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Denisovan

January 19, 2024

The Denisovans or Denisova hominins ( /dɪˈnsəvə/ di-NEE-sə-və) are an extinct species or subspecies of archaic human that ranged across Asia during the Lower and Middle Paleolithic. Denisovans are known from few physical remains; consequently, most of what is known about them comes from DNA evidence. No formal species name has been established pending more complete fossil material.

Denisova 4, a molar

The first identification of a Denisovan individual occurred in 2010, based on mitochondrial DNA (mtDNA) extracted from a juvenile female finger bone excavated from the Siberian Denisova Cave in the Altai Mountains in 2008.[1] Nuclear DNA indicates close affinities with Neanderthals. The cave was also periodically inhabited by Neanderthals, but it is unclear whether Neanderthals and Denisovans ever cohabited in the cave. Additional specimens from Denisova Cave were subsequently identified, as was a single specimen from the Baishiya Karst Cave on the Tibetan Plateau, and Cobra Cave in the Annamite Mountains of Laos. DNA evidence suggests they had dark skin, eyes, and hair, and had a Neanderthal-like build and facial features. However, they had larger molars which are reminiscent of Middle to Late Pleistocene archaic humans and australopithecines.

Denisovans apparently interbred with modern humans, with a high percentage (roughly 5%) occurring in Melanesians, Aboriginal Australians, and Filipino Negritos. This distribution suggests that there were Denisovan populations across Asia. There is also evidence of interbreeding with the Altai Neanderthal population, with about 17% of the Denisovan genome from Denisova Cave deriving from them. A first-generation hybrid nicknamed "Denny" was discovered with a Denisovan father and a Neanderthal mother. Additionally, 4% of the Denisovan genome comes from an unknown archaic human species which diverged from modern humans over one million years ago.

Taxonomy edit

Denisovans may represent a new species of Homo or an archaic subspecies of Homo sapiens (modern humans), but there are too few fossils to erect a proper taxon. Proactively proposed species names for Denisovans are H. denisova[2] or H. altaiensis.[3]

Discovery edit

 
 
Denisova Cave
 
Baishiya Karst Cave
 
Tam Ngu Hao 2 Cave
class=notpageimage|
Locations of paleoarchaeological finds linked to Denisovans: Denisova Cave (blue) in the Altai Mountains of Siberia; Baishiya Karst Cave (yellow) on the Tibetan Plateau; and Tam Ngu Hao 2 Cave (grey) in northern Laos
 
The Denisova Cave, where the first reported Denisovans were found

Denisova Cave is in south-central Siberia, Russia, in the Altai Mountains near the border with Kazakhstan, China and Mongolia. It is named after Denis (Dyonisiy), a Russian hermit who lived there in the 18th century. The cave was first inspected for fossils in the 1970s by Russian paleontologist Nikolai Ovodov, who was looking for remains of canids.[4]

In 2008, Michael Shunkov from the Russian Academy of Sciences and other Russian archaeologists from the Institute of Archaeology and Ethnography of the Siberian Branch of the Russian Academy of Sciences in Novosibirsk Akademgorodok investigated the cave and found the finger bone of a juvenile female hominin originally dated to 50–30,000 years ago.[1][5] The estimate has changed to 76,200–51,600 years ago.[6] The specimen was originally named X-woman because matrilineal mitochondrial DNA (mtDNA) extracted from the bone demonstrated it to belong to a novel ancient hominin, genetically distinct both from contemporary modern humans and from Neanderthals.[1]

In 2019, Greek archaeologist Katerina Douka and colleagues radiocarbon dated specimens from Denisova Cave, and estimated that Denisova 2 (the oldest specimen) lived 195,000–122,700 years ago.[6] Older Denisovan DNA collected from sediments in the East Chamber dates to 217,000 years ago. Based on artifacts also discovered in the cave, hominin occupation (most likely by Denisovans) began 287±41 or 203±14 ka. Neanderthals were also present 193±12 ka and 97±11 ka, possibly concurrently with Denisovans.[7]

Specimens edit

"Woman X" redirects here. For other uses, see X woman (disambiguation).

The fossils of five distinct Denisovan individuals from Denisova Cave have been identified through their ancient DNA (aDNA): Denisova 2, 3, 4, 8, and 11. An mtDNA-based phylogenetic analysis of these individuals suggests that Denisova 2 is the oldest, followed by Denisova 8, while Denisova 3 and Denisova 4 were roughly contemporaneous.[8] During DNA sequencing, a low proportion of the Denisova 2, Denisova 4 and Denisova 8 genomes were found to have survived, but a high proportion of the Denisova 3 genome was intact.[8][9] The Denisova 3 sample was cut into two, and the initial DNA sequencing of one fragment was later independently confirmed by sequencing the mtDNA from the second.[10]

These specimens remained the only known examples of Denisovans until 2019, when a research group led by Fahu Chen, Dongju Zhang and Jean-Jacques Hublin described a partial mandible discovered in 1980 by a Buddhist monk in the Baishiya Karst Cave on the Tibetan Plateau in China. Known as the Xiahe mandible, the fossil became part of the collection of Lanzhou University, where it remained unstudied until 2010.[11] It was determined by ancient protein analysis to contain collagen that by sequence was found to have close affiliation to that of the Denisovans from Denisova Cave, while uranium decay dating of the carbonate crust enshrouding the specimen indicated it was more than 160,000 years old.[12] The identity of this population was later confirmed through study of environmental DNA, which found Denisovan mtDNA in sediment layers ranging in date from 100,000 to 60,000 years before present, and perhaps more recent.[13]

In 2018, a team of Laotian, French, and American anthropologists, who had been excavating caves in the Laotian jungle of the Annamite Mountains since 2008, was directed by local children to the site Tam Ngu Hao 2 ("Cobra Cave") where they recovered a human tooth. The tooth (catalogue number TNH2-1) developmentally matches a 3.5 to 8.5 year old, and a lack of amelogenin (a protein on the Y chromosome) suggests it belonged to a girl barring extreme degradation of the protein over a long period of time. Dental proteome analysis was inconclusive for this specimen, but the team found it anatomically comparable with the Xiahe mandible, and so tentatively categorized it as a Denisovan, although they could not rule out it being Neanderthal. The tooth probably dates to 164,000 to 131,000 years ago.[14]

Some older findings may or may not belong to the Denisovan line, but Asia is not well mapped in regards to human evolution. Such findings include the Dali skull,[15] the Xujiayao hominin,[16] Maba Man, the Jinniushan hominin, and the Narmada Human.[17] The Xiahe mandible shows morphological similarities to some later East Asian fossils such as Penghu 1,[12][18] but also to Chinese H. erectus.[10] In 2021, Chinese palaeoanthropologist Qiang Ji suggested his newly erected species, H. longi, may represent the Denisovans based on the similarity between the type specimen's molar and that of the Xiahe mandible.[19]

