Homo erectus

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Homo erectus
Temporal range: 2–0.1  Ma
Java Man holotype.jpg
Java Man, the holotype of H. erectus [a]
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Primates
Suborder: Haplorhini
Infraorder: Simiiformes
Family: Hominidae
Subfamily: Homininae
Tribe: Hominini
Genus: Homo
Species:
H. erectus
Binomial name
Homo erectus
(Dubois, 1893)

Homo erectus ( /ˌhməˈrɛktəs/ lit.' upright man') is an extinct species of archaic human from the Pleistocene, spanning nearly 2 million years. It is the first human species to evolve a humanlike body plan and gait, to leave Africa and colonize Asia and Europe, and to wield fire. H. erectus is the ancestor of later Homo species, including H. heidelbergensis , the last common ancestor of modern humans, Neanderthals, and Denisovans. As such a widely distributed species both geographically and temporally, H. erectus anatomy varies considerably. Subspecies are sometimes recognized: H. e. erectus , H. e. pekinensis , H. e. soloensis , H. e. ergaster , H. e. georgicus , and H. e. tautavelensis .

Contents

The species was first described by Eugène Dubois in 1893 as " Pithecanthropus erectus" using a skullcap, molar, and femur from Java, Indonesia. Further discoveries around East Asia were used to contend that humanity evolved out of Asia. Based on historical race concepts, it was argued that local H. erectus populations directly evolved into local modern human populations (polycentricism) rather than everyone sharing an anatomically modern ancestor (monogenism). As the fossil record improved over the mid-to-late 20th century, "Out of Africa" theory and monogenism became the consensus.

The skull usually has a pronounced brow ridge, a protruding jaw, and large teeth. The bones are extraordinarily thickened. East Asian H. erectus normally have much more robust skeletons and bigger brain volumes — averaging 1,000 cc (61 cu in), within the range of variation for modern humans, but that of H. e. georgicus was as low as 546 cc (33.3 cu in). H. erectus probably had a faster apelike growth trajectory, lacking the extended childhood required for language acquisition. Reconstructed adult body dimensions range from 148–167 cm (4 ft 10 in – 5 ft 6 in) in height and about 50 kg (110 lb) in weight.

H. erectus invented the Acheulean industry, a major innovation of large, heavy-duty stone tools, which may have been used in butchery, vegetable processing, and woodworking maybe to make digging sticks and spears. H. erectus was a major predator of large herbivores on the expanding savannas of the Quaternary glaciation. H. erectus is usually characterized as the first hunter-gatherer, and practiced sexual division of labor. Evidence of fire and cave habitation by H. erectus is sparse, and similarly, populations appear to have preferred warmer climates and usually ate meat raw. The last occurrence of H. erectus is 117,000 to 108,000 years ago (H. e. soloensis), when the last savannas in the region gave way to jungle.

Taxonomy

Research history

In 1868, Ernst Haeckel suggested early humans dispersed from the now-disproven hypothetical continent "Lemuria" (above). Hypothetical sketch of the monophylitic origin and of the diffusion of the 12 varieties of men from Lemuria over the earth LCCN2014649358.jpg
In 1868, Ernst Haeckel suggested early humans dispersed from the now-disproven hypothetical continent "Lemuria" (above).

Despite what Charles Darwin had hypothesized in his 1871 Descent of Man , [b] many late-19th century evolutionary naturalists postulated that Asia (instead of Africa) was the birthplace of humankind as it is midway between all continents via land routes or short sea crossings, providing optimal dispersal routes throughout the world. Among the major proponents of "Out of Asia" theory was Ernst Haeckel, who argued that the first human species (which he proactively named "Homo primigenius") evolved on the now-disproven hypothetical continent "Lemuria" in what is now Southeast Asia from a species he termed " Pithecanthropus alalus " ("speechless ape-man"). "Lemuria" had supposedly sunk below the Indian Ocean, so no fossils could be found to prove this. [3]

Nevertheless, Haeckel's model inspired Dutch scientist Eugène Dubois to join the Royal Netherlands East Indies Army and search for his "missing link" in Java. [c] At the Trinil site, his team found a skullcap and molar in 1891, and a femur in 1892 (Java Man), which he named "Pithecanthropus erectus" in 1893. [7] He unfruitfully attempted to convince the European scientific community that he had found an upright-walking ape-man dating to the late Pliocene or early Pleistocene; they dismissed his findings as some kind of malformed non-human ape. [3]

Homo erectus Sangiran 17 IMG 5644 BMNH.jpg
Sinanthropus Skull XII.png
Franz Weidenreich and Ralph von Koenigswald argued Java Man was an ancient human using fossils like Sangiran (left) and Peking Man (right)

Dubois continued to argue that "P. erectus" was a gibbon-like ape which was the precursor to a more familiar human body plan, but in the 1930s, Jewish-German anatomist Franz Weidenreich noticed a striking similarity with ancient human remains recently being unearthed in China (Peking Man, "Sinanthropus pekinensis"). [8] [9] This characterization became better supported as German-Dutch palaeontologist Gustav Heinrich Ralph von Koenigswald discovered more Indonesian ancient human remains over the decade at Mojokerto, Sangiran, and Ngandong. [d] [11] [12] Weidenreich believed that they were the direct ancestors of the local modern human Homo sapiens subspecies in accord with historical race concepts — that is, Peking Man was the direct ancestor of specifically Chinese people, and Java Man of Aboriginal Australians (polycentricism). [13] [14] As the importance of racial distinction diminished with the development of modern evolutionary synthesis, many fossil human species and genera around Asia, Africa, and Europe (including "Pithecanthropus erectus" and "Sinanthropus pekinensis") were reclassified as subspecies of Homo erectus. [15] [16]

