Phylogeny & Classification
Where Do We Fit?🌳 Humans Are Apes — Not Descended from Apes
A critical IEB distinction: humans did NOT evolve from modern chimpanzees. Humans and chimpanzees share a common ancestor that lived approximately 6–7 million years ago. Both lineages evolved separately from that shared ancestor. Humans belong to the Order Primates, Family Hominidae (the great apes), and our lineage — the hominins — is distinguished by bipedalism, reduced canine teeth, and progressive brain enlargement over millions of years.
| Taxonomic Level | Human Classification | Key Shared Feature |
|---|---|---|
| Kingdom | Animalia | Multicellular, heterotrophic, no cell wall |
| Phylum | Chordata | Notochord, dorsal hollow nerve cord, pharyngeal slits (at some stage) |
| Class | Mammalia | Hair, mammary glands, endothermic, 4-chambered heart |
| Order | Primates | Forward-facing eyes, grasping hands, large brain relative to body size, nails not claws, reduced snout |
| Family | Hominidae | Great apes — no tail, large body, complex social behaviour, great intelligence. Includes gorillas, chimpanzees, orangutans, bonobos, and humans. |
| Genus | Homo | Fully bipedal, large brain (>600 cc), reduced face and jaw, tool use |
| Species | Homo sapiens | Brain ~1400 cc, chin, high forehead, fully modern skull, language and symbolic thought |
🧠 Primate Features Relevant to Human Evolution
- Forward-facing eyes — binocular stereoscopic vision; excellent depth perception; critical for tool manipulation and judging distances
- Grasping hands — opposable thumbs; precision grip; critical for tool making and use
- Large brains — relative to body size; associated with complex social behaviour, learning, and problem solving
- Reduced olfaction, enhanced vision — colour vision in three wavelengths; diurnal lifestyle
- Slow reproduction, extended parental care — longer period of learning and brain development; small litter size
🧬 Molecular Evidence of Common Ancestry
- Human DNA is ~98.7% identical to chimpanzee DNA — the closest living relative
- Gorilla DNA is ~98.3% identical to humans
- These comparisons use DNA hybridisation and sequencing techniques
- Cytochrome c (a protein involved in cellular respiration) is identical in humans and chimpanzees — used as molecular evidence of common ancestry
- Shared non-functional DNA sequences (pseudogenes, endogenous retroviruses) at the same locations in human and chimp genomes — impossible to explain except through common ancestry
The Hominin Timeline
6 Million Years of Change⏳ A Branching Bush, Not a Ladder
Human evolution was NOT a straight line from ape to modern human. It was a branching bush with many species coexisting, competing, and going extinct. For the IEB, you need to know the key species in the human lineage in chronological order, their approximate dates, their key physical features, and the general trend toward bipedalism, reduced jaw, and increased brain size over time.
Skull Features & Trends
Reading the Fossil Record💀 What Skulls Tell Us
The IEB requires you to identify and compare hominid skull features — from fossil photographs or diagrams. You need to know which features changed over time, in which direction, and what those changes mean for behaviour and lifestyle. The main trends are: increasing brain size, decreasing jaw and tooth size, reducing brow ridges, changing skull shape from flat to rounded, and the appearance of a chin.