Name Fossil elements Age Discovery Place Sex and age Publication Image GenBank accession
Denisova 3
(also known as X Woman)[20][10][1]		 Distal phalanx of the fifth finger 76.2–51.6 ka[6] 2008 Denisova cave (Russia) 13.5-year-old adolescent female 2010
 
Replica of part of the phalanx.
 NC013993
Denisova 4[20][15] Permanent upper 2nd or 3rd molar 84.1–55.2 ka[6] 2000 Denisova cave (Russia) Adult male 2010
 
Replica of the molar of Denisova. Part of the roots was destroyed to study the mtDNA. Their size and shape indicate it is neither neanderthal nor sapiens.
 FR695060
Denisova 8[9] Permanent upper 3rd molar 136.4–105.6 ka[6] 2010 Denisova cave (Russia) Adult male 2015 KT780370
Denisova 2[8] Deciduous 2nd lower molar 194.4–122.7 ka[6] 1984 Denisova cave (Russia) Adolescent female 2017 KX663333
Xiahe mandible[12] Partial mandible > 160 ka 1980 Baishiya Cave (China) 2019  
Denisova 11
(also known as Denny, Denisovan x Neanderthal hybrid)
[21]		 Arm or leg bone fragment 118.1–79.3 ka[6] 2012 Denisova cave (Russia) 13 year old adolescent female 2016  

KU131206

Denisova 13[22] Parietal bone fragment Found in layer 22[22] which dates to ~285±39 ka[7] 2019 Denisova cave (Russia) pending
TNH2-1[14] Permanent lower left 1st or 2nd molar 164–131 ka 2018 Tam Ngu Hao 2 cave (Laos) 3.5 to 8.5 year old female 2022  

Evolution edit

 
The evolution and geographic spread of Denisovans as compared with Neanderthals, Homo heidelbergensis and Homo erectus

Sequenced mitochondrial DNA (mtDNA), preserved by the cool climate of the cave (average temperature is at freezing point), was extracted from Denisova 3 by a team of scientists led by Johannes Krause and Svante Pääbo from the Max Planck Institute for Evolutionary Anthropology in Leipzig, Germany. Denisova 3's mtDNA differs from that of modern humans by 385 bases (nucleotides) out of approximately 16,500, whereas the difference between modern humans and Neanderthals is around 202 bases. In comparison, the difference between chimpanzees and modern humans is approximately 1,462 mtDNA base pairs. This suggested that Denisovan mtDNA diverged from that of modern humans and Neanderthals about 1,313,500–779,300 years ago; whereas modern human and Neanderthal mtDNA diverged 618,000–321,200 years ago. Krause and colleagues then concluded that Denisovans were the descendants of an earlier migration of H. erectus out of Africa, completely distinct from modern humans and Neanderthals.[1]

However, according to the nuclear DNA (nDNA) of Denisova 3—which had an unusual degree of DNA preservation with only low-level contamination—Denisovans and Neanderthals were more closely related to each other than they were to modern humans. Using the percent distance from human–chimpanzee last common ancestor, Denisovans/Neanderthals split from modern humans about 804,000 years ago, and from each other 640,000 years ago.[20] Using a mutation rate of 1×10−9 or 0.5×10−9 per base pair (bp) per year, the Neanderthal/Denisovan split occurred around either 236–190,000 or 473–381,000 years ago respectively.[23] Using 1.1×10−8 per generation with a new generation every 29 years, the time is 744,000 years ago. Using 5×10−10 nucleotide site per year, it is 616,000 years ago. Using the latter dates, the split had likely already occurred by the time hominins spread out across Europe.[24] H. heidelbergensis is typically considered to have been the direct ancestor of Denisovans and Neanderthals, and sometimes also modern humans.[25] Due to the strong divergence in dental anatomy, they may have split before characteristic Neanderthal dentition evolved about 300,000 years ago.[20]

The more divergent Denisovan mtDNA has been interpreted as evidence of admixture between Denisovans and an unknown archaic human population,[26] possibly a relict H. erectus or H. erectus-like population about 53,000 years ago.[23] Alternatively, divergent mtDNA could have also resulted from the persistence of an ancient mtDNA lineage which only went extinct in modern humans and Neanderthals through genetic drift.[20] Modern humans contributed mtDNA to the Neanderthal lineage, but not to the Denisovan mitochondrial genomes yet sequenced.[27][28][29][30] The mtDNA sequence from the femur of a 400,000-year-old H. heidelbergensis from the Sima de los Huesos Cave in Spain was found to be related to those of Neanderthals and Denisovans, but closer to Denisovans,[31][32] and the authors posited that this mtDNA represents an archaic sequence which was subsequently lost in Neanderthals due to replacement by a modern-human-related sequence.[33]

Demographics edit

See also: Archaic humans in Southeast Asia
 
Denisovans appear to have crossed the Wallace Line.[17]

Denisovans are known to have lived in Siberia, Tibet, and Laos.[14] The Xiahe mandible is the earliest recorded human presence on the Tibetan Plateau.[12] Though their remains have been identified in only these three locations, traces of Denisovan DNA in modern humans suggest they ranged across East Asia,[34][35] and potentially western Eurasia.[36] In 2019, geneticist Guy Jacobs and colleagues identified three distinct populations of Denisovans responsible for the introgression into modern populations now native to, respectively: Siberia and East Asia; New Guinea and nearby islands; and Oceania and, to a lesser extent, across Asia. Using coalescent modeling, the Denisova Cave Denisovans split from the second population about 283,000 years ago; and from the third population about 363,000 years ago. This indicates that there was considerable reproductive isolation between Denisovan populations.[37]

Based on the high percentages of Denisovan DNA in modern Papuans and Australians, Denisovans may have crossed the Wallace Line into these regions (with little back-migration west), the second known human species to do so,[17] along with earlier Homo floresiensis. By this logic, they may have also entered the Philippines, living alongside H. luzonensis which, if this is the case, may represent the same or a closely related species.[38] These Denisovans may have needed to cross large bodies of water.[37] Alternately, high Denisovan DNA admixture in modern Papuan populations may simply represent higher mixing among the original ancestors of Papuans prior to crossing the Wallace line. Icelanders also have an anomalously high Denisovan heritage, which could have stemmed from a Denisovan population far west of the Altai mountains. Genetic data suggests Neanderthals were frequently making long crossings between Europe and the Altai mountains especially towards the date of their extinction.[36]

Using exponential distribution analysis on haplotype lengths, Jacobs calculated introgression into modern humans occurred about 29,900 years ago with the Denisovan population ancestral to New Guineans; and 45,700 years ago with the population ancestral to both New Guineans and Oceanians. Such a late date for the New Guinean group could indicate Denisovan survival as late as 14,500 years ago, which would make them the latest surviving archaic human species. A third wave appears to have introgressed into East Asia, but there is not enough DNA evidence to pinpoint a solid timeframe.[37]