In the late 20th century, far older H. erectus fossils were discovered across Africa, the first being Kenyan archeologist Louis Leakey's Olduvai Hominin 9 in 1960. [e] [17] As the human fossil record expanded, the "Out of Africa" theory and monogenism became the consensus (that all modern humans share a fully anatomically modern common ancestor). H. erectus is now generally considered to be an African species which later dispersed across Eurasia. [18]

Subspecies

By the middle of the 20th century, human taxonomy was in a state of turmoil, with many different species and genera defined across Europe, Asia, and Africa, which overexaggerated how different these fossils actually are from each other. [19] In 1940, Weidenreich was the first to suggest reclassifying "Sinanthropus pekinensis" and "Pithecanthropus erectus" as subspecies of H. erectus. [13] In 1950, German-American evolutionary biologist Ernst Mayr had entered the field of anthropology, and, surveying a "bewildering diversity of names," decided to subsume human fossils into three species of Homo : "H. transvaalensis" (the australopithecines), H. erectus (including "Sinanthropus", "Pithecanthropus", and various other putative Asian, African, and European taxa), and H. sapiens (including anything younger than H. erectus, such as modern humans and Neanderthals), as had been broadly recommended by various priors. Mayr defined these species as a sequential lineage, with each species evolving into the next (chronospecies). [f] [14] Though later Mayr changed his opinion on the australopithecines (recognizing Australopithecus ), his more conservative view of archaic human diversity became widely adopted in the subsequent decades. [15]

In the 1970s, as population genetics became better understood, the anatomical variation of H. erectus across its wide geographic and temporal range (the basis for the subspecies distinctions) became better understood as clines — different populations which attained some anatomical regionality but were not reproductively isolated. [18] In general, subspecies names for H. erectus are now used for convenience to indicate time and region rather than specific anatomical trends. [20]

...to paleontologists in general, subspecies are epiphenomena which do not merit the attention paid to species... The pursuit of subspecies in the fossil record is at best fraught with difficulty, and is more probably futile.

Ian Tattersall, 1986 [21]
Ergaster Skull.png
Erectus Skull.png
Reconstructions of H. e. ergaster (KNM ER 3733) left and H. e. pekinensis right

If an author uses subspecies, the ones usually recognized can include: [22]

The ancient Georgia fossils have variably been classified as a population of H. e. ergaster (sometimes denoted by a quadrinomial H. e. ergaster georgicus) [25] its own subspecies as H. e. georgicus, or elevated to its own species as H. georgicus. [23] Some authors may also elevate H. ergaster, [26] H. soloensis, [27] and H. pekinensis. [28] Material relegated to H. e. tautavelensis is traditionally assigned to H. heidelbergensis . [24]

Evolution and dispersal

H. e. georgicus (above) represents one of the earliest dispersals out of Africa about 1.8 million years ago. Dmanisi fossils D 2282 + D 211 (Replika).JPG
H. e. georgicus (above) represents one of the earliest dispersals out of Africa about 1.8 million years ago.

H. erectus is generally considered to have its origins in Africa, evolving from a population of H. habilis (anagenesis). [30] [31] The oldest identified H. erectus specimen is a 2.04 million year old skull, DNH 143, from Drimolen, South Africa, coexisting with the australopithecine Paranthropus robustus . [32] H. erectus dispersed out of Africa soon after evolution, the earliest recorded instances being H. e. georgicus 1.85 to 1.78 million years ago in Georgia [29] and the Indonesian Mojokerto and Sangiran sites 1.8 to 1.6 million years ago. [33] [34] Populations may have pushed into northwestern Europe at around the same time. [35] Since the species was first defined in East Asia, those populations are sometimes distinguished as H. erectus sensu stricto ("in the strict sense"), and African and West Eurasian populations as H. erectus sensu lato ("in the broad sense"), but this may not reflect how these populations are actually related to each other. [g] [20]

Once established around the Old World, H. erectus evolved into the other later species in genus Homo, including: H. heidelbergensis, H. antecessor , [36] H. floresiensis , [37] and H. luzonensis . [38] H. heidelbergensis, in turn, is usually placed as the last common ancestor of modern humans (H. sapiens), Neanderthals (H. neanderthalensis), and Denisovans. [36] H. erectus is thus a non-natural, paraphyletic grouping of fossils and does not include all the descendants of a last common ancestor. [39] Despite being designated as different species, H. erectus may have been interbreeding with some of its descendant species, namely the common ancestor of Neanderthals and Denisovans ("Neandersovans"). [40]

Successive dispersals of .mw-parser-output .legend{page-break-inside:avoid;break-inside:avoid-column}.mw-parser-output .legend-color{display:inline-block;min-width:1.25em;height:1.25em;line-height:1.25;margin:1px 0;text-align:center;border:1px solid black;background-color:transparent;color:black}.mw-parser-output .legend-text{} Homo erectus (yellow), Homo neanderthalensis (ochre) and Homo sapiens (red, Out of Africa II) Spreading homo sapiens la.svg
Successive dispersals of  Homo erectus (yellow),   Homo neanderthalensis (ochre) and   Homo sapiens (red, Out of Africa II )

