📖 Lesson 14 ⏱ ~30 min Year 10 · Unit 1 ⚡ +115 XP

Evidence for Evolution, Molecular and Biogeographical

Humans share 85% of protein-coding DNA with a zebrafish and 60% with a banana, because all three share a common ancestor traced back over 1.5 billion years.

Today's hook: Humans share about 85% of their protein-coding DNA with a zebrafish, a tiny aquarium fish, and about 60% with a banana. That staggering similarity reflects shared ancestors going back hundreds of millions of years. Researchers at the Australian National University in 2018 used mitochondrial DNA from 186 species to confirm that Australia's marsupials originated in South America 80 million years ago and crossed via Antarctica. Today you explore the molecular and biogeographical evidence that locks evolution into place. If DNA tells us we're cousins with a zebrafish, what does that actually mean?

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Warm-up

Think First

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Q1 · Humans share about 98% of their DNA with chimpanzees and about 50% with bananas. What does DNA similarity tell us about evolutionary relationships?

Think about why closely related species would have more similar DNA.

Q2 · Australia has marsupials like kangaroos and koalas, while other continents have mostly placental mammals. How might the movement of continents explain this pattern?

Consider what would happen if a landmass became isolated before certain groups evolved.

Learning objectives

What you'll master

3 areas

● Know

That DNA and protein similarities across species indicate relatedness
The concept of a molecular clock for estimating divergence times
That biogeography and antibiotic resistance provide evidence for evolution

● Understand

How molecular evidence independently supports the theory of common ancestry
Why species distribution across continents matches evolutionary predictions
How antibiotic resistance demonstrates evolution by natural selection in real time

● Can do

Interpret DNA similarity data to infer evolutionary relationships
Use biogeographical patterns to explain evolutionary history
Explain antibiotic resistance using the principles of natural selection

Vocabulary · tap to flip

Words You Need

8 terms

Core term Concept Skill Reference

Molecular evidence

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Molecular evidence

Evidence for evolution based on similarities and differences in DNA, RNA and proteins.

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Molecular clock

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Molecular clock

A conceptual tool that uses the rate of DNA mutations to estimate when species diverged from common ancestors.

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Biogeography

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Biogeography

The study of the geographical distribution of species and how it relates to evolutionary history.

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Common ancestry

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Common ancestry

The idea that different species descended from a shared ancestral population.

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Antibiotic resistance

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Antibiotic resistance

The ability of bacteria to survive and reproduce in the presence of antibiotics that once killed them.

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Cytochrome c

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Cytochrome c

A protein involved in cellular respiration, used to compare evolutionary relatedness across species.

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Convergent evolution

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Convergent evolution

The independent evolution of similar traits in unrelated species facing similar environments.

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MRSA

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MRSA

Methicillin-resistant Staphylococcus aureus, a strain of bacteria resistant to many antibiotics.

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Cross-lesson links: Molecular evidence connects directly to Lesson 2 (DNA Structure and Function), because DNA sequence comparisons are only possible because of base pairing and the genetic code. It also reinforces Lesson 13 (fossil and anatomical evidence) as a second, independent line of proof, and explains the biogeographical patterns, like Australia's marsupials, that Lesson 15 (Speciation and Isolation) accounts for mechanistically.

Core learning

Stop & Check, Molecular Evidence

Quick Check

+5 XP

Swap the DNA sequence of a human cytochrome c protein with that of a chimpanzee, and it works perfectly, the proteins differ by just 0 amino acids out of 104. Compare the same protein in a yeast cell and 44 positions differ. That measurable distance is the molecular clock of evolution. Molecular evidence for evolution comes from comparing the DNA, RNA and proteins of different species. The principle is simple: closely related species have more similar molecules because they inherited them from a more recent common ancestor. Humans and chimpanzees share about 98-99% of their DNA; humans and mice share about 85%; humans and fruit flies share about 60%. These percentages reflect the evolutionary distances between the groups.

Biogeographythe study of where species live, provides complementary evidence. Related species tend to be found near each other, not randomly distributed across the globe. Australia has marsupials because marsupials evolved when Australia was connected to South America via Antarctica, and then Australia drifted northward in isolation. Placental mammals outcompeted marsupials on most other continents, but in Australia, marsupials diversified to fill ecological niches occupied by placentals elsewhere.

Example

The extinct thylacine, or Tasmanian tiger, looked and behaved so much like a dog that European settlers called it a tiger. But DNA extracted from preserved thylacine pups shows it was a marsupial, more closely related to kangaroos than to any dog or wolf. Its dog-like form evolved independently through convergent evolution, because the niche of a medium-sized predator favours similar body plans regardless of ancestry.