The mtDNA from Denisova 4 bore a high similarity to that of Denisova 3, indicating that they belonged to the same population.[20] The genetic diversity among the Denisovans from Denisova Cave is on the lower range of what is seen in modern humans, and is comparable to that of Neanderthals. However, it is possible that the inhabitants of Denisova Cave were more or less reproductively isolated from other Denisovans, and that, across their entire range, Denisovan genetic diversity may have been much higher.[8]

Denisova Cave, over time of habitation, continually swung from a fairly warm and moderately humid pine and birch forest to tundra or forest-tundra landscape.[7] Conversely, Baishiya Karst Cave is situated at a high elevation, an area characterized by low temperature, low oxygen, and poor resource availability. Colonization of high-altitude regions, due to such harsh conditions, was previously assumed to have only been accomplished by modern humans.[12] Denisovans seem to have also inhabited the jungles of Southeast Asia.[35] The Tam Ngu Hao 2 site might have been a closed forest environment.[14]

Anatomy edit

Little is known of the precise anatomical features of the Denisovans since the only physical remains discovered so far are a finger bone, four teeth, long bone fragments, a partial jawbone,[11][14] and a parietal bone skull fragment.[22] The finger bone is within the modern human range of variation for women,[10] which is in contrast to the large, robust molars which are more similar to those of Middle to Late Pleistocene archaic humans. The third molar is outside the range of any Homo species except H. habilis and H. rudolfensis, and is more like those of australopithecines. The second molar is larger than those of modern humans and Neanderthals, and is more similar to those of H. erectus and H. habilis.[20] Like Neanderthals, the mandible had a gap behind the molars, and the front teeth were flattened; but Denisovans lacked a high mandibular body, and the mandibular symphysis at the midline of the jaw was more receding.[12][18] The parietal is reminiscent of that of H. erectus.[39]

A facial reconstruction has been generated by comparing methylation at individual genetic loci associated with facial structure.[40] This analysis suggested that Denisovans, much like Neanderthals, had a long, broad, and projecting face; large nose; sloping forehead; protruding jaw; elongated and flattened skull; and wide chest and hips. The Denisovan tooth row was longer than that of Neanderthals and anatomically modern humans.[41]

Middle-to-Late Pleistocene East Asian archaic human skullcaps typically share features with Neanderthals. The skullcaps from Xuchang feature prominent brow ridges like Neanderthals, though the nuchal and angular tori near the base of the skull are either reduced or absent, and the back of the skull is rounded off like in early modern humans. Xuchang 1 had a large brain volume of approximately 1800 cc, on the high end for Neanderthals and early modern humans, and well beyond the present-day human average.[42]

The Denisovan genome from Denisova Cave has variants of genes which, in modern humans, are associated with dark skin, brown hair, and brown eyes.[43] The Denisovan genome also contains a variant region around the EPAS1 gene that in Tibetans assists with adaptation to low oxygen levels at high elevation,[44][12] and in a region containing the WARS2 and TBX15 loci which affect body-fat distribution in the Inuit.[45] In Papuans, introgressed Neanderthal alleles are highest in frequency in genes expressed in the brain, whereas Denisovan alleles have highest frequency in genes expressed in bones and other tissue.[46]

Culture edit

Denisova Cave edit

 
 
Some ornaments (above) and animal bones and stone tools (below) found in Denisova Cave. Note, ornaments may have been crafted by modern humans

Early Middle Paleolithic stone tools from Denisova Cave were characterized by discoidal (disk-like) cores and Kombewa cores, but Levallois cores and flakes were also present. There were scrapers, denticulate tools, and notched tools, deposited about 287±41 thousand years ago in the Main Chamber of the cave; and about 269±97 thousand years ago in the South Chamber; up to 170±19 thousand and 187±14 thousand years ago in the Main and East Chambers, respectively.[7]

Middle Paleolithic assemblages were dominated by flat, discoidal, and Levallois cores, and there were some isolated sub-prismatic cores. There were predominantly side scrapers (a scraper with only the sides used to scrape), but also notched-denticulate tools, end-scrapers (a scraper with only the ends used to scrape), burins, chisel-like tools, and truncated flakes. These dated to 156±15 thousand years ago in the Main Chamber, 58±6 thousand years ago in the East Chamber, and 136±26–47±8 thousand years ago in the South Chamber.[7]

Early Upper Paleolithic artefacts date to 44±5 thousand years ago in the Main Chamber, 63±6 thousand years ago in the East Chamber, and 47±8 thousand years ago in the South Chamber, though some layers of the East Chamber seem to have been disturbed. There was blade production and Levallois production, but scrapers were again predominant. A well-developed, Upper Paleolithic stone bladelet technology distinct from the previous scrapers began accumulating in the Main Chamber around 36±4 thousand years ago.[7]

In the Upper Paleolithic layers, there were also several bone tools and ornaments: a marble ring, an ivory ring, an ivory pendant, a red deer tooth pendant, an elk tooth pendant, a chloritolite bracelet, and a bone needle. However, Denisovans are only confirmed to have inhabited the cave until 55 ka; the dating of Upper Paleolithic artefacts overlaps with modern human migration into Siberia (though there are no occurrences in the Altai region); and the DNA of the only specimen in the cave dating to the time interval (Denisova 14) is too degraded to confirm species identity, so the attribution of these artefacts is unclear.[47][7]

Tibet edit

In 1998, five child hand- and footprint impressions were discovered in a travertine unit near the Quesang hot springs in Tibet, which in 2021 were dated to 226 to 169 thousand years ago using uranium decay dating. This is the oldest evidence of human occupation of the Tibetan Plateau, and given the Xiahe mandible is the oldest human fossil from the region (albeit, younger than the Quesang impressions), these may have been made by Denisovan children. The impressions were printed onto a small panel of space, and there is little overlap between all the prints, so they seem to have been taking care to make new imprints in unused space. If considered art, they are the oldest known examples of rock art. Similar hand stencils and impressions do not appear again in the archeological record until roughly 40,000 years ago.[48]

The footprints comprise four right impressions and one left superimposed on one of the rights. They were probably left by two individuals. The tracks of the individual who superimposed their left onto their right may have scrunched up their toes and wiggled them in the mud, or dug their finger into the toe prints. The footprints average 192.3 mm (7.57 in) long, which roughly equates to a 7 or 8 year old child by modern human growth rates. There are two sets of handprints (from a left and right hand), which may have been created by an older child unless one of the former two individuals had long fingers. The handprints average 161.1 mm (6.34 in), which roughly equates with a 12 year old modern human child, and the middle finger length agrees with a 17 year old modern human. One of the handprints shows an impression of the forearm, and the individual was wiggling their thumb through the mud.[48]

