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HUMAN EVOLUTION: GENUS AUSTRALOPITHECUS & PARANTHROPUS

HUMAN EVOLUTION: GENUS AUSTRALOPITHECUS & PARANTHROPUS. What is a Hominid?. Modern humans & our direct and indirect ancestors (after our lineage split from the chimpanzee)

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HUMAN EVOLUTION: GENUS AUSTRALOPITHECUS & PARANTHROPUS

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  1. HUMAN EVOLUTION: GENUS AUSTRALOPITHECUS & PARANTHROPUS

  2. What is a Hominid? • Modern humans & our direct and indirect ancestors (after our lineage split from the chimpanzee) • In the last decade, the time range of genus Australopithecus has beenpushed back to 4.2 mya & its distribution expanded to include regions outside E. and S. Africa. • New finds from 4.5-7 mya are thought to be hominids that predate Australopithecines, although their status is debated

  3. Map of Hominid Evolution

  4. Hominid Sites • Earliest fossil hominid sites are in Africa • They now span the latest Miocene to the early Pleistocene from about 6-7 mya to about 1.6 mya • The major groups of sites are: • Ethiopia = Middle Awash valley & Hadar (Australopithecus afarensis) • Kenya = Lake Turkana • Tanzania = Olduvai Gorge • South Africa = various sites in limestone caverns centered around Sterkfontein

  5. What Makes A Hominid? - Bipedalism • Primary feature distinguishing hominids from other hominoids is walking erect on two legs – erect bipedalism • Adaptations for bipedalism in the the partial skeleton of “Lucy,” an australopithecine ( 3.2 mya) clearly seen in the hip, spine and leg bones

  6. Why did bipedalism become the primary adaptation of hominids? 1. Carrying behavior 2. Reduction of overall heat stress - facilitates heat loss through convection by exposing body to air currents, only humans have sweat glands that produce moisture to cool body 3. Most energy efficient way to travel long distances 4. Allows for better vision in open environments & defensive action against predators by freeing hands to throw objects

  7. Evidence for Early Bipedalism • The record of bipedalism is most graphically preserved in the fossilized footprints at Laetoli, Tanzania, 3.6 mya • Tracks of 2 individuals were uncovered in volcanic ash by Mary Leakey (1978-79) • Footprints were left by 2 australopithecines in damp volcanic ash of Laetoli • Notice how close the tracks are!

  8. Laetoli Footprints • Laetoli footprints clearly show that the creatures who made them were fully bipedal • Big toe hardly diverges from the rest of the foot, unlike in apes • Gait = “heel-strike” followed by “toe-off” – the way modern humans walk

  9. Laetoli Reconstruction • 2 early hominids walk bipedally across an open ash field produced by an erupting volcano. • Rain wet the volcanic ash & footprints filled up with more ash, and were thus preserved. • Footprints reveal that our ancestors walked upright with a gait very similar to our own.

  10. Time-Line of Hominid Evolution:5 Adaptive Radiations • First Adaptive Radiation: 6-7 mya in the late Miocene, potential last common ancestors • Second Adaptive Radiation: 4-5 mya in early Pliocene, first true hominids • Third Adaptive Radiation: 3-4 mya in middle Pliocene, more hominids • Fourth Adaptive Radiation: 2-3 mya in late Pliocene, more & “robust” hominids • Fifth Adaptive Radiation: 2-1.8 mya in late Pliocene & first ice age, genus Homo

  11. First Adaptive Radiation • 6-7 mya in the late Miocene, potential last common ancestors 1. Sahelanthropus tchadensis 6-7 mya in Chad (North Central Africa) 2. Orrorin tungenensis 6 mya in Kenya (East Africa) Note: We know little about the lifeways of these species. However, we do know that they were forest adapted.

  12. 1. Sahelanthropus tchadensis • Discovered in Chad (6-7 mya) • Most complete cranium from this time period • Mosaic of ape & human-like features, but at the “ape grade” of evolution: • Cranial capacity (320-380 cc) • U-shaped upper jaw • Very wide distance between the orbits • Large, thick continuous brow ridge • Human-like flat face • Human-like dentition

  13. 2. Orrorin tungenensis • Fossils from Tugen Hills in Kenya have been dated to about 6 mya • Earliest Evidence for • Walking on Two Legs? • How far back in time does the record of bipedalism extend?

  14. Orrorin tungenensis (cont.) • Fossils Include: upper portion of a femur, lower portion of the humerus, some lower jaw fragments, & teeth • Arm bone: virtually identical to that of a chimpanzee • Femur: more human-like, most important for showing adaptations for walking on 2 legs • Was Orrorin a direct human ancestor, or a common ancestor of chimps and humans?

  15. Second Adaptive Radiation • 4-5 mya in early Pliocene, first true hominids 1. Ardipithecus ramidus 4.5-5.5 mya in Ethiopia (East Africa) 2.Australopithecus anamensis 4.2-3.9 mya in Kenya (East Africa) Note: We know little about the lifeways of these species. However, we do know that they were forest adapted and fully bipedal.