Real-world anchor

Australian ancient DNA: The Australian Centre for Ancient DNA (ACAD) at the University of Adelaide extracts and sequences DNA from fossils up to 50,000 years old. Their work has shown that the extinct thylacine and Tasmanian devil shared a common ancestor relatively recently, and that both lineages diversified during Australia's drying climate. Ancient DNA is rewriting what we know about Australian evolution.

Watch out

Some students think molecular evidence contradicts the fossil record. In fact, the two usually agree beautifully. When they disagree, scientists do not throw out evolution, they investigate the discrepancy. Sometimes the fossils were misdated; sometimes molecular clocks need recalibration; sometimes both. The convergence of independent lines of evidence is what makes evolutionary theory so robust.

Predict / Observe / Explain+8 XP

1 · Predict

2 · Observe

3 · Explain

Scenario

Australia separated from other continents around 50 million years ago and has been isolated ever since. Predict: would you expect Australian mammals to be more genetically similar to mammals on other continents, or to each other?

Step 1 · Your prediction

Your prediction: (none recorded)

Observation

Australian mammals such as kangaroos, koalas, wombats and Tasmanian devils are all marsupials that share a more recent common ancestor with each other than with placental mammals on other continents. DNA studies confirm that Australian marsupials form a distinct evolutionary branch that diverged after the separation of Australia.

Step 3 · Now explain

Use these terms in your explanation: isolation · divergence · marsupial · gene flow

From the lesson

Additional content

If you want to know how closely related two species are, compare their DNA. The molecule that stores genetic instructions is a historical document, and it records the evolutionary past with remarkable fidelity.

From the lesson

Additional content

All living things use DNA as their genetic material, and the genetic code (which codons specify which amino acids) is nearly universal. This universality itself is strong evidence for common ancestry. But the details are even more revealing:

From the lesson

Additional content

Humans and chimpanzees share approximately 98.8% of their DNA. Our last common ancestor lived roughly 6–7 million years ago.

Humans and mice share about 85% of their DNA. Our last common ancestor lived roughly 90 million years ago.

Humans and fruit flies share about 60% of their DNA. Our last common ancestor lived roughly 600 million years ago.

Humans and bananas share about 50% of our DNA. This sounds surprising, but both humans and bananas are eukaryotes that perform cellular respiration, have cell nuclei, and use many of the same core genes for basic cell functions.

From the lesson

Additional content

Scientists also compare specific proteins. Cytochrome c, a protein involved in cellular respiration, has been sequenced in hundreds of species. The number of amino acid differences between species correlates strongly with how long ago they diverged. Humans and chimpanzees have identical cytochrome c. Humans and yeast differ by 45 amino acids.

From the lesson

Additional content

Science Tip

Percentage DNA similarity reflects the recency of common ancestry, not "how human" something is. A banana sharing 50% of its DNA with humans simply means we both inherited the same ancient genes for basic cellular functions from our distant eukaryotic ancestor.

From the lesson

Additional content

Fun Fact, Humans and Bananas

Humans share about 50% of our DNA with bananas. This does not mean we are "half banana." It means that about half of the genes in a banana cell perform basic cellular functions, making energy, building proteins, responding to stimuli, that are also essential in human cells. These core genes have been conserved for over a billion years because they work so well. Evolution rarely fixes what is not broken.

Estimating evolutionary time from DNA changes

Molecular Clocks

+5 XP

Convergent evolution occurs when unrelated species independently evolve similar traits because they face similar environmental challenges. The classic example is the marsupial-placental comparison. Australia has marsupial 'moles', 'mice', 'cats', 'wolves' and 'flying squirrels' that look and behave like their placental counterparts on other continents, but evolved entirely separately. These similarities are analogous (same function, different origin), not homologous (same origin, different function).

Convergent evolution is strong evidence for natural selection because it shows that similar environments produce similar solutions, even starting from different ancestral stock. It also explains why unrelated species on different continents can look confusingly alike. The key to telling homology from analogy is detailed anatomical and molecular comparison: analogous structures may look similar on the outside, but their underlying anatomy and genetics differ.

Example

The eye has evolved independently at least 40 times in different animal lineages. Octopus eyes and human eyes look remarkably similar, both have a lens, iris, retina and optic nerve, but they evolved completely separately. In fact, octopus eyes are arguably better designed: their retinas are oriented correctly, with nerves behind the photoreceptors, so they have no blind spot. Human eyes are built backwards, a quirk inherited from our fish ancestors.