Interbreeding edit

See also: Interbreeding between archaic and modern humans

Analyses of the modern human genomes indicate past interbreeding with at least two groups of archaic humans, Neanderthals[49] and Denisovans,[20][50] and that such interbreeding events occurred on multiple occasions. Comparisons of the Denisovan, Neanderthal, and modern human genomes have revealed evidence of a complex web of interbreeding among these lineages.[49]

Archaic humans edit

As much as 17% of the Denisovan genome from Denisova Cave represents DNA from the local Neanderthal population.[49] Denisova 11 was an F1 (first generation) Denisovan/Neanderthal hybrid; the fact that such an individual was found may indicate interbreeding was a common occurrence here.[51] The Denisovan genome shares more derived alleles with the Altai Neanderthal genome from Siberia than with the Vindija Cave Neanderthal genome from Croatia or the Mezmaiskaya cave Neanderthal genome from the Caucasus, suggesting that the gene flow came from a population that was more closely related to the local Altai Neanderthals.[52] However, Denny's Denisovan father had the typical Altai Neanderthal introgression, while her Neanderthal mother represented a population more closely related to Vindija Neanderthals.[53]

About 4% of the Denisovan genome derives from an unidentified archaic hominin,[49] perhaps the source of the anomalous ancient mtDNA, indicating this species diverged from Neanderthals and humans over a million years ago. The only identified Homo species of Late Pleistocene Asia are H. erectus and H. heidelbergensis,[52][54] though in 2021, specimens allocated to the latter species were reclassified as H. longi and H. daliensis.[55]

Before splitting from Neanderthals, their ancestors ("Neandersovans") migrating into Europe apparently interbred with an unidentified "superarchaic" human species who were already present there; these superarchaics were the descendants of a very early migration out of Africa around 1.9 mya.[56]

Modern humans edit

A 2011 study found that Denisovan DNA is prevalent in Papuans, Aboriginal Australians, Near Oceanians, Polynesians, Fijians, Eastern Indonesians and Aeta (from the Philippines); but not in East Asians, western Indonesians, Jahai people (from Malaysia) or Onge (from the Andaman Islands). This may suggest that Denisovan introgression occurred within the Pacific region rather than on the Asian mainland, and that ancestors of the latter groups were not present in Southeast Asia at the time.[35][57] In the Melanesian genome, about 4–6%[20] or 1.9–3.4% derives from Denisovan introgression.[58] Prior to 2021, New Guineans and Australian Aborigines were reported to have the most introgressed DNA,[17] but Australians have less than New Guineans.[59] A 2021 study discovered 30 to 40% more Denisovan ancestry in Aeta people in the Philippines than in Papuans, estimated as about 5% of the genome. The Aeta Magbukon in Luzon have the highest known proportion of Denisovan ancestry of any population in the world.[38] In Papuans, less Denisovan ancestry is seen in the X chromosome than autosomes, and some autosomes (such as chromosome 11) also have less Denisovan ancestry, which could indicate hybrid incompatibility. The former observation could also be explained by less female Denisovan introgression into modern humans, or more female modern human immigrants who diluted Denisovan X chromosome ancestry.[43]

In contrast, 0.2% derives from Denisovan ancestry in mainland Asians and Native Americans.[60] South Asians were found to have levels of Denisovan admixture similar to that seen in East Asians.[61] The discovery of the 40,000-year-old Chinese modern human Tianyuan Man lacking Denisovan DNA significantly different from the levels in modern-day East Asians discounts the hypothesis that immigrating modern humans simply diluted Denisovan ancestry whereas Melanesians lived in reproductive isolation.[62][17] A 2018 study of Han Chinese, Japanese, and Dai genomes showed that modern East Asians have DNA from two different Denisovan populations: one similar to the Denisovan DNA found in Papuan genomes, and a second that is closer to the Denisovan genome from Denisova Cave. This could indicate two separate introgression events involving two different Denisovan populations. In South Asian genomes, DNA only came from the same single Denisovan introgression seen in Papuans.[61] A 2019 study found a third wave of Denisovans which introgressed into East Asians. Introgression, also, may not have immediately occurred when modern humans immigrated into the region.[37]

The timing of introgression into Oceanian populations likely occurred after Eurasians and Oceanians split roughly 58,000 years ago, and before Papuan and Aboriginal Australians split from each other roughly 37,000 years ago. Given the present day distribution of Denisovan DNA, this may have taken place in Wallacea, though the discovery of a 7,200 year old Toalean girl (closely related to Papuans and Aboriginal Australians) from Sulawesi carrying Denisovan DNA makes Sundaland another potential candidate. Other early Sunda hunter gatherers so far sequenced carry very little Denisovan DNA, which either means the introgression event did not take place in Sundaland, or Denisovan ancestry was diluted with gene flow from the mainland Asian Hòabìnhian culture and subsequent Neolithic cultures.[63]

In other regions of the world, archaic introgression into humans stems from a group of Neanderthals related to those which inhabited Vindija Cave, Croatia, as opposed to archaics related to Siberian Neanderthals and Denisovans. However, about 3.3% of the archaic DNA in the modern Icelandic genome descends from the Denisovans, and such a high percentage could indicate a western Eurasian population of Denisovans which introgressed into either Vindija-related Neanderthals or immigrating modern humans.[36]

Denisovan genes may have helped early modern humans migrating out of Africa to acclimatize[citation needed]. Although not present in the sequenced Denisovan genome, the distribution pattern and divergence of HLA-B*73 from other HLA alleles (involved in the immune system's natural killer cell receptors) has led to the suggestion that it introgressed from Denisovans into modern humans in West Asia. In a 2011 study, half of the HLA alleles of modern Eurasians were shown to represent archaic HLA haplotypes, and were inferred to be of Denisovan or Neanderthal origin.[64] A haplotype of EPAS1 in modern Tibetans, which allows them to live at high elevations in a low-oxygen environment, likely came from Denisovans.[44][12] Genes related to phospholipid transporters (which are involved in fat metabolism) and to trace amine-associated receptors (involved in smelling) are more active in people with more Denisovan ancestry.[65] Denisovan genes may have conferred a degree of immunity against the G614 mutation of SARS-CoV-2.[66] Denisovan introgressions may have influenced the immune system of present-day Papuans and potentially favoured "variants to immune-related phenotypes" and "adaptation to the local environment".[67]

In December 2023, scientists reported that genes inherited by modern humans from Neanderthals and Denisovans may biologically influence the daily routine of modern humans.[68]

See also edit

References edit

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Further reading edit

  • Karlsson, Mattis. From Fossil To Fact: The Denisova Discovery as Science in Action (Thesis). LiU E-press. ISBN 9789179291716. Retrieved 18 March 2022.

External links edit

  •   Media related to Denisova at Wikimedia Commons
  • The Denisova Consortium's raw sequence data and alignments
  • Human Timeline (Interactive) – Smithsonian, National Museum of Natural History (August 2016).
  • Picture of Denisovan molar.