The dispersal of H. erectus is generally ascribed to the evolution of bipedalism, better technology, and a dietary switch to carnivory. [h] Populations spread out via open grassland and woodland savannas, which were expanding due to a global aridification trend at the onset of the Quaternary glaciation. [42] [i] Most H. erectus sensu lato specimens date to 1.8 to 1 million years ago in the Early Pleistocene before giving way to descendant species. [1] [j] H. erectus sensu stricto persisted much longer than sensu lato, with the youngest population (H. e. soloensis) dating to 117,000 to 108,000 years ago in Late Pleistocene Java. [1] This population appears to have died out when the savannah corridors closed in the Late Pleistocene, and tropical jungle took over. [45]

A 2021 phylogeny of some H. erectus fossils using tip dating: [39]

Homo  (2.85)

H. habilis

H. erectus (2.3)
(2.1)

Stw 53 (†1.9)

Dmanisi (†1.8)

Turkana (†1.7)

Olduvai Hominid 9 (†1.5)

Sangiran (†1.4)

(1.1)
(0.8)

Nanjing Man (†0.6)

Peking Man (†0.5)

(0.9)

Hexian (†0.5)

(0.6)

Sambungmacan (†0.2)

Ngandong (†0.1)

(1.3)

Biology

As such a widely distributed species both geographically and through time, the anatomy of H erectus can vary considerably. Among living primates, the degree of regionality achieved by H. erectus (phenotypic plasticity) is only demonstrated in modern humans. [46]

Franz Weidenreich's reconstruction of the H. e. soloensis skull Solo Man reconstruction.png
Franz Weidenreich's reconstruction of the H. e. soloensis skull

Dubois originally described the species using a skullcap, noting the traits of a low and thickened cranial vault and a continuous bar of bone forming the brow ridge (supraorbital torus), [l] as well as several other traits now considered more typical of H. erectus sensu stricto, such as a strong crest on the mastoid part of the temporal bone, a sagittal keel running across the midline, and a bar of bone running across the back of the skull (occipital torus). [48] The latter traits can be still be found nonetheless in a few H. erectus sensu lato specimens, namely the 1.47 million year old Olduvai Hominin 9. [49] Compared to H. erectus sensu lato, the skullcap of sensu stricto narrows considerably at the front, the face is bigger and presumably more prognathic (it juts out more, but the face is poorly documented), and the molars are larger particularly in Indonesian fossils. [50] H. erectus was the first human species with a fleshy nose, which is generally thought to have evolved in response to breathing dry air in order to retain moisture. [51] Compared to earlier Homo, H. erectus has smaller teeth, thinner enamel, and weaker mandibles (jawbone), likely due to a greater reliance on tool use and food processing. [52]

The brain size of H. erectus varies considerably, but is generally smaller in H. erectus sensu lato, as low as 546 cc (33.3 cu in) in Dmanisi skull 5. [53] Asian H. erectus overall are rather big-brained, averaging roughly 1,000 cc, [46] staying within the range of variation for modern humans. [54] The late-surviving H. e. soloensis has the biggest brain volume with one specimen measuring 1,251 cc (76.3 cu in). [49]

Body

Skeleton and reconstruction of Turkana Boy by Mauricio Anton Turkana boy by Mauricio Anton.jpg
Skeleton and reconstruction of Turkana Boy by Mauricio Antón

The rest of the body is primarily understood by three partial skeletons from the Kenyan Lake Turkana site, notably Turkana Boy. Other postcranial fossils attributed to H. erectus are not associated with a skull, making attribution unverifiable. Though the body plan of earlier Homo is poorly understood, H. erectus has typically been characterized as the first Homo species with a human body plan, distinct from non-human apes. [55] [46] [56] Fossil tracks near Ileret, Kenya, similarly suggest a human gait. This adaptation is implicated in the spread of H. erectus across the Old World. [57]

Body size and robusticity differs appreciably among populations. Height reconstructions range approximately 148–167 cm (4 ft 10 in – 5 ft 6 in), [m] with tropical populations typically reconstructed as scoring on the higher end like modern human populations. Adult weight is harder to approximate, but it may have been about 50 kg (110 lb). H. erectus is usually thought to be the first human species with little size-specific sexual dimorphism, but the variability of postcranial material makes this unclear. [46]

It is largely unclear when human ancestors lost most of their body hair. [n] Genetic analysis suggests that high activity in the melanocortin 1 receptor, which would produce dark skin, dates back to 1.2 million years ago. This could indicate the evolution of hairlessness around this time, as a lack of body hair would have left the skin exposed to harmful UV radiation. [60] Populations in higher latitudes potentially developed lighter skin to prevent vitamin D deficiency, [61] though a 500,000 to 300,000 year old Turkish H. erectus specimen presents the earliest case of tuberculous meningitis, which is typically exacerbated by vitamin D deficiency specifically in dark-skinned people living in higher latitudes. [62] Hairlessness is generally thought to have facilitated sweating, [63] but reducing parasite load and sexual selection have also been proposed. [64] [65]