Real-world anchor

Australian biogeography: Alfred Russel Wallace, who independently conceived the theory of natural selection alongside Darwin, spent years in the Malay Archipelago and defined the Wallace Line, a sharp biogeographical boundary between Asian and Australian fauna. The line marks the edge of the former Australian continental shelf, and species distributions on either side provide dramatic evidence of how geography shapes evolution.

Match each Australian marsupial to its convergent placental counterpart.

Thylacine (Tasmanian tiger)
Numbat
Marsupial mole
Sugar glider
Quoll

Anteater
Flying squirrel
Golden mole
Cat
Wolf / dog

Stop & Check, Biogeography

Quick Check

+5 XP

Islands are natural laboratories for evolution. When a population becomes isolated, on an island, behind a mountain range, or on a separated continent, it can no longer exchange genes with the main population. Over time, mutations and different selection pressures cause the isolated population to diverge. If the divergence is great enough, the populations may become separate species that cannot interbreed even if they meet again.

DNA barcoding is a modern tool that uses a short, standardised segment of DNA to identify species. By comparing barcode sequences, scientists can distinguish closely related species, detect invasive species at borders, and monitor biodiversity. In Australia, DNA barcoding has revealed cryptic species, organisms that look identical but are genetically distinct, among frogs, insects and plants. This hidden diversity is crucial for conservation.

Example

New Zealand has no native land mammals except bats. When Maori and then European settlers arrived, they introduced rats, cats and possums. These placental predators devastated native bird populations that had evolved without mammalian predators and lacked defensive behaviours. The isolation that made New Zealand's birds unique also made them vulnerable, a tragic illustration of how evolution shapes both resilience and fragility.

Real-world anchor

Australian conservation genomics: The Australian Museum's Australian Museum Research Institute uses DNA barcoding to catalogue Australia's immense biodiversity. Their work has discovered hundreds of new species and is building a reference library that helps biosecurity officers identify pests at ports and airports, protecting Australian agriculture and ecosystems from invasive species.

Why do Australian marsupials dominate while placental mammals dominate most other continents?

From the lesson

Additional content

The geographical distribution of species provides powerful evidence for evolutionary history. If species were independently created, there would be no reason to expect their distribution to match the movement of continents. But they do.

From the lesson

Additional content

Biogeography is the study of where species live and why. Key patterns include:

From the lesson

Additional content

Continental driftas tectonic plates moved, they carried species with them. Fossil distributions on now-separated continents match the ancient supercontinent of Pangaea.

Island biogeographyislands tend to have unique species closely related to those on the nearest mainland. For example, marsupials in Australia are related to ancient South American marsupials, because both continents were once connected as part of Gondwana.

The Wallace Linea sharp boundary between Asian and Australian fauna running through Indonesia. It marks the ancient separation of the Asian and Australian continental plates.

From the lesson

Additional content

Australian Context

Marsupial evolution in Australia is one of the great biogeographical stories. When Australia separated from Gondwana around 50 million years ago, it carried marsupial mammals with it. Isolated from placental mammals that dominated other continents, Australian marsupials diversified into an astonishing array of forms: carnivorous Tasmanian devils, burrowing wombats, gliding possums, hopping kangaroos and koalas that climb eucalypts. This adaptive radiation occurred because marsupials filled ecological niches that placental mammals filled elsewhere, a pattern predicted by evolution and explained by Australia's long isolation.

From the lesson

Additional content

Antibiotic Resistance, Evolution in Real Time

From the lesson

Additional content

Perhaps the most medically urgent example of evolution is antibiotic resistance. When antibiotics are used, they create a powerful selection pressure on bacterial populations:

From the lesson

Additional content

Variation exists, some bacteria have random mutations that make them slightly less susceptible to the antibiotic.

Selection pressurethe antibiotic kills susceptible bacteria.

Differential survivalresistant bacteria survive and reproduce.

Heritabilityresistance is encoded in DNA and passed to offspring.

Resultover time, the population shifts from mostly susceptible to mostly resistant.

From the lesson

Additional content

MRSA (methicillin-resistant Staphylococcus aureus) is a major problem in Australian hospitals. It evolved through natural selection acting on bacterial variation in response to antibiotic use. Understanding evolution is not just academic, it is essential for modern medicine.