  16. 1. Ardipithecus ramidus Earliest True Hominid or Last Common Ancestor? LAST COMMON ANCESTOR OF CHIMPS & HUMANS MOST LIKELY HAD A MIX OF FEATURES: SOME RETAINED IN CHIMPS, OTHERS RETAINED IN HUMANS!

  17. Ardipithecus ramidus (cont.) • Between 4.5 and 5.5 mya from the Middle Awash valley site in Ethiopia • Fossil Remains very fragmentary: limb bones, toe bones, jaws & teeth • Straight toe bones suggest it may have been bipedal • A mosaic of features seen in later hominids & modern chimpanzees

  18. 2. Australopithecus anamensis • Lake Turkana Region of Kenya • 4.2-3.9 mya • Probably walked upright • Teeth enamel thicker than Ardipithecus ramidus, so diet included hard foods

  19. Australopithecus anamensis (cont.) • Fossil Remains very fragmentary • Those shown here include: • Jawbone • part of the front of the face • parts of an arm bone (radius) • fragments of a lower leg bone (tibia)

  20. Third Adaptive Radiation • 3-4 mya in middle Pliocene, many hominids 1. Australopithecus afarensis (“Lucy”) 3-4 mya in East Africa 2.Australopithecus africanus 2.5-4 mya in South Africa 3. Kenyanthropus platyops 3.5-3.2 mya in Kenya Note: We know little about the lifeways of these species. However, we do know that they lived in open woodlands & along wooded streams in the savannas, ate fruits and soft foods, maybe had a tool-culture like modern chimps

  21. 1. Australopithecus afarensis • 3-4 mya in East Africa • Pelvis & leg bones resemble modern humans • Sexual dimorphism (males larger with sagittal crest) • Tree climbers (curved fingers & toes) Ape-like Features: • Small brain case (430 cc.) • Prognathic (jutting out) face • U-shaped palate (v. parabolic shape)

  22. Australopithecus afarensis

  23. A. afarensis Skeleton - Lucy

  24. 2. Australopithecus africanus • 4-2.5 mya in Transvaal region of South Africa • 1924: 1st Australopithicine to be described by Raymond Dart! • Globular cranium, slightly higher ratio of brain to body size than A. afarensis • Face less prognathic than A. afarensis • Proportions of arm to leg lengths may be more ape-like than A. afarensis

  25. Australopithecus africanus

  26. Australopithecus africanus Australopithecus africanus best known A. africanus cranium(front & lateral views) Most complete A. africanus skull Taung Child

  27. A. afarensis verses A. africanus A. afarensis Australopithecus afarensis Australopithecus africanus

  28. 3. Kenyanthropus platyops • 3.5-3.2 mya: found in 2001 west of Lake Turkana in Kenya • Ape-like features: small ear canal, small brain case • Human-like features: flat face, small molars • Importance: flat face appeared early in evolution, alongside the range of other facial forms. • Evidence that evolution is not linear or progressive

  29. Kenyanthropus platyops

  30. Fourth Adaptive Radiation • 1-3 mya in late Pliocene, more & “robust” hominids 1. Paranthropus boisei 2.2-1.2 mya in East Africa 2. Paranthropus robustus 2-1 mya in South Africa 3. Australopithecus garhi 2-3 mya in East Africa Note: We know little about the lifeways of these species. However, we do know that they lived in open dry woodlands & savannas. The robust species are famous for eating hard to chew food, like seeds, nuts, and roots. May have used tools to dig for roots in dry seasons.

  31. 1. Paranthropus boisei • 2.2-1.2 mya in East Africa: Ethiopia, Kenya, Tanzania • Largest teeth found in any hominid! • Referred to as “hyper-robust” due to massive molars and premolars • Skull: broad, short face with flaring cheek bones, relatively small brain, pronounced sagittal crest in males • Skull and dental features are adaptations for heavy chewing!

  32. Paranthropus boisei (KNM-ER 406)

  33. Paranthropus boisei (KNM-ER 406)

  34. Paranthropus boisei (KNM-ER 406)

  35. Paranthropus boisei (OH 5)

  36. 2. Paranthropus robustus • 2-1 mya in South Africa • Short, broad face with deep zygomatic arches (cheek bones). Larger individuals have sagittal crests. • Large molars covered with thick enamel • Wear patterns on teeth: herbivorous diet of hard resistant foods such as seeds, nuts, roots • Lived in grasslands near rivers and wetlands

  37. Paranthropus robustus

  38. 3. Australopithecus garhi • 2-3 mya in East Africa: spotty fossil record, cranial & dental remains found in 1999 in Bouri, Ethiopia • Bones of antelopes, horses, and other animals with cut marks made by stone tools: butchering animals & smashing bones for marrow. First meat eaters? • Molars too large to be early Homo • Ape-like long lower arm, human-like upper arm & leg • Mixed traits: classified as a new species, maybe ancestor of early Homo

  39. Australopithecus garhi

  40. Australopithecus garhi One surprise in the A. garhi skull was enormous back teeth, instead of smaller ones seen in later Homo species (Video Image/UC Berkeley)

  41. Australopithecus garhi • EARLIEST BUTCHERS: • Signs that hominids scraped & smashed animal bones, like this antelope tibia, 2.5 mya • Earliest documented percussion marks made by hominids, presumably extracting fatty marrow from these bones

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