Growth and development

The dimensions of a 1.8 million years old adult female H. e. ergaster pelvis from Gona, Ethiopia, suggests that she would have been capable of birthing children with a maximum prenatal brain size of 315 cc (19.2 cu in), about 30–50% of adult brain size, falling between chimpanzees (~40%) and modern humans (28%). [66] Similarly, a 1.5 million year old infant skull from Mojokerto had a brain volume of about 72–84% the size of an adult, which suggests a brain growth trajectory more similar to that of non-human apes. [67] This suggests that the childhood growth and development of H. erectus was intermediate between that of chimpanzees and modern humans, [66] and the faster development rate suggests that altriciality (an extended childhood) evolved at a later stage in human evolution. [67] The faster development rate might also indicate a shorter expected lifespan compared to later Homo. [68]

Bone thickness

Cross sections of Peking Man Skulls III (A) and XII (B), and Java Man Skull II (C) Homo erectus skull cross-section.png
Cross sections of Peking Man Skulls III (A) and XII (B), and Java Man Skull II (C)

The bones are extraordinarily thickened, particularly in Homo erectus sensu stricto, so much so that skull fragments have sometimes been confused for fossil turtle carapaces. [69] The medullary canal in the long bones (where the bone marrow is stored, in the limbs) is extremely narrowed (medullary stenosis). This degree of thickening is usually exhibited in semi-aquatic animals which use their heavy (pachyosteosclerotic) bones as ballasts to help them sink, induced by hypothyroidism. [70]

It is largely unclear what function this could have served. Before more complete skeletons were discovered, Weidenreich suggested H. erectus was a gigantic species.. [71] Other explanations include a far more violent and impact-prone lifestyle than other Homo, [72] or pathological nutrient deficiencies causing hyperparathyroidism (such as hypocalcemia). [73]

Culture

Subsistence

H. erectus overhunting may have led to the extinction of Megalochelys (above). Megalochelys AMNH.jpg
H. erectus overhunting may have led to the extinction of Megalochelys (above).

H. erectus was early-on portrayed as the earliest hunter-gatherer and a skilled predator of big game, relying on endurance running. The gradual shift to "top predator" may have led to its dispersal throughout Afro-Eurasia. [42] Though scavenging may have instead played a bigger role at least in some populations, H. erectus fossils are often associated with the butchered remains of large herbivores, [75] especially elephants, rhinos, hippos, bovines, and boars. The complexities of prey behaviors and the nutritional value of meat have been connected to brain volume growth. [76]

H. erectus is usually assumed to have practiced sexual division of labor much like recent hunter-gatherer societies, with men hunting and women gathering. This ideation is supported by a fossil trackway from Ileret, Kenya, made by a probably all-male band of over 20 H. erectus individuals, possibly a hunting party or (similar to chimpanzees) a border patrol group. [77]

Since common modern human tapeworms began to diverge from those of other predators roughly 1.7 million years ago (specifically the pork tapeworm, beef tapeworm, and Asian tapeworm), not only was H. erectus consuming meat regularly enough for speciation to occur in these parasites, but meat was probably consumed raw more often than not. [78] Some populations were collecting aquatic resources, include fish, shellfish, and turtles such as at Lake Turkana [79] and Trinil. [80] Underground storage organs (roots, tubers, etc.) were likely also major dietary components, and traces of the edible plant Celtis have been documented at several H. erectus sites. [81]

Possibly due to overhunting of the biggest game available, the dispersal of H. erectus and descendant species may be implicated in the extinctions of large herbivores and the gradual reduction of average herbivore size over the Pleistocene. [82] H. erectus overhunting has been blamed by some authors for the decline of proboscidean species [o] as well as competing carnivores, [76] [84] [83] but their decline may be better attributed to the spread of grasslands. [83] [85] The giant tortoise genus Megalochelys may have been driven to extinction by H. erectus in Island Southeast Asia due to insular species of the genus tending to go extinct shortly after the arrival of Homo erectus on the islands they inhabited. [74]

Technology

Stone tools

A handaxe from the Saint-Acheul site at the Musee d'Archeologie nationale, France Piece bifaciale Saint-Acheul La Garenne Archeologie Nationale 01042018.jpg
A handaxe from the Saint-Acheul site at the Musée d'Archéologie nationale, France

H. erectus manufactured Lower Paleolithic technologies, and is credited with the invention of the Acheulean stone tool industry at latest 1.75 million years ago. This was a major technological breakthrough featuring large, symmetrical, heavy-duty tools; most iconicly the handaxe. Over hundreds of thousands of years, the Achuelean eventually replaced its predecessor — the Oldowan (a chopper and flake industry) — in Africa, and spread out across Western Eurasia. [86] This sudden innovation was typically explained as a response to environmental instability in order to process more types of food and broaden the diet, which allowed H. erectus to colonize Eurasia. Despite this characterization of the Acheulean, H. e. georgicus was able to leave Africa despite only manufacturing Oldowan-style tools, [42] [86] and the handaxe does not seem to have been manufactured commonly in East Asia. [87] This conspicuous pattern was first noted by American archaeologist Hallam L. Movius in 1948, who drew the "Movius Line", dividing the East into a "chopping-tool culture" and the West into a "hand axe culture". [p] [88]

H. erectus seems to have been using stone tools in butchery, vegetable processing, and woodworking (maybe manufacturing digging sticks and spears). [81] [89] In Africa, Oldowan sites are typically found alongside major fossil assemblages, but Acheulean sites normally feature more stone tools than fossils, so H. erectus could have been using choppers and handaxes for different activities. [89]

