1. Cladograms or Phylogenetic Trees

2. Phylogenetic Trees or Cladograms By studying inherited species' characteristics and other historical evidence, we can reconstruct evolutionary relationships and represent them on a "family tree”, called a phylogeny. a branching pattern of evolutionary relationships.

3. Uses for phylogenetic trees Biologists use phylogenetic trees for many purposes, including: Testing hypotheses about evolution Learning about the characteristics of extinct species and ancestral lineages Classifying organisms

4. Aristotles’s Great Chain of Being Idea based on a step ladder Simplest to most complex

5. New Classification System Linnaean system of classification that assigns every organism a kingdom, phylum, class, order, family, genus, and species. This system was created long before scientists understood that organisms evolved. Linnaean system is not based on evolution, most biologists are switching to a classification system that reflects the organisms' evolutionary history. Linnaean System of Classification Evolutionary Based Classification

6. 3 Keys to remember about phylogenies

7. 1) They are not ladders Evolution produces a pattern of relationships among lineages that is tree- like, not ladder-like.

8. 2) Just because we tend to read phylogenies from left to right, there is no correlation with level of "advancement."

9. 3) For any speciation event on a phylogeny, the choice of which lineage goes to the right and which goes to the left is irrelavant.

10. Understanding Phlogenies (Cladograms) The root of the tree represents the ancestral lineage, and the tips of the branches represent the descendants of that ancestor. As you move from the root to the tips, you are moving forward in time.

11. Speciation When a lineage splits (speciation), it is represented as branching on a phylogeny. When a speciation event occurs, a single ancestral lineage gives rise to two or more daughter lineages.

12. Lineages Phylogenies trace patterns of shared ancestry between lineages. Each lineage has a part of its history that is unique to it alone and parts that are shared with other lineages.

13. Common Ancestor Similarly, each lineage has ancestors that are unique to that lineage and ancestors that are shared with other lineages — common ancestors.

14. Clades A clade is a grouping that includes a common ancestor and all the descendants (living and extinct) of that ancestor A clade may include many thousands of species or just a few.

15. What do we use to “group” organisms into their clades Shared-Derived Characteristics (Shared=what they have in common; Derived=what separates them) –Physical Characteristics (morphology) Homologous and Analogous Structures –Genetics Sequences –Behavioral Traits

16. Using Homologous and Analogous characteristics How does this clade show both homologous and analogous characteristics?

17. Homologous Structure Tetrapods- “Four Footed” Why aren’t bats and birds more closely related?

18. Analogous structures Bat wings and bird wings are analogous due to convergent evolution Bat’s wings consist of stretched skin between the bones Bird’s wings consist of feathers along the arm

19. Using DNA technology Scientist are using DNA sequences to construct phylogenetic trees »Construct a possible phylogenetic tree using the information in the table for humans, chimpanzee, gibbon, rhesus monkey, and galago.

20. HumanHuman ChimpanzeeChimpanzee GibbonGibbon RhesusRhesus GalagoGalago

22. Amniotic Egg http://youtu.be/Qq0kMEWzdHg http://youtu.be/Qq0kMEWzdHg The significance of the evolution of the amniotic egg is that it afforded greater independence to land animals They would no longer have to return to water to lay their eggs as there was no risk of the eggs drying out

23. What came first…. The Chicken or the Egg????? http://youtu.be/1a8pI65emDE