhangs the rest of the skull. The crest probably functioned to anchor muscle tissue, including the splenius as well as an additional muscle layer called the "extra splenius" (which was likely similar to the "splenius superficialis" found in Asian elephants, and which may have been an extension of the rhomboideus cervicis muscle) which wrapped around the top of the head to support it. The development of the crest is variable depending on the species, growth stage and gender, with females and juveniles having less developed or absent crests. The crest likely developed as a response to the large size of the head, which in proportional and absolute terms are the largest in size of any proboscideans.<ref name=":1" /> The skull is proportionally short and tall,<ref name=":3">Template:Citation</ref> with the premaxillary bones containing the tusks being flared outwards. The tusks have relatively little curvature, and are proportionally large,<ref name=":1">Template:Cite journal</ref> and somewhat twisted, with the tusk alveoli (sockets) being divergent from each other at least in Pleistocene species.<ref name=":3" /> These tusks could reach Template:Convert in length, and probably over Template:Convert in weight in the largest species, larger than any recorded in modern elephants.<ref>Template:Cite journal</ref>

The molar teeth of Palaeoloxodon species typically show a "dot-dash-dot" wear pattern,<ref>Template:Cite journal</ref> with the enamel folds concentrated into a major central structure at the midline of the tooth, which are flanked by smaller folds on either side, and the crowns of the tooth are generally proportionally narrow.<ref>Template:Cite journal</ref> The teeth are typically very hypsodont (high crowned) with a substantial number of lamellae (up to 19<ref name=":1" /> to 21<ref name=":162">Template:Cite journal</ref> on the third molar), though the lamellae frequency is distinctly lower than that reached by advanced mammoth species.<ref name=":3" /> The morphology of the teeth varies little between non-dwarf Eurasian Palaeoloxodon species, meaning that they generally cannot be distinguished based on tooth morphology alone.<ref name=":03">Template:Cite journal</ref>

Species of Palaeoloxodon varied widely in size. Fully grown bulls of Palaeoloxodon recki, Palaeoloxodon antiquus, Palaeoloxodon namadicus and Chinese Palaeoloxodon grew substantially larger than living elephants, with some mature bulls exceeding Template:Convert tall at the shoulder and Template:Convert in body mass, making them some of the largest known terrestrial mammals to have ever lived.<ref>Template:Cite journal</ref><ref name="probos_mass" /> In a 2015 study, one fragmentary unlocated femur of P. namadicus described in the 19th century was estimated to have belonged to an individual Template:Convert tall and Template:Convert in weight, exceeding the estimates for the otherwise largest known land mammals, the paraceratheres. However, this estimate is highly speculative and the author suggested that it should be "taken with a grain of salt".<ref name="probos_mass" /> In contrast, some of the island dwarf species are the smallest elephants known. The smallest species, P. cypriotes and P. falconeri, only reached Template:Convert tall as fully grown adults,<ref>Template:Cite journal</ref><ref name=":2">Template:Cite journal</ref> with fully grown adult bulls of P. falconeri having an estimated body mass of only Template:Convert.<ref name=":2" />

{{#invoke:Gallery|gallery}}

Template:See also Species of Palaeoloxodon are thought to have had similar social behaviour to modern elephants, with herds of adult females and juveniles, as well as solitary adult males.<ref>Template:Cite journal</ref> The African species of Palaeoloxodon, as well as P. namadicus are suggested to have been grazers,<ref name=":02">Template:Cite journal</ref><ref>Template:Cite journal</ref> while P. antiquus is suggested to have been a variable mixed feeder that consumed a considerable amount of browse.<ref>Template:Cite journal</ref>