Materials for stone tools were normally sourced locally, and it seems blanks were usually chosen based on size rather than material quality. [86] H. erectus also produced tools from shells at Sangiran [90] and Trinil. [91]

Fire

H. erectus is credited as the first human species to wield fire. The earliest claimed fire site is Wonderwerk Cave, South Africa, at 1.7 million years old. [92] While its dispersal far out of Africa has often been attributed to fire and cave dwelling, fire does not become common in the archaeological record until 400,000–300,000 years ago, [93] and cave-dwelling about 600,000 years ago. [94] Therefore, H. erectus may have only been scavenging fire opportunistically. Similarly, H. erectus sites usually stay within warmer tropical or subtropical latitudes, [42] and the dating of northerly populations (namely Peking Man) could suggest that they were retreating to warmer refugia during glacial periods, but the precise age of the Peking Man fossils is poorly resolved. [q] [48] [96]

Healthcare

The single-toothed H. e. georgicus specimen (above) is the earliest probable example of group care. Dmanisi fossils D 3444 + D 3900 (Replika).jpg
The single-toothed H. e. georgicus specimen (above) is the earliest probable example of group care.

Like other primates, H. erectus probably used medicinal plants [81] and infirmed sick group members. The earliest probable example of this is a 1.77 million year old H. e. georgicus specimen who had lost all but one tooth due to age or gum disease (the earliest example of severe chewing impairment) yet still survived for several years afterwards. [97]

Seafaring

H. erectus made long sea crossings to arrive on the islands of Flores, Luzon, [98] and some Mediterranean islands. Some authors have asserted that H. erectus intentionally made these crossings by inventing watercrafts and seafaring so early in time, speaking to advanced cognition and language skills. These populations could have also been founded by natural rafting events instead. [99]

Art and rituals

In East Asia, H. erectus is usually represented only by skullcaps, which used to be interpreted as widespread cannibalism and ritual headhunting. This had been reinforced by the historic practice of headhunting and cannibalism in some recent Indonesian, Australian, and Polynesian cultures, which were formerly believed to have directly descended from these H. erectus populations. The lack of the rest of the skeleton is now normally explained by natural phenomena. [100]

Engraved Pseudodon shell DUB1006-fL from Trinil, Java Homo Erectus shell with geometric incisions circa 500,000 BP, Naturalis Biodiversity Center, Netherlands (with detail).jpg
Engraved Pseudodon shell DUB1006-fL from Trinil, Java

Art-making could be evidence of symbolic thinking. An engraved Pseudodon shell DUB1006-fL from Trinil, Java, with geometric markings could possibly be the earliest example of art-making, dating to 546,000 to 436,000 years ago. [91] [101] [102] H. erectus was also the earliest human to collect red-colored pigments, namely ochre. Ochre lumps at Olduvai Gorge, Tanzania, associated with the 1.4 million year old Olduvai Hominid 9 may have been purposefully shaped and trimmed by a hammerstone. Red ochre is normally recognized as bearing symbolic value when associated with modern humans. [102]

Language

The hyoid bone supports the tongue and makes possible modulation of the vocal tract to control pitch and volume. A 400,000 year old H. erectus hyoid bone from Castel di Guido, Italy, is bar-shaped—more similar to that of other Homo than to that of non-human apes and Australopithecus—but is devoid of muscle impressions, has a shield-shaped body, and is implied to have had reduced greater horns, meaning H. erectus lacked a humanlike vocal apparatus and thus anatomical prerequisites for a modern human level of speech. [r] [105] Similarly, the spinal column of the 1.6 million year old Turkana boy would not have supported properly developed respiratory muscles required to produce speech; [106] [107] and a 1.5 million year old infant H. erectus skull from Mojokerto, Java, shows that this population did not have an extended childhood, which is a prerequisite for language acquisition. [67] On the other hand, despite the cochlear (ear) anatomy of Sangiran 2 and 4 retaining several traits reminiscent of australopithecines, the hearing range may have included the higher frequencies used to discern speech. [108]

Given expanding brain size and technological innovation, H. erectus may have been using some basic proto-language in combination with gesturing, and built the basic framework which fully-fledged languages would eventually be formed around. [109]