January 19, 2024
denisovan, denisova, hominins, extinct, species, subspecies, archaic, human, that, ranged, across, asia, during, lower, middle, paleolithic, known, from, physical, remains, consequently, most, what, known, about, them, comes, from, evidence, formal, species, n. The Denisovans or Denisova hominins d ɪ ˈ n iː s e v e di NEE se ve are an extinct species or subspecies of archaic human that ranged across Asia during the Lower and Middle Paleolithic Denisovans are known from few physical remains consequently most of what is known about them comes from DNA evidence No formal species name has been established pending more complete fossil material Denisova 4 a molarThe first identification of a Denisovan individual occurred in 2010 based on mitochondrial DNA mtDNA extracted from a juvenile female finger bone excavated from the Siberian Denisova Cave in the Altai Mountains in 2008 1 Nuclear DNA indicates close affinities with Neanderthals The cave was also periodically inhabited by Neanderthals but it is unclear whether Neanderthals and Denisovans ever cohabited in the cave Additional specimens from Denisova Cave were subsequently identified as was a single specimen from the Baishiya Karst Cave on the Tibetan Plateau and Cobra Cave in the Annamite Mountains of Laos DNA evidence suggests they had dark skin eyes and hair and had a Neanderthal like build and facial features However they had larger molars which are reminiscent of Middle to Late Pleistocene archaic humans and australopithecines Denisovans apparently interbred with modern humans with a high percentage roughly 5 occurring in Melanesians Aboriginal Australians and Filipino Negritos This distribution suggests that there were Denisovan populations across Asia There is also evidence of interbreeding with the Altai Neanderthal population with about 17 of the Denisovan genome from Denisova Cave deriving from them A first generation hybrid nicknamed Denny was discovered with a Denisovan father and a Neanderthal mother Additionally 4 of the Denisovan genome comes from an unknown archaic human species which diverged from modern humans over one million years ago Contents 1 Taxonomy 1 1 Discovery 1 2 Specimens 1 3 Evolution 2 Demographics 3 Anatomy 4 Culture 4 1 Denisova Cave 4 2 Tibet 5 Interbreeding 5 1 Archaic humans 5 2 Modern humans 6 See also 7 References 8 Further reading 9 External linksTaxonomy editDenisovans may represent a new species of Homo or an archaic subspecies of Homo sapiens modern humans but there are too few fossils to erect a proper taxon Proactively proposed species names for Denisovans are H denisova 2 or H altaiensis 3 Discovery edit nbsp nbsp Denisova Cave nbsp Baishiya Karst Cave nbsp Tam Ngu Hao 2 Caveclass notpageimage Locations of paleoarchaeological finds linked to Denisovans Denisova Cave blue in the Altai Mountains of Siberia Baishiya Karst Cave yellow on the Tibetan Plateau and Tam Ngu Hao 2 Cave grey in northern Laos nbsp The Denisova Cave where the first reported Denisovans were foundDenisova Cave is in south central Siberia Russia in the Altai Mountains near the border with Kazakhstan China and Mongolia It is named after Denis Dyonisiy a Russian hermit who lived there in the 18th century The cave was first inspected for fossils in the 1970s by Russian paleontologist Nikolai Ovodov who was looking for remains of canids 4 In 2008 Michael Shunkov from the Russian Academy of Sciences and other Russian archaeologists from the Institute of Archaeology and Ethnography of the Siberian Branch of the Russian Academy of Sciences in Novosibirsk Akademgorodok investigated the cave and found the finger bone of a juvenile female hominin originally dated to 50 30 000 years ago 1 5 The estimate has changed to 76 200 51 600 years ago 6 The specimen was originally named X woman because matrilineal mitochondrial DNA mtDNA extracted from the bone demonstrated it to belong to a novel ancient hominin genetically distinct both from contemporary modern humans and from Neanderthals 1 In 2019 Greek archaeologist Katerina Douka and colleagues radiocarbon dated specimens from Denisova Cave and estimated that Denisova 2 the oldest specimen lived 195 000 122 700 years ago 6 Older Denisovan DNA collected from sediments in the East Chamber dates to 217 000 years ago Based on artifacts also discovered in the cave hominin occupation most likely by Denisovans began 287 41 or 203 14 ka Neanderthals were also present 193 12 ka and 97 11 ka possibly concurrently with Denisovans 7 Specimens edit Woman X redirects here For other uses see X woman disambiguation The fossils of five distinct Denisovan individuals from Denisova Cave have been identified through their ancient DNA aDNA Denisova 2 3 4 8 and 11 An mtDNA based phylogenetic analysis of these individuals suggests that Denisova 2 is the oldest followed by Denisova 8 while Denisova 3 and Denisova 4 were roughly contemporaneous 8 During DNA sequencing a low proportion of the Denisova 2 Denisova 4 and Denisova 8 genomes were found to have survived but a high proportion of the Denisova 3 genome was intact 8 9 The Denisova 3 sample was cut into two and the initial DNA sequencing of one fragment was later independently confirmed by sequencing the mtDNA from the second 10 These specimens remained the only known examples of Denisovans until 2019 when a research group led by Fahu Chen Dongju Zhang and Jean Jacques Hublin described a partial mandible discovered in 1980 by a Buddhist monk in the Baishiya Karst Cave on the Tibetan Plateau in China Known as the Xiahe mandible the fossil became part of the collection of Lanzhou University where it remained unstudied until 2010 11 It was determined by ancient protein analysis to contain collagen that by sequence was found to have close affiliation to that of the Denisovans from Denisova Cave while uranium decay dating of the carbonate crust enshrouding the specimen indicated it was more than 160 000 years old 12 The identity of this population was later confirmed through study of environmental DNA which found Denisovan mtDNA in sediment layers ranging in date from 100 000 to 60 000 years before present and perhaps more recent 13 In 2018 a team of Laotian French and American anthropologists who had been excavating caves in the Laotian jungle of the Annamite Mountains since 2008 was directed by local children to the site Tam Ngu Hao 2 Cobra Cave where they recovered a human tooth The tooth catalogue number TNH2 1 developmentally matches a 3 5 to 8 5 year old and a lack of amelogenin a protein on the Y chromosome suggests it belonged to a girl barring extreme degradation of the protein over a long period of time Dental proteome analysis was inconclusive for this specimen but the team found it anatomically comparable with the Xiahe mandible and so tentatively categorized it as a Denisovan although they could not rule out it being Neanderthal The tooth probably dates to 164 000 to 131 000 years ago 14 Some older findings may or may not belong to the Denisovan line but Asia is not well mapped in regards to human evolution Such findings include the Dali skull 15 the Xujiayao hominin 16 Maba Man the Jinniushan hominin and the Narmada Human 17 The Xiahe mandible shows morphological similarities to some later East Asian fossils such as Penghu 1 12 18 but also to Chinese H erectus 10 In 2021 Chinese palaeoanthropologist Qiang Ji suggested his newly erected species H longi may represent the Denisovans based on the similarity between the type specimen s molar and that of the Xiahe mandible 19 Name Fossil elements Age Discovery Place Sex and age Publication Image GenBank accessionDenisova 3 also known as X Woman 20 