| Feature | Australopithecus | H. habilis | H. erectus | H. sapiens |
|---|---|---|---|---|
| Brain size (cranial capacity) | 400–500 cc | ~650 cc | 850–1100 cc | ~1400 cc |
| Skull shape | Low, flat skull; sagittal crest (in some) for jaw muscle attachment | Slightly more rounded than Australopithecus | Low, elongated skull with thick bones | High, rounded, domed skull with thin bones |
| Forehead | Very sloping, receding | Slightly less sloping | Low, sloping | High, vertical, prominent |
| Brow ridges (supraorbital torus) | Heavy, prominent brow ridge | Pronounced but less than Australopithecus | Heavy, continuous brow ridge (most prominent in genus Homo) | Minimal — small or absent |
| Face / prognathism | Very prognathous — face projects forward significantly | Prognathous but less than Australopithecus | Moderately prognathous | Flat, orthognathous — face sits below braincase |
| Jaw and teeth | Large jaw; large molars and premolars for grinding tough plant food; reduced canines | Smaller than Australopithecus | Smaller, thinner jaw | Small, parabolic (rounded) jaw; small teeth |
| Chin | Absent — receding chin | Absent | Absent | Present — protruding bony chin. Unique to H. sapiens |
| Occipital region (back of skull) | Flat; occipital torus (ridge) | Less pronounced ridge | Occipital torus present | Rounded; no occipital torus |
| Foramen magnum position | More forward than apes — confirming bipedalism | Forward | Forward | Directly beneath skull — fully bipedal |
| Tool use | No stone tools | Oldowan tools — simple pebble choppers | Acheulean tools — bifacial hand axes; fire | Complex tools, art, language, symbolic thought |
🦴 Skeletal Evidence for Bipedalism
- Foramen magnum — positioned centrally below skull (not at back like in quadrupeds)
- Pelvis — bowl-shaped (broad, short ilium) to support abdominal organs in upright position; vs long, narrow ape pelvis
- Femur — angled inward (valgus angle) so feet are under centre of gravity; apes have vertical femur
- Knee joint — adapted for full extension and weight-bearing in upright posture
- Foot — arched foot with non-opposable big toe aligned with other toes; apes have grasping feet
- Vertebral column — S-shaped curve (lumbar lordosis) absorbs shock and balances head over pelvis; apes have C-shaped
- Laetoli footprints (Tanzania, 3.6 mya) — fossilised footprints of A. afarensis showing human-like bipedal gait with arched foot and aligned big toe
✅ Advantages of Bipedalism
- Frees the hands — for carrying food, infants, and eventually making and using tools
- Energy efficient — bipedal walking is more energy-efficient than knuckle-walking over long distances
- Thermoregulation — upright posture reduces surface area exposed to midday sun; head is further from hot ground; allows longer foraging in open savanna heat
- Elevated head — better view over tall grass for predator detection
- Long-distance running (persistence hunting) — Achilles tendon, arched foot, gluteus maximus allow endurance running unique to humans
Evidence for Human Evolution
Multiple Lines of Proof🔬 Convergent Evidence from Many Fields
The evidence for human evolution does not come from a single source — it converges from palaeontology (fossil record), comparative anatomy, molecular biology, and archaeology. The IEB requires you to know what each type of evidence is, give examples, and explain what conclusions can be drawn. Crucially, you should be able to explain why multiple independent lines of evidence strengthen scientific confidence in the theory of evolution.
🪨 What Fossils Tell Us
- Fossils are the preserved remains or traces of past organisms — bones, teeth, shells, casts, footprints, impressions
- Hard tissues (bone, teeth) are most commonly preserved — soft tissue rarely fossilises
- Skull morphology shows changes in brain size, jaw structure, brow ridges, and face shape over time
- Post-cranial skeleton (pelvis, femur, foot) shows transition to bipedalism
- The fossil record shows a progression of increasing complexity and human-like features over time — though with many branches, dead ends, and gaps
⏱️ Dating Fossil Specimens
- Radiometric dating — uses radioactive decay of isotopes (e.g. potassium-40 → argon-40 with a half-life of 1.25 billion years; carbon-14 for material up to ~50 000 years old). Gives absolute age in years.
- Stratigraphy — relative dating using rock layers (strata). Deeper layers are older. Fossils found in the same stratum are approximately the same age. Does NOT give an absolute age.
- Palaeomagnetism — uses reversals in Earth's magnetic field recorded in rocks to date strata
- Biostratigraphy — using known ages of other fossil species found in the same layer to date specimens
🦴 Homologous Structures
- Structures that share the same basic anatomical plan (same bones, same developmental origin) even if they have different functions — evidence of common ancestry
- The pentadactyl limb: human arm, horse leg, whale flipper, bat wing, dog leg — all have the same sequence of bones (humerus, radius/ulna, carpals, metacarpals, phalanges) despite very different functions
- Primate forelimbs are homologous — reflecting shared evolutionary origin of the vertebrate limb
- Distinguished from analogous structures (same function, different origin — e.g. bird wing and insect wing): analogous structures indicate convergent evolution, NOT common ancestry
🌫️ Vestigial Structures in Humans
