1. The Theory of Evolution by Natural Selection

2. Evolution of Evolutionary thinking (Pre-Darwinian)
Jean-Baptiste Lamarck ( ) – French naturalist, proposed a theory that organisms were driven by some inner force toward greater complexity. But thought that org. could pass on traits to their offspring that they acquired during their lives. (“Lamarckism”, proposed in 1809)

3. Lamarckism
Lamarck based his theory on two observations thought to be true in his day:
“Use it or lose it” - Individuals lose characteristics they do not require and develop those which are useful.
Inheritance of acquired traits - Individuals inherit the acquired traits of their ancestors.

4. Lamarckism This theory was later disproved!
Examples include: the stretching by giraffes to reach leaves leads to offspring with longer necks;
Strengthening of muscles in a blacksmith's arm leads to sons with like muscular development.
This theory was later disproved!

5. Darwin’s Voyage Charles Darwin Set sail on the HMS Beagle in 1831
Became the ship’s naturalist
Arrived in the Galapagos Islands in 1835
Observed that the animals on the islands were similar to those on the mainland

6. Darwin’s Voyage Galapagos Animals
The Galapagos animals, while similar, were also different from island to island as well as to the mainland
Most obvious difference were the sizes and shapes of the finches’ (small birds) beaks
Sizes and shapes of the beaks were adapted to what the birds ate

7. Galápagos Finches Beak shape varies depending on diet Berry eater
Seed eaters
Cactus eaters
Insect eaters

8. Darwin’s Voyage On the Origin of Species (Darwin’s book)
For the 20 years that followed his return to England Darwin studied plants, animals and adaptations
Darwin wrote about how species can change gradually over many, many generations and become better adapted to new environmental conditions.

9. Evolution
"Change over time"

10. Natural Selection
Organisms that are better adapted to an environment are more likely to survive and reproduce than organisms that are less well adapted.

11. Adaptations Katydids have camouflage to look like leaves.
Non-poisonous king snakes mimic poisonous coral snakes.

12. Factors that affect Natural Selection:
Overproduction most species produce far more offspring than will/can survive
Competition: since food and resources are limited, the offspring have to compete to survive
Variation:  Members within a species exhibit individual differences – these differences must be inheritable

13. How do new species form? Natural Selection-"survival of the fittest"
Continental Drift-continents separated, the animals were separated
Changes in environment-changes in water temp or acidity
Mutations-changes in DNA
Man-Artificial Selection (video from warm-up)

14. Mutations
Some species are more susceptible to mutations. Some mutations allow the animal to survive; other mutations do not allow the animal to survive. The mutations that are not decrease the chance of survival remain.

15. Continental Drift
Fossil records show that when the continents were connected animals walked across. When the continents separated, the animals were separated.

16. Changes in the Environment
Example, the pepper moth.
Originally, the pepper moth was white, which was good because it could blend in.
Then, trains were invented and the soot they produced covered the trees. Making the trees black. The moths that were black could now survive better.

17. Man: Artificial Selection
Selective breeding as practiced by humans on domesticated plants and animals….
For example: Dogs

18. Evidence of Evolution Fossil Record Similarities in Body Structure
Similarities in Early Development
Vestigial Structures
Similarities in DNA

19. Fossil Record How fossils form
An organism dies and becomes buried in sediment
Minerals gradually replace the bones and more sediments cover the fossil
Pterodactyl
Trilobite

20. Homologous structures
similar in function, similar in structure inherited from a common ancestor) 

21. Analogous Structures
similar in function, not inherited from a common ancestor.  (Different in structure)  
Ex. 
bird wing   butterfly wing   

22. Vestigial Structures
Vestigial Structures A structure found in an organism that is no longer in use but may have been useful at some point in the organism's life.
Whales possess a femur and pelvis, but these bones are no longer useful to the mammals.
Tail Present in human and all vertebrate embryos. In humans, the tail is reduced; most adults only have three to five tiny tail bones and, occasionally, a trace of a tail-extending muscle.

23. Similarities in Early Development
Scientists look at embryos of different organisms and find that many embryos resemble one another.

24. Vestigial Structures
Why do dogs have tiny, functionless toes on their feet (dewclaws)?
Ancestral dogs had five toes on each foot

25. Similarities in DNA
The more similar the sequences of DNA are, the more closely related the organisms are.
Humans and chimpanzees DNA is more similar than human DNA is to dog DNA.

26. Patterns of Evolution
Divergence
Adaptive radiation
Convergence

27. Divergent Evolution
New species develop traits that differentiate them from their ancestors
Divergence accounts for descendants that differ from their ancestors and from one another

28. Convergent Evolution
Unrelated animals develop similar body forms to fill same niche

29. Adaptive radiation
Mammals filled ecological niches vacated by dinosaurs
Greatest mass extinction occurred millions of years before us- the dinosaurs
More than 90% of all species died out – the animals that remained filled the gap

30. How we know what happened when
Radiometric Dating
Stratigraphy
Molecular clocks

31. Radiometric Dating Radioactive Dating (Absolute Dating)
Rocks that fossils are found near contain radioactive elements.
The half-life of a radioactive element is the time it takes for half the atoms in an element to change into a stable element (carbon 14 into carbon 12)

32. Stratigraphy
Fossils from organisms that died longer ago are buried deeper in the sediment/rock than fossils from organisms that died more recently.

33. Molecular clocks
When a stretch of DNA does indeed behave like a molecular clock, it becomes a powerful tool for estimating the dates of lineage-splitting events.