Real-World Anchor

Antibiotic Resistance in Australian Hospitals

The Australian Commission on Safety and Quality in Health Care tracks antibiotic resistance nationwide. In 2023, MRSA and resistant strains of E. coli and Klebsiella caused thousands of serious infections. The World Health Organization has declared antimicrobial resistance one of the top ten global public health threats. Combating it requires not just new drugs, but also public understanding of evolution: finishing prescribed courses, avoiding unnecessary antibiotic use, and recognising that bacteria evolve in response to our medical practices.

From the lesson

DNA Chart

Fig. 1, DNA similarity percentages between humans and other species. The closer the match, the more recently the species shared a common ancestor.

From the lesson

Activity 1

Interpret Data, Activity 1

Analyse the Molecular Evidence

Use the DNA similarity data above and your knowledge to answer the following.

1 Based on DNA similarity, which species is most closely related to humans? Explain your reasoning.

Answer in your book.

2 Why do humans and bananas share 50% of their DNA despite looking completely different?

Answer in your book.

3 A scientist sequences cytochrome c from an unknown mammal and finds it differs from human cytochrome c by 12 amino acids. From chimpanzee cytochrome c, it differs by 11 amino acids. What can you conclude?

Answer in your book.

4 Explain how molecular evidence supports the theory of common ancestry independently from fossil evidence.

Answer in your book.

5 If molecular clock estimates suggest humans and mice diverged 90 million years ago, but a new fossil discovery pushes that date back to 100 million years, which estimate is likely more reliable? Why?

Answer in your book.

From the lesson

Activity 2

Apply & Explain, Activity 2

Biogeography and Australian Marsupials

Use your understanding of biogeography and natural selection to explain Australian marsupial diversity.

1 Explain why Australia has so many marsupials while other continents have mostly placental mammals.

Answer in your book.

2 Describe how natural selection and Australia's unique environments contributed to the evolution of kangaroos, koalas and Tasmanian devils from a common marsupial ancestor.

Answer in your book.

3 Explain how antibiotic resistance in bacteria demonstrates all five principles of natural selection. Use MRSA as your example.

Write your explanation in your book.

From the lesson

Copy Into Your Book

▼

Molecular Evidence

DNA/protein similarities = relatedness
Human-chimp: ~98.8%
Human-banana: ~50% (shared core genes)
Cytochrome c differences correlate with divergence time

Molecular Clocks

Mutations accumulate at roughly steady rates
More differences = longer since divergence
Conceptual tool, cross-checked with fossils

Biogeography

Species distribution matches continental drift
Australian marsupials = Gondwana heritage + isolation
Wallace Line separates Asian and Australian fauna

Antibiotic Resistance

Evolution by natural selection in real time
Variation + antibiotic pressure = resistant survivors
MRSA is a major health threat in Australia

From the lesson

Additional content

Reflect

Revisit your thinking

reflect

At the start of this lesson you were told that humans share about 85% of their protein-coding DNA with a zebrafish, a figure that was probably surprising and maybe even hard to believe. That statistic was chosen to show you how powerful molecular evidence is: it reveals common ancestry that no fossil or anatomical clue could prove on its own.

Now that you have worked through molecular similarities, DNA comparisons and biogeographical evidence, including why Australia's marsupials ended up so isolated, explain in your own words why two independent lines of evidence (molecules + geography) are more convincing together than either would be alone.

Quick check · multiple choice

Quick check

Why do closely related species have more similar DNA?

+10 XP

Quick check

What is a molecular clock ?

+10 XP

Quick check

Biogeography supports evolution because...

+10 XP

Quick check

Antibiotic resistance in bacteria is an example of...

+10 XP

Quick check

Which statement best integrates the evidence for evolution?

+10 XP

From the lesson

Additional content

Short answer

Short answer · explain in your own words

Show your reasoning

3 questions

Understand Core 2 marks

Q1. Explain how DNA similarities between species provide evidence for common ancestry. 3 MARKS

Apply Core 3 marks

Q2. What is a molecular clock, and why is it useful for understanding evolutionary relationships? 4 MARKS

Analyse Core 3 marks

Q3. Using antibiotic resistance as an example, explain how evolution by natural selection can be observed directly. Refer to variation, selection pressure and heritability in your answer. 5 MARKS

From the lesson

Revisit

Revisit Your Initial Thinking

Go back to your Think First responses at the top of the lesson.

Did you correctly identify that DNA similarity indicates shared ancestry and recency of divergence?
Did you recognise that humans and bananas share DNA because core cellular functions are conserved across all eukaryotes?
Write one sentence summarising the most important new concept you learned about molecular evidence for evolution.