- Structures that have reduced function compared to related species — evidence that we evolved from ancestors that used them
- Coccyx (tailbone) — remnant of tail; 3–5 fused vertebrae; serves as muscle attachment but no tail function
- Plica semilunaris — small fold of tissue in corner of eye; remnant of the nictitating membrane (third eyelid) present in many vertebrates
- Erector pili muscles — cause "goosebumps"; in ancestors raised body hair for insulation or threat display — no significant function in modern hairless humans
- Wisdom teeth (third molars) — functional in ancestors with large jaws and tough diets; now frequently impacted due to reduced jaw size
- Palmaris longus muscle — forearm muscle for gripping and swinging in trees; absent in ~10–15% of modern humans with no functional loss
| Technique | What It Compares | What It Shows |
|---|---|---|
| DNA sequencing | Nucleotide sequences of the same gene across species | The more similar the sequence, the more closely related. Humans share 98.7% DNA with chimps, 98.3% with gorillas — confirming the phylogenetic tree built from anatomy. |
| DNA hybridisation | How tightly DNA strands from two species bind together | More similar sequences bind more tightly (higher melting point). Used to estimate degree of relatedness before sequencing was routine. |
| Protein comparison | Amino acid sequences of conserved proteins (e.g. cytochrome c, haemoglobin) | Differences in amino acid sequence reflect accumulated mutations since divergence. Cytochrome c is identical in humans and chimps — extremely conserved. |
| Mitochondrial DNA (mtDNA) | Maternally inherited DNA with high mutation rate | Used to trace female lineages. All modern human mtDNA traces back to a common African ancestor ("Mitochondrial Eve") ~150 000–200 000 years ago — supports Out of Africa model. |
| Y-chromosome analysis | Paternally inherited DNA | All modern human Y chromosomes trace to a common African ancestor ("Y-chromosomal Adam") — also supports African origin of modern humans. |
South African Fossil Heritage
Cradle of Humankind🇿🇦 South Africa — The Birthplace of Human Palaeontology
South Africa holds some of the most important fossil hominin sites in the world. The Cradle of Humankind (northwest of Johannesburg) is a UNESCO World Heritage Site containing a complex of cave systems — Sterkfontein, Swartkrans, Kromdraai, Drimolen, Rising Star — that have yielded hundreds of hominin fossils spanning 3+ million years. South Africa's contribution to understanding human origins is unmatched. For the IEB, knowing the key discoveries, who found them, and what they revealed is essential.
📍 Discovery Details
- Discoverer: Raymond Dart, University of the Witwatersrand, 1924
- Site: Taung limestone quarry, Northern Cape, South Africa
- Specimen: Skull of a child aged approximately 3–4 years; includes endocast (cast of brain cavity)
- Age: ~2.5–2.8 million years old
- Named: Australopithecus africanus — "Southern Ape of Africa"
🔬 Why It Was Significant
- The foramen magnum was positioned forward and downward — confirming bipedalism even with a brain the size of a chimpanzee's (~440 cc)
- Smaller canine teeth than apes — indicating reduced aggression function
- Rounded orbits and some humanlike dental features
- Dart proposed it was a human ancestor — but was initially ridiculed by the European scientific establishment who believed the "Piltdown Man" (later revealed as a hoax) was the true ancestor
- Dart was ultimately vindicated — the Taung Child remains one of the most important fossil discoveries in history
| Specimen | Discoverer / Year | Significance |
|---|---|---|
| "Mrs Ples" (Sts 5) | Robert Broom, 1947 | Nearly complete A. africanus skull. One of the most famous hominin fossils. Initially thought to be female (hence the nickname), more recent analysis suggests possibly male. Confirms Dart's earlier findings on a much more complete specimen. |
| "Little Foot" (StW 573) | Ron Clarke, 1994–ongoing (still being excavated) | Most complete Australopithecus skeleton ever found (~90% complete). ~3.67 million years old. Shows mosaic of ape and human features — could both walk upright and climb trees. Took decades to excavate from solid rock. |
| Stw 53 | Hughes & Tobias, 1976 | Partial skull possibly representing early Homo or transitional form; debated classification. Shows Sterkfontein contains multiple hominin species over time. |
📍 Discovery
- Site: Dinaledi Chamber ("Chamber of Stars"), Rising Star cave, Cradle of Humankind
- Discoverer: Lee Berger (Wits University) and team, 2013; announced 2015
- Specimens: Over 1 550 bone fragments representing at least 15 individuals — one of the largest hominin fossil collections ever found in Africa
- Age: Surprising — 236 000–335 000 years old, meaning H. naledi lived at the same time as early H. sapiens
🔬 Unique Features — A Mosaic Species
- Small brain — ~465–560 cc, similar to Australopithecus despite being Homo
- Hands — human-like curved fingers suitable for tool use but also for climbing
- Feet — nearly identical to modern human feet — fully bipedal
- Teeth — small, simple teeth more like H. sapiens than australopithecines
- Possible deliberate burial — location deep in cave with no evidence of predation or water transport suggests intentional body disposal — raises questions about cognitive complexity
🎯 Human Evolution Assessment
Eight IEB-style questions on human evolution.