10 1 Distal phalanx of the fifth finger 76 2 51 6 ka 6 2008 Denisova cave Russia 13 5 year old adolescent female 2010 nbsp Replica of part of the phalanx NC013993Denisova 4 20 15 Permanent upper 2nd or 3rd molar 84 1 55 2 ka 6 2000 Denisova cave Russia Adult male 2010 nbsp Replica of the molar of Denisova Part of the roots was destroyed to study the mtDNA Their size and shape indicate it is neither neanderthal nor sapiens FR695060Denisova 8 9 Permanent upper 3rd molar 136 4 105 6 ka 6 2010 Denisova cave Russia Adult male 2015 KT780370Denisova 2 8 Deciduous 2nd lower molar 194 4 122 7 ka 6 1984 Denisova cave Russia Adolescent female 2017 KX663333Xiahe mandible 12 Partial mandible gt 160 ka 1980 Baishiya Cave China 2019 nbsp Denisova 11 also known as Denny Denisovan x Neanderthal hybrid 21 Arm or leg bone fragment 118 1 79 3 ka 6 2012 Denisova cave Russia 13 year old adolescent female 2016 nbsp KU131206Denisova 13 22 Parietal bone fragment Found in layer 22 22 which dates to 285 39 ka 7 2019 Denisova cave Russia pendingTNH2 1 14 Permanent lower left 1st or 2nd molar 164 131 ka 2018 Tam Ngu Hao 2 cave Laos 3 5 to 8 5 year old female 2022 nbsp Evolution edit nbsp The evolution and geographic spread of Denisovans as compared with Neanderthals Homo heidelbergensis and Homo erectusSequenced mitochondrial DNA mtDNA preserved by the cool climate of the cave average temperature is at freezing point was extracted from Denisova 3 by a team of scientists led by Johannes Krause and Svante Paabo from the Max Planck Institute for Evolutionary Anthropology in Leipzig Germany Denisova 3 s mtDNA differs from that of modern humans by 385 bases nucleotides out of approximately 16 500 whereas the difference between modern humans and Neanderthals is around 202 bases In comparison the difference between chimpanzees and modern humans is approximately 1 462 mtDNA base pairs This suggested that Denisovan mtDNA diverged from that of modern humans and Neanderthals about 1 313 500 779 300 years ago whereas modern human and Neanderthal mtDNA diverged 618 000 321 200 years ago Krause and colleagues then concluded that Denisovans were the descendants of an earlier migration of H erectus out of Africa completely distinct from modern humans and Neanderthals 1 However according to the nuclear DNA nDNA of Denisova 3 which had an unusual degree of DNA preservation with only low level contamination Denisovans and Neanderthals were more closely related to each other than they were to modern humans Using the percent distance from human chimpanzee last common ancestor Denisovans Neanderthals split from modern humans about 804 000 years ago and from each other 640 000 years ago 20 Using a mutation rate of 1 10 9 or 0 5 10 9 per base pair bp per year the Neanderthal Denisovan split occurred around either 236 190 000 or 473 381 000 years ago respectively 23 Using 1 1 10 8 per generation with a new generation every 29 years the time is 744 000 years ago Using 5 10 10 nucleotide site per year it is 616 000 years ago Using the latter dates the split had likely already occurred by the time hominins spread out across Europe 24 H heidelbergensis is typically considered to have been the direct ancestor of Denisovans and Neanderthals and sometimes also modern humans 25 Due to the strong divergence in dental anatomy they may have split before characteristic Neanderthal dentition evolved about 300 000 years ago 20 The more divergent Denisovan mtDNA has been interpreted as evidence of admixture between Denisovans and an unknown archaic human population 26 possibly a relict H erectus or H erectus like population about 53 000 years ago 23 Alternatively divergent mtDNA could have also resulted from the persistence of an ancient mtDNA lineage which only went extinct in modern humans and Neanderthals through genetic drift 20 Modern humans contributed mtDNA to the Neanderthal lineage but not to the Denisovan mitochondrial genomes yet sequenced 27 28 29 30 The mtDNA sequence from the femur of a 400 000 year old H heidelbergensis from the Sima de los Huesos Cave in Spain was found to be related to those of Neanderthals and Denisovans but closer to Denisovans 31 32 and the authors posited that this mtDNA represents an archaic sequence which was subsequently lost in Neanderthals due to replacement by a modern human related sequence 33 Demographics editSee also Archaic humans in Southeast Asia nbsp Denisovans appear to have crossed the Wallace Line 17 Denisovans are known to have lived in Siberia Tibet and Laos 14 The Xiahe mandible is the earliest recorded human presence on the Tibetan Plateau 12 Though their remains have been identified in only these three locations traces of Denisovan DNA in modern humans suggest they ranged across East Asia 34 35 and potentially western Eurasia 36 In 2019 geneticist Guy Jacobs and colleagues identified three distinct populations of Denisovans responsible for the introgression into modern populations now native to respectively Siberia and East Asia New Guinea and nearby islands and Oceania and to a lesser extent across Asia Using coalescent modeling the Denisova Cave Denisovans split from the second population about 283 000 years ago and from the third population about 363 000 years ago This indicates that there was considerable reproductive isolation between Denisovan populations 37 Based on the high percentages of Denisovan DNA in modern Papuans and Australians Denisovans may have crossed the Wallace Line into these regions with little back migration west the second known human species to do so 17 along with earlier Homo floresiensis By this logic they may have also entered the Philippines living alongside H luzonensis which if this is the case may represent the same or a closely related species 38 These Denisovans may have needed to cross large bodies of water 37 Alternately high Denisovan DNA admixture in modern Papuan populations may simply represent higher mixing among the original ancestors of Papuans prior to crossing the Wallace line Icelanders also have an anomalously high Denisovan heritage which could have stemmed from a Denisovan population far west of the Altai mountains Genetic data suggests Neanderthals were frequently making long crossings between Europe and the Altai mountains especially towards the date of their extinction 36 Using exponential distribution analysis on haplotype lengths Jacobs calculated introgression into modern humans occurred about 29 900 years ago with the Denisovan population ancestral to New Guineans and 45 700 years ago with the population ancestral to both New Guineans and Oceanians Such a late date for the New Guinean group could indicate Denisovan survival as late as 14 500 years ago which would make them the latest surviving archaic human species A third wave appears to have introgressed into East Asia but there is not enough DNA evidence to pinpoint a solid timeframe 37 The mtDNA from Denisova 4 bore a high similarity to that of Denisova 3 indicating that they belonged to the same population 20 The genetic diversity among the Denisovans from Denisova Cave is on the lower range of what is seen in modern humans and is comparable to that of Neanderthals However it is possible that the inhabitants of Denisova Cave were more or less reproductively isolated from other Denisovans and that across their entire range Denisovan genetic diversity may have been much higher 8 Denisova Cave over time of habitation continually swung from a fairly warm and moderately humid pine and birch forest to tundra or forest tundra landscape 7 Conversely Baishiya Karst Cave is situated at a high elevation an area characterized by low temperature low