Model answers (click to reveal)

Comprehensive Answers

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Activity 1, Analyse the Molecular Evidence

1. Most closely related: Chimpanzees share ~98.8% of DNA with humans, the highest similarity shown [1 mark]. This indicates the most recent common ancestor [0.5 mark].

2. Humans and bananas: Both are eukaryotes that need the same core genes for basic cellular functions (cellular respiration, DNA replication, protein synthesis) [1 mark]. These genes have been conserved for over a billion years because they are essential for survival [1 mark].

3. Unknown mammal conclusion: The unknown mammal is very closely related to both humans and chimpanzees, likely another great ape [1 mark]. The small difference (11–12 amino acids) suggests divergence very recently in evolutionary terms [0.5 mark].

4. Independent support: Molecular evidence is independent of fossils because it comes from living organisms, not rocks [1 mark]. When DNA trees match fossil timelines, the conclusion is much stronger [0.5 mark].

5. More reliable estimate: Both estimates should be considered together. Molecular clocks provide relative timing, but fossils anchor estimates to absolute geological time [1 mark]. A conflict suggests the molecular rate estimate may need revision [0.5 mark].

Activity 2, Biogeography and Australian Marsupials

2. Marsupial radiation: After Gondwana separation, Australian marsupials were isolated from placental competitors [1 mark]. Different environments (arid plains, forests, grasslands) created different selection pressures [1 mark]. Variation in the ancestral population meant some individuals were better suited to each environment [1 mark]. Natural selection favoured different traits in different niches, leading to adaptive radiation [1 mark].

3. MRSA and natural selection: Variation exists, some bacteria have random mutations conferring resistance [1 mark]. Antibiotics create selection pressure, killing susceptible bacteria [1 mark]. Resistant bacteria survive and reproduce more [1 mark]. Resistance is heritable (encoded in DNA), so the trait spreads [1 mark]. The result is a population shift from susceptible to resistant, evolution observed in real time [1 mark].

Multiple Choice

1. BClosely related species share more DNA because they diverged more recently from a common ancestor. Option A confuses ecology with genetics. Option C reverses cause and effect. Option D is false.

2. CA molecular clock uses mutation rates to estimate divergence times. Options A, B and D describe laboratory equipment, not the conceptual tool.

3. ASpecies distribution matches continental drift and fossils. Options B, C and D are false.

4. CAntibiotic resistance is evolution by natural selection in real time. Option A describes Lamarckism. Option B describes a social issue, not a biological mechanism. Option D anthropomorphises bacteria.

5. DMultiple independent lines of evidence converge on common ancestry. Options A, B and C are false or present false conflicts.

Short Answer Model Answers

Q6 (3 marks): DNA similarities indicate common ancestry because all living things inherited their genetic code from shared ancestors [1 mark]. The more similar the DNA, the more recently the species shared a common ancestor, for example, humans and chimps share ~98.8% of DNA, reflecting divergence only 6–7 million years ago [1 mark]. Even distantly related species like humans and bananas share ~50% of DNA because core cellular genes have been conserved for over a billion years [1 mark].

Q7 (4 marks): A molecular clock is a conceptual tool that uses the roughly steady rate of DNA mutations to estimate when two species diverged from a common ancestor [1 mark]. Scientists count the number of DNA differences between species and use known mutation rates to calculate time [1 mark]. It is useful because it provides independent estimates of divergence times that can be compared with fossil and geological evidence [1 mark]. While not exact, molecular clocks consistently support the evolutionary relationships predicted by anatomy and fossils, strengthening the overall evidence [1 mark].

Q8 (5 marks): Antibiotic resistance is a direct observation of evolution by natural selection. Variation exists within bacterial populations, some bacteria carry random mutations that make them less susceptible to antibiotics [1 mark]. When antibiotics are used, they create a strong selection pressure that kills susceptible bacteria while resistant ones survive [1 mark]. This is differential survivalthe resistant bacteria reproduce more because they are alive [1 mark]. Resistance is heritable because it is encoded in bacterial DNA and passed to offspring during reproduction [1 mark]. Over many generations, the bacterial population shifts from mostly susceptible to mostly resistant, the population has evolved [1 mark]. MRSA in Australian hospitals is a direct result of this process.

Quick-fire challenge

Game time

+25 XP

From the lesson

Jump Through Molecular Evidence!

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Science Jump

Jump Through Molecular Evidence!

Climb platforms using your knowledge of DNA, molecular clocks and biogeography. Pool: Lesson 14.

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