See also

Notes

  1. The Java Man femur presents a noticeable osteocyte, likely Paget's disease of bone and osteopetrosis (thickening of the bone), probably stemming from skeletal fluorosis caused by ingestion of food contaminated by fluoride-filled volcanic ash (as the specimen was found in ash-filled strata). Livestock that graze on volcanic ash-ridden fields typically die of acute toxicity within a few days or weeks. [2]
  2. Darwin's work mainly aimed to demonstrate that his theory of common descent with modification by natural and sexual selection applied to humans, "The sole object of this work is to consider, firstly, whether man, like every other species, is descended from some pre-existing form; secondly, the manner of his development; and thirdly, the value of the differences between the so-called races of man." [5]
  3. Dubois was studying the anatomy and evolution of the larynx in vertebrates in Amsterdam with German anatomist Max Fürbringer, but fed up with both the research and Fürbringer, he decided to drop everything and board the SS Prinses Amalia to the Dutch East Indies on 29 October 1887. Dubois said his interest in human evolution began in secondary school (the State Hogere Burgerschool), where he heard of lectures given by Carl Vogt in 1868. [6]
  4. Dubois never accepted that the Java Man was a type of human, and continued to fight Weidenreich and von Koenigswald until his death in 1940. Sir Arthur Keith described Dubois in an obituary notice as, "an idealist, his ideas being so firmly held that his mind tended to bend facts rather than alter his ideas to fit them." [10]
  5. Leakey believed that the East Asian H. erectus was a distant offshoot of the modern human line, and he believed he would find the true ancestors of H. sapiens in East Africa. He was unsure what to do with Olduvai Hominin 9, but when he described H. habilis a few years later, he unpopularly circumvented H. erectus and placed H. habilis as the direct ancestor of H. sapiens. His hypothesis later became untenable as more and more African H. erectus material was described. [17]
  6. Mayr's main rationale may be summarized in his statement, "never more than one species of man existed on the earth at any one time," and the anatomical diversity which priors took as evidence of speciation was better explained by the unparalleled adaptability of humanity. For example, "If fossils of Congo pygmies and of Watusi were to be found in the same deposit by a paleontologist, a million years hence, he might well think that they belonged to two different species." He also believed that if different human species had indeed coexisted, then the inferior one would have been quickly exterminated. [14]
  7. There may have been two different H. erectus dispersals into East Asia: an early one that led to the Sangiran Java Man (specifically the older material), and a later one which led to the northern Chinese Peking Man. That is, the older Sangiran material may be more closely related to H. erectus sensu lato than to Peking Man. The younger Sangiran material, though, possibly descended from or interbred with Chinese H. erectus. [31]
  8. The sudden increase of butchery in the East African archeological record following the evolution of H. erectus may be due to sampling bias. In other words, earlier species such as H. habilis could have been consuming the same amount of meat. [41]
  9. Homo erectus is usually thought to have occupied the Saharo-Arabian region during humid periods, but populations may have persisted into desert periods. [43]
  10. The classification of Middle Pleistocene Homo has been a controversial topic, termed "the muddle in the middle". [24] [44]
  11. H. heidelbergensis is also a paraphyletic assemblage of fossils, which in this study includes Tautavel Man. [39]
  12. H. erectus fossils typically share these traits, but the Kenyan Koobi Fora skulls notably have thinner skulls and weaker supraorbital tori. [47]
  13. The Turkana Boy specimen was originally estimated in 1993 to have been roughly 165 cm (5 ft) when it died at about 12 years of age, and predicted to reach 177–193 cm (5 ft 10 in – 6 ft 4 in) had it survived past its pubertal growth spurt and into adulthood assuming a humanlike growth curve. Further fossil discoveries instead better supports an apelike growth curve, making for an adult height of 163 cm (5 ft 4 in) at the age of 16. [58]
  14. Australopithecines seem to have lived at much higher, much colder elevations — typically 1,000–1,600 m (3,300–5,200 ft) where the nighttime temperature can drop to 10 or 5 °C (50 or 41 °F) — so they may have required hair to stay warm, unlike early Homo which inhabited lower, hotter elevations. [59]
  15. Proboscidean diversity peaked near the beginning of the Pliocene over 5 million years ago, and decreased with the gradual disappearance of forestlands. By 2 million years ago, there were 5 proboscidean species in Africa: Deinotherium bozasi , Palaeoloxodon recki , Mammuthus meridionalis , Loxodonta atlantica , and Loxodonta adaurora . [83]
  16. Movius believed that East Asian H. erectus were unevolved, "throughout the early portion of the Old Stone Age the tools consist for the most part of relatively monotonous and unimaginative assemblages of chopper, chopping-tools, and hand-adze...as early as Lower Palaeolithic times Southern and Eastern Asia as a whole was a region of cultural retardation...very primitive forms of Early Man apparently persisted there long after types at a comparable stage of physical evolution had become extinct elsewhere." [88]
  17. There have been claims of manmade hearths and "clear-cut evidence for intentional fire use" at the Zhoukoudian Peking Man Site, [95] ostensibly as far back as 770,000 years ago in the supposed cave home of Peking Man. [96] At the French Caune de L'Arago, Tautavel Man does not seem to have been using fire at all, even though occupation sequences span two cold periods. [24]
  18. The individuals at the contemporaneous Sima de los Huesos site in Spain ( H. heidelbergensis ) had a modern humanlike hyoid bone, as well as middle ear bones capable of finely distinguishing frequencies within the range of normal human speech. [103] [104]

Related Research Articles

<i>Homo habilis</i> Archaic human species from 2.8 to 1.65 mya

Homo habilis is an extinct species of archaic human from the Early Pleistocene of East and South Africa about 2.4 million years ago to 1.4 million years ago (mya). Upon species description in 1964, H. habilis was highly contested, with many researchers recommending it be synonymised with Australopithecus africanus, the only other early hominin known at the time, but H. habilis received more recognition as time went on and more relevant discoveries were made. By the 1980s, H. habilis was proposed to have been a human ancestor, directly evolving into Homo erectus, which directly led to modern humans. This viewpoint is now debated. Several specimens with insecure species identification were assigned to H. habilis, leading to arguments for splitting, namely into "H. rudolfensis" and "H. gautengensis" of which only the former has received wide support.