Palaeoloxodon first unambiguously appears in the fossil record in Africa during the Early Pleistocene, around 1.8 million years ago as the species Palaeoloxodon recki ileretensis (it is contested whether earlier "E. recki" subspecies are related to Palaeoloxodon).<ref name=":23">Template:Cite book</ref> P. recki was the dominant elephant in East Africa for most of the Pleistocene. A population of P. recki migrated out of Africa at the beginning of the Middle Pleistocene around 800,000 years ago, diversifying into the radiation of Eurasian Palaeoloxodon species, including P. antiquus, and P. namadicus. The precise relationships of the Eurasian taxa to each other are obscure.<ref name=":0" /> The arrival of P. antiquus in Europe co-incides with the extinction of the temperate adapted mammoth species Mammuthus meridionalis (sometimes called the southern mammoth) and its replacement by Mammuthus trogontherii (the steppe mammoth) in Europe, with the extinction of M. meridionalis possibly in part a result of competition with P. antiquus.<ref name=":0">Template:Citation</ref> P. antiquus was able to disperse onto many islands in the Mediterranean, undergoing insular dwarfism and speciating into numerous distinct varieties of dwarf elephants. Palaeoloxodon fossils are abundant in China and are assigned to three species, P. namadicus, P. naumanni and P. huaihoensis.<ref>Template:Cite journal</ref> However, the relationships of Chinese Palaeoloxodon are currently unresolved and it is unclear how many species were present in the region.<ref name=":1" />

Template:Further

Evidence of interaction with Palaeoloxodon by archaic humans extends back over 1 million years ago in Africa, with a number sites with Palaeoloxodon recki in Africa showing evidence of butchery.<ref>Template:Cite journal</ref> There is extensive evidence for butchery and to a lesser extent hunting of the European straight-tusked elephant by archaic humans like Homo heidelbergensis and Neanderthals.<ref name=":8">Template:Cite journal</ref> Evidence has been found for butchery of Palaeoloxodon turkmenicus by archaic humans in the Indian subcontinent.<ref>Template:Cite journal</ref> Based on the association of their remains with stone artefacts, it has been suggested modern humans encountered and butchered the Japanese P. naumanni and the Cyprus dwarf elephant P. cypriotes during the Last Glacial Period.<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref>

Template:See also The timing of the extinction of the last Paleoloxodon species in Africa, P. jolensis, is uncertain. While often suggested to have gone extinct during the Late Pleistocene, most specimens of the species are poorly dated and dating of specimens from Kenya suggests that it went extinct there around 130,000 years ago, at the end of the Middle Pleistocene.<ref name=":02"/> Most Eurasian species of Palaeoloxodon became extinct towards the end of the Last Glacial Period as part of the Late Pleistocene extinction event of most large terrestrial mammals globally, probably as a result of climate change, human activity, or a combination of both.<ref name=":25">Template:Cite journal</ref> The youngest records of P. antiquus are from the Iberian Peninsula, dating to around 44-43,000 years ago, with footprints from the southern part of the peninsula possibly extending the record to 28,000 years ago.<ref>Template:Cite journal</ref> The youngest Japanese records of P. naumanni date to around 24,000 years ago.<ref>Template:Cite journal</ref> The timing of extinction of Chinese Palaeoloxodon and Indian P. namadicus is uncertain, but claims of a Holocene survival are not substantiated for either region.<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref><ref>Template:Cite journal</ref> The youngest dates for the Sicilian dwarf elephant P. cf. mnaidriensis are around 32-20,000 years ago,<ref name=":22">Template:Cite journal</ref> while those of Cyprus dwarf elephant P. cypriotes are around 12,000 years ago, shortly after humans arrived to the island.<ref>Template:Cite journal</ref> The dwarf elephant P. tiliensis from the Greek island of Tilos is suggested by some authors to have survived as recently as 3,500 years Before Present (around 1500 BC) based on preliminary radiocarbon dating done in the 1970s, which would make it the youngest surviving elephant in Europe, but this has not been thoroughly investigated.<ref name=":6">Template:Cite journal</ref>

Template:Reflist

Template:Proboscidea Genera Template:Taxonbar