oxygen and poor resource availability Colonization of high altitude regions due to such harsh conditions was previously assumed to have only been accomplished by modern humans 12 Denisovans seem to have also inhabited the jungles of Southeast Asia 35 The Tam Ngu Hao 2 site might have been a closed forest environment 14 Anatomy editLittle is known of the precise anatomical features of the Denisovans since the only physical remains discovered so far are a finger bone four teeth long bone fragments a partial jawbone 11 14 and a parietal bone skull fragment 22 The finger bone is within the modern human range of variation for women 10 which is in contrast to the large robust molars which are more similar to those of Middle to Late Pleistocene archaic humans The third molar is outside the range of any Homo species except H habilis and H rudolfensis and is more like those of australopithecines The second molar is larger than those of modern humans and Neanderthals and is more similar to those of H erectus and H habilis 20 Like Neanderthals the mandible had a gap behind the molars and the front teeth were flattened but Denisovans lacked a high mandibular body and the mandibular symphysis at the midline of the jaw was more receding 12 18 The parietal is reminiscent of that of H erectus 39 A facial reconstruction has been generated by comparing methylation at individual genetic loci associated with facial structure 40 This analysis suggested that Denisovans much like Neanderthals had a long broad and projecting face large nose sloping forehead protruding jaw elongated and flattened skull and wide chest and hips The Denisovan tooth row was longer than that of Neanderthals and anatomically modern humans 41 Middle to Late Pleistocene East Asian archaic human skullcaps typically share features with Neanderthals The skullcaps from Xuchang feature prominent brow ridges like Neanderthals though the nuchal and angular tori near the base of the skull are either reduced or absent and the back of the skull is rounded off like in early modern humans Xuchang 1 had a large brain volume of approximately 1800 cc on the high end for Neanderthals and early modern humans and well beyond the present day human average 42 The Denisovan genome from Denisova Cave has variants of genes which in modern humans are associated with dark skin brown hair and brown eyes 43 The Denisovan genome also contains a variant region around the EPAS1 gene that in Tibetans assists with adaptation to low oxygen levels at high elevation 44 12 and in a region containing the WARS2 and TBX15 loci which affect body fat distribution in the Inuit 45 In Papuans introgressed Neanderthal alleles are highest in frequency in genes expressed in the brain whereas Denisovan alleles have highest frequency in genes expressed in bones and other tissue 46 Culture editDenisova Cave edit nbsp nbsp Some ornaments above and animal bones and stone tools below found in Denisova Cave Note ornaments may have been crafted by modern humans Early Middle Paleolithic stone tools from Denisova Cave were characterized by discoidal disk like cores and Kombewa cores but Levallois cores and flakes were also present There were scrapers denticulate tools and notched tools deposited about 287 41 thousand years ago in the Main Chamber of the cave and about 269 97 thousand years ago in the South Chamber up to 170 19 thousand and 187 14 thousand years ago in the Main and East Chambers respectively 7 Middle Paleolithic assemblages were dominated by flat discoidal and Levallois cores and there were some isolated sub prismatic cores There were predominantly side scrapers a scraper with only the sides used to scrape but also notched denticulate tools end scrapers a scraper with only the ends used to scrape burins chisel like tools and truncated flakes These dated to 156 15 thousand years ago in the Main Chamber 58 6 thousand years ago in the East Chamber and 136 26 47 8 thousand years ago in the South Chamber 7 Early Upper Paleolithic artefacts date to 44 5 thousand years ago in the Main Chamber 63 6 thousand years ago in the East Chamber and 47 8 thousand years ago in the South Chamber though some layers of the East Chamber seem to have been disturbed There was blade production and Levallois production but scrapers were again predominant A well developed Upper Paleolithic stone bladelet technology distinct from the previous scrapers began accumulating in the Main Chamber around 36 4 thousand years ago 7 In the Upper Paleolithic layers there were also several bone tools and ornaments a marble ring an ivory ring an ivory pendant a red deer tooth pendant an elk tooth pendant a chloritolite bracelet and a bone needle However Denisovans are only confirmed to have inhabited the cave until 55 ka the dating of Upper Paleolithic artefacts overlaps with modern human migration into Siberia though there are no occurrences in the Altai region and the DNA of the only specimen in the cave dating to the time interval Denisova 14 is too degraded to confirm species identity so the attribution of these artefacts is unclear 47 7 Tibet edit In 1998 five child hand and footprint impressions were discovered in a travertine unit near the Quesang hot springs in Tibet which in 2021 were dated to 226 to 169 thousand years ago using uranium decay dating This is the oldest evidence of human occupation of the Tibetan Plateau and given the Xiahe mandible is the oldest human fossil from the region albeit younger than the Quesang impressions these may have been made by Denisovan children The impressions were printed onto a small panel of space and there is little overlap between all the prints so they seem to have been taking care to make new imprints in unused space If considered art they are the oldest known examples of rock art Similar hand stencils and impressions do not appear again in the archeological record until roughly 40 000 years ago 48 The footprints comprise four right impressions and one left superimposed on one of the rights They were probably left by two individuals The tracks of the individual who superimposed their left onto their right may have scrunched up their toes and wiggled them in the mud or dug their finger into the toe prints The footprints average 192 3 mm 7 57 in long which roughly equates to a 7 or 8 year old child by modern human growth rates There are two sets of handprints from a left and right hand which may have been created by an older child unless one of the former two individuals had long fingers The handprints average 161 1 mm 6 34 in which roughly equates with a 12 year old modern human child and the middle finger length agrees with a 17 year old modern human One of the handprints shows an impression of the forearm and the individual was wiggling their thumb through the mud 48 Interbreeding editSee also Interbreeding between archaic and modern humans Analyses of the modern human genomes indicate past interbreeding with at least two groups of archaic humans Neanderthals 49 and Denisovans 20 50 and that such interbreeding events occurred on multiple occasions Comparisons of the Denisovan Neanderthal and modern human genomes have revealed evidence of a complex web of interbreeding among these lineages 49 Archaic humans edit As much as 17 of the Denisovan genome from Denisova Cave represents DNA from the local Neanderthal population 49 Denisova 11 was an F1 first generation Denisovan Neanderthal hybrid the fact that such an individual was found may indicate interbreeding was a common occurrence here 51 The Denisovan genome shares more derived alleles with the Altai Neanderthal genome from Siberia than with the Vindija Cave Neanderthal genome