<span class="mw-page-title-main">Peking Man</span> Subspecies of the genus Homo (fossil)

Peking Man is a subspecies of H. erectus which inhabited what is now northern China during the Middle Pleistocene. Its fossils have been found in a cave some 50 km (31 mi) southwest of Beijing, known as the Zhoukoudian Peking Man Site. The first fossil, a tooth, was discovered in 1921, and Zhoukoudian has since become the most productive H. erectus site in the world. Peking Man was instrumental in the foundation of Chinese anthropology, and fostered an important dialogue between Western and Eastern science. Peking Man became the centre of anthropological discussion, and was classified as a direct human ancestor, propping up the Out of Asia theory that humans evolved in Asia.

<i>Homo ergaster</i> Extinct species or subspecies of archaic human

Homo ergaster is an extinct species or subspecies of archaic humans who lived in Africa in the Early Pleistocene. Whether H. ergaster constitutes a species of its own or should be subsumed into H. erectus is an ongoing and unresolved dispute within palaeoanthropology. Proponents of synonymisation typically designate H. ergaster as "African Homo erectus" or "Homo erectus ergaster". The name Homo ergaster roughly translates to "working man", a reference to the more advanced tools used by the species in comparison to those of their ancestors. The fossil range of H. ergaster mainly covers the period of 1.7 to 1.4 million years ago, though a broader time range is possible. Though fossils are known from across East and Southern Africa, most H. ergaster fossils have been found along the shores of Lake Turkana in Kenya. There are later African fossils, some younger than 1 million years ago, that indicate long-term anatomical continuity, though it is unclear if they can be formally regarded as H. ergaster specimens. As a chronospecies, H. ergaster may have persisted to as late as 600,000 years ago, when new lineages of Homo arose in Africa.

<i>Meganthropus</i> Hominin fossil

Meganthropus is an extinct genus of non-hominin hominid ape, known from the Pleistocene of Indonesia. It is known from a series of large jaw and skull fragments found at the Sangiran site near Surakarta in Central Java, Indonesia, alongside several isolated teeth. The genus has a long and convoluted taxonomic history. The original fossils were ascribed to a new species, Meganthropus palaeojavanicus, and for a long time was considered invalid, with the genus name being used as an informal name for the fossils.

<i>Homo</i> Genus of hominins that includes humans and their closest extinct relatives

Homo is a genus of great ape that emerged from the genus Australopithecus and encompasses only a single extant species, Homo sapiens, along with a number of extinct species classified as either ancestral or closely related to modern humans; these include Homo erectus and Homo neanderthalensis. The oldest member of the genus is Homo habilis, with records of just over 2 million years ago. Homo, together with the genus Paranthropus, is probably most closely related to the species Australopithecus africanus within Australopithecus. The closest living relatives of Homo are of the genus Pan, with the ancestors of Pan and Homo estimated to have diverged around 5.7-11 million years ago during the Late Miocene.

<span class="mw-page-title-main">Java Man</span> Subspecies of Homo erectus (fossil) discovered on the island of Java in 1891

Java Man is an early human fossil discovered in 1891 and 1892 on the island of Java (Indonesia). Estimated to be between 700,000 and 1,490,000 years old, it was, at the time of its discovery, the oldest hominid fossil ever found, and it remains the type specimen for Homo erectus.

<i>Homo floresiensis</i> Extinct small human species found in Flores

Homo floresiensis(), also known as "Flores Man" or "Hobbit", is an extinct species of small archaic humans that inhabited the island of Flores, Indonesia, until the arrival of modern humans about 50,000 years ago.

<i>Paranthropus boisei</i> Extinct species of hominin of East Africa

Paranthropus boisei is a species of australopithecine from the Early Pleistocene of East Africa about 2.5 to 1.15 million years ago. The holotype specimen, OH 5, was discovered by palaeoanthropologist Mary Leakey in 1959 at Olduvai Gorge, Tanzania and described by her husband Louis a month later. It was originally placed into its own genus as "Zinjanthropus boisei", but is now relegated to Paranthropus along with other robust australopithecines. However, it is also argued that Paranthropus is an invalid grouping and synonymous with Australopithecus, so the species is also often classified as Australopithecus boisei.

Human taxonomy is the classification of the human species within zoological taxonomy. The systematic genus, Homo, is designed to include both anatomically modern humans and extinct varieties of archaic humans. Current humans are classified as subspecies to Homo, differentiated, according to some, from the direct ancestor, Homo sapiens idaltu.

<span class="mw-page-title-main">Lantian Man</span> Subspecies of the genus Homo (fossil)

Lantian Man, Homo erectus lantianensis) is a subspecies of Homo erectus known from an almost complete mandible from Chenchiawo (陈家窝) Village discovered in 1963, and a partial skull from Gongwangling (公王岭) Village discovered in 1964, situated in Lantian County on the Loess Plateau. The former dates to about 710–684 thousand years ago, and the latter 1.65–1.59 million years ago. This makes Lantian Man the second-oldest firmly dated H. erectus beyond Africa, and the oldest in East Asia. The fossils were first described by Woo Ju-Kan in 1964, who considered the subspecies an ancestor to Peking Man.

<span class="mw-page-title-main">Yuanmou Man</span> Subspecies of Homo erectus

Yuanmou Man is a subspecies of H. erectus which inhabited the Yuanmou Basin in Yunnan Province, southwestern China, roughly 1.7 million years ago. It is the first fossil evidence of humans in China, though they probably reached the region by at least 2 million years ago. Yuanmou Man is known only from two upper first incisors presumed to have belonged to a male, and a partial tibia presumed to have belonged to a female. The female may have stood about 123.6–130.4 cm in life. These remains are anatomically quite similar to those contemporary early Homo in Africa, namely H. habilis and H. (e?) ergaster.

<span class="mw-page-title-main">Wushan Man</span> Fossil of an extinct non-hominin ape of central China from 2 mya

Wushan Man is a set of fossilised remains of an extinct, undetermined non-hominin ape found in central China in 1985. The remains are dated to around 2 million years ago and were originally considered to represent a subspecies of Homo erectus.

The multiregional hypothesis, multiregional evolution (MRE), or polycentric hypothesis, is a scientific model that provides an alternative explanation to the more widely accepted "Out of Africa" model of monogenesis for the pattern of human evolution.

<i>Australopithecus sediba</i> Two-million-year-old hominin from the Cradle of Humankind

Australopithecus sediba is an extinct species of australopithecine recovered from Malapa Cave, Cradle of Humankind, South Africa. It is known from a partial juvenile skeleton, the holotype MH1, and a partial adult female skeleton, the paratype MH2. They date to about 1.98 million years ago in the Early Pleistocene, and coexisted with Paranthropus robustus and Homo ergaster / Homo erectus. Malapa Cave may have been a natural death trap, the base of a long vertical shaft which creatures could accidentally fall into. A. sediba was initially described as being a potential human ancestor, and perhaps the progenitor of Homo, but this is contested and it could also represent a late-surviving population or sister species of A. africanus which had earlier inhabited the area.

<span class="mw-page-title-main">Early expansions of hominins out of Africa</span> First hominin expansion into Eurasia (2.1–0.1 Ma)

Several expansions of populations of archaic humans out of Africa and throughout Eurasia took place in the course of the Lower Paleolithic, and into the beginning Middle Paleolithic, between about 2.1 million and 0.2 million years ago (Ma). These expansions are collectively known as Out of Africa I, in contrast to the expansion of Homo sapiens (anatomically modern humans) into Eurasia, which may have begun shortly after 0.2 million years ago.

<span class="mw-page-title-main">Mojokerto child</span> Hominin fossil

The Mojokerto child, also known as Mojokerto 1 and Perning 1, is the fossilized skullcap of a juvenile early human. It was discovered in February 1936 near Mojokerto by a member of an excavation team led by Ralph von Koenigswald. Von Koenigswald first called the specimen Pithecanthropus modjokertensis but soon renamed it Homo modjokertensis because Eugène Dubois – the discoverer of Java Man, which was then called Pithecanthropus erectus – disagreed that the new fossil was a Pithecanthropus. The skullcap is now identified as belonging to the species Homo erectus.

<i>Homo naledi</i> South African archaic human species

Homo naledi is an extinct species of archaic human discovered in 2013 in the Rising Star Cave system, Gauteng province, South Africa, dating to the Middle Pleistocene 335,000–236,000 years ago. The initial discovery comprises 1,550 specimens of bone, representing 737 different skeletal elements, and at least 15 different individuals. Despite this exceptionally high number of specimens, their classification with other Homo species remains unclear.

<span class="mw-page-title-main">Archaic humans in Southeast Asia</span>

The region of Southeast Asia is considered a possible place for the evidence of archaic human remains that could be found due to the pathway between Australia and mainland Southeast Asia, where the migration of multiple early humans has occurred out of Africa. One of many pieces of evidence is of the early human found in central Java of Indonesia in the late 19th century by Eugene Dubois, and later in 1937 at Sangiran site by G.H.R. van Koenigswald. These skull and fossil materials are Homo erectus, named Pithecanthropus erectus by Dubois and Meganthropus palaeojavanicus by van Koenigswald. They were dated to c. 1.88 and 1.66 Ma, as suggested by Swisher et al. by analysis of volcanic rocks.

<span class="mw-page-title-main">Dmanisi hominins</span> Hominid species or subspecies discovered in Dmanisi, Georgia

The Dmanisi hominins, Dmanisi people, or Dmanisi man were a population of Early Pleistocene hominins whose fossils have been recovered at Dmanisi, Georgia. The fossils and stone tools recovered at Dmanisi range in age from 1.85 to 1.77 million years old, making the Dmanisi hominins the earliest well-dated hominin fossils in Eurasia and the best preserved fossils of early Homo from a single site so early in time, though earlier fossils and artifacts have been found in Asia. Though their precise classification is controversial and disputed, the Dmanisi fossils are highly significant within research on early hominin migrations out of Africa. The Dmanisi hominins are known from over a hundred postcranial fossils and five famous well-preserved skulls, referred to as Dmanisi Skulls 1–5.

The Narmada Human, originally the Narmada Man, is a species of extinct human that lived in central India during the Middle and Late Pleistocene. From a skull cup discovered from the bank of the Narmada River in Madhya Pradesh in 1982, the discoverer, Arun Sonakia classified it was an archaic human and gave the name Narmada Man, with the scientific name H. erectus narmadensis. Analysis of additional fossils from the same location in 1997 indicated that the individual could be a female, hence, a revised name, Narmada Human, was introduced. It remains the oldest human species in India.

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