from Croatia or the Mezmaiskaya cave Neanderthal genome from the Caucasus suggesting that the gene flow came from a population that was more closely related to the local Altai Neanderthals 52 However Denny s Denisovan father had the typical Altai Neanderthal introgression while her Neanderthal mother represented a population more closely related to Vindija Neanderthals 53 About 4 of the Denisovan genome derives from an unidentified archaic hominin 49 perhaps the source of the anomalous ancient mtDNA indicating this species diverged from Neanderthals and humans over a million years ago The only identified Homo species of Late Pleistocene Asia are H erectus and H heidelbergensis 52 54 though in 2021 specimens allocated to the latter species were reclassified as H longi and H daliensis 55 Before splitting from Neanderthals their ancestors Neandersovans migrating into Europe apparently interbred with an unidentified superarchaic human species who were already present there these superarchaics were the descendants of a very early migration out of Africa around 1 9 mya 56 Modern humans edit A 2011 study found that Denisovan DNA is prevalent in Papuans Aboriginal Australians Near Oceanians Polynesians Fijians Eastern Indonesians and Aeta from the Philippines but not in East Asians western Indonesians Jahai people from Malaysia or Onge from the Andaman Islands This may suggest that Denisovan introgression occurred within the Pacific region rather than on the Asian mainland and that ancestors of the latter groups were not present in Southeast Asia at the time 35 57 In the Melanesian genome about 4 6 20 or 1 9 3 4 derives from Denisovan introgression 58 Prior to 2021 New Guineans and Australian Aborigines were reported to have the most introgressed DNA 17 but Australians have less than New Guineans 59 A 2021 study discovered 30 to 40 more Denisovan ancestry in Aeta people in the Philippines than in Papuans estimated as about 5 of the genome The Aeta Magbukon in Luzon have the highest known proportion of Denisovan ancestry of any population in the world 38 In Papuans less Denisovan ancestry is seen in the X chromosome than autosomes and some autosomes such as chromosome 11 also have less Denisovan ancestry which could indicate hybrid incompatibility The former observation could also be explained by less female Denisovan introgression into modern humans or more female modern human immigrants who diluted Denisovan X chromosome ancestry 43 In contrast 0 2 derives from Denisovan ancestry in mainland Asians and Native Americans 60 South Asians were found to have levels of Denisovan admixture similar to that seen in East Asians 61 The discovery of the 40 000 year old Chinese modern human Tianyuan Man lacking Denisovan DNA significantly different from the levels in modern day East Asians discounts the hypothesis that immigrating modern humans simply diluted Denisovan ancestry whereas Melanesians lived in reproductive isolation 62 17 A 2018 study of Han Chinese Japanese and Dai genomes showed that modern East Asians have DNA from two different Denisovan populations one similar to the Denisovan DNA found in Papuan genomes and a second that is closer to the Denisovan genome from Denisova Cave This could indicate two separate introgression events involving two different Denisovan populations In South Asian genomes DNA only came from the same single Denisovan introgression seen in Papuans 61 A 2019 study found a third wave of Denisovans which introgressed into East Asians Introgression also may not have immediately occurred when modern humans immigrated into the region 37 The timing of introgression into Oceanian populations likely occurred after Eurasians and Oceanians split roughly 58 000 years ago and before Papuan and Aboriginal Australians split from each other roughly 37 000 years ago Given the present day distribution of Denisovan DNA this may have taken place in Wallacea though the discovery of a 7 200 year old Toalean girl closely related to Papuans and Aboriginal Australians from Sulawesi carrying Denisovan DNA makes Sundaland another potential candidate Other early Sunda hunter gatherers so far sequenced carry very little Denisovan DNA which either means the introgression event did not take place in Sundaland or Denisovan ancestry was diluted with gene flow from the mainland Asian Hoabinhian culture and subsequent Neolithic cultures 63 In other regions of the world archaic introgression into humans stems from a group of Neanderthals related to those which inhabited Vindija Cave Croatia as opposed to archaics related to Siberian Neanderthals and Denisovans However about 3 3 of the archaic DNA in the modern Icelandic genome descends from the Denisovans and such a high percentage could indicate a western Eurasian population of Denisovans which introgressed into either Vindija related Neanderthals or immigrating modern humans 36 Denisovan genes may have helped early modern humans migrating out of Africa to acclimatize citation needed Although not present in the sequenced Denisovan genome the distribution pattern and divergence of HLA B 73 from other HLA alleles involved in the immune system s natural killer cell receptors has led to the suggestion that it introgressed from Denisovans into modern humans in West Asia In a 2011 study half of the HLA alleles of modern Eurasians were shown to represent archaic HLA haplotypes and were inferred to be of Denisovan or Neanderthal origin 64 A haplotype of EPAS1 in modern Tibetans which allows them to live at high elevations in a low oxygen environment likely came from Denisovans 44 12 Genes related to phospholipid transporters which are involved in fat metabolism and to trace amine associated receptors involved in smelling are more active in people with more Denisovan ancestry 65 Denisovan genes may have conferred a degree of immunity against the G614 mutation of SARS CoV 2 66 Denisovan introgressions may have influenced the immune system of present day Papuans and potentially favoured variants to immune related phenotypes and adaptation to the local environment 67 In December 2023 scientists reported that genes inherited by modern humans from Neanderthals and Denisovans may biologically influence the daily routine of modern humans 68 See also edit nbsp Biology portalRed Deer Cave people Prehistoric humans from 12 500 BCE in southwest China Homo naledi South African archaic human species Nesher Ramla Homo Extinct population of archaic humans Timeline of human evolution Chronological outline of major events in the development of the human speciesReferences edit a b c d e Krause J Fu Q Good J M Viola B et al 2010 The complete mitochondrial DNA genome of an unknown hominin from southern Siberia Nature 464 7290 894 897 Bibcode 2010Natur 464 894K doi 10 1038 nature08976 ISSN 1476 4687 PMC 10152974 PMID 20336068 S2CID 4415601 Douglas M M Douglas J M 2016 Exploring Human Biology in the Laboratory Morton Publishing Company p 324 ISBN 9781617313905 Zubova A Chikisheva T Shunkov M V 2017 The Morphology of Permanent Molars from the Paleolithic Layers of Denisova Cave 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Discovery as Science in Action Thesis LiU E press ISBN 9789179291716 Retrieved 18 March 2022 External links edit nbsp Media related to Denisova at Wikimedia Commons The Denisova Consortium s raw sequence data and alignments Human Timeline Interactive Smithsonian National Museum of Natural History August 2016 Picture of Denisovan molar Retrieved from https en wikipedia org w index php title Denisovan amp oldid 1195320794, wikipedia, wiki, book, books, library,

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