1. Classification
8a Define taxonomy and recognize the importance of a standardized taxonomic system
8b Categorize organisms using a hierarchical classification system based on similarities and differences shared among groups
8c Compare characteristics of taxonomic groups including archaea, bacteria, protists, fungi, plants and animals

2. What’s my name?
Mountain lion
Cougar
Puma
Panther
Catamount

3. Taxonomy
the naming, describing, and classifying organisms based on characteristics

4. Carolus Linnaeus
Father of taxonomy

5. Binomial Nomenclature
formal system of naming organisms by giving each a name composed of two parts, both of which use Latin

6. Scientific Names
The first word is the organism’s Genus (closely related species)
The second word is the organism’s species
Genus species

7. Homo sapiens

8. Felis concolor

9. Liquidambar styraciflua

10. Canis lupus

11. Linnaeus’s System of Classification:
Flowchart
Linnaeus’s System of Classification:
General to Specific
Section 18-1
Kingdom
Phylum
Class
Order
Family
Genus
Species

14. Why classify? To group organisms according to similarities
To name organisms in a way that all scientists across the world can communicate (to get around language barriers)

15. But scientific names can change…
With new discoveries, we can re-classify organisms
“Chinese tallow tree” changed from Sapium sebiferum toTriadica sebifera

16. Modern Evolutionary Classification
The old Linnaeus way of using visible physical similarities puts organisms that are very different in the same groups.
So, now organisms are grouped according to characteristics that show common ancestry.
Phylogeny – the study of evolutionary relationships among organisms.
All members of a genus share a recent common ancestor.

17. Example: Barnacles and Limpets

18. CLASSIFICATION BASED ON VISIBLE SIMILARITIES
Traditional Classification Versus Cladogram pg. 452
Appendages
Conical Shells
Crustaceans
Gastropod
Crab
Barnacle
Limpet
Crab
Barnacle
Limpet
Molted exoskeleton
Segmentation
Tiny free-swimming larva
CLASSIFICATION BASED ON VISIBLE SIMILARITIES
CLADOGRAM

19. Example: Barnacles and Limpets
Adult barnacles look and act like limpets.
Limpets have similar insides to a snail and don’t shed their shells like a snail – mollusks.
Barnacles have similar anatomy and development to crabs – crustaceans.
So, barnacles are grouped with crabs and limpets are grouped with snails.

21. Cladogram
diagram that shows the evolutionary relationships among organisms

22. The closer together in a relational “line” the organisms are, the more closely they are related (the more recent their common ancestor)
The more similar the DNA the more recently they shared a common ancestor and the more closely they are related.

23. Derived Character
trait that is shared by organisms with a recent common ancestor

24. Clade
Group consisting of its ancestor and all its descendants

26. Cladogram of Six Kingdoms and Three Domains, pg. 460
DOMAIN ARCHAEA
DOMAIN EUKARYA
Kingdoms
Eubacteria
Archaebacteria
Protista
Plantae
Fungi
Animalia
DOMAIN BACTERIA

27. http://ccl. northwestern

28. Figure 3
___ Egg shells ___ Cells ___ Mammary glands ___ Feathers ___ Lungs ___ Four limbs D A F E C B

29. Dichotomous Key Series of ordered steps you follow to ID an organism
To use, you read both options, decide which variation is best, and move on to the next step.

31. Review
Prokaryote vs. Eukaryote

32. Review
Unicelluar vs. Multicellular

33. Review
Autotroph vs. Heterotroph

35. 3 Domains
Recently, new discoveries at the molecular level of organisms have caused a new way to categorize: domains.
Eukarya – protists, fungi, plants, and animals
Bacteria – same as eubacteria
Archaea – same as archaebacteria

36. The 6 Kingdoms Eubacteria – normal bacteria (strep, E. coli)
Archaebacteria – bacteria that live in extreme conditions and are usually anaerobic (hot springs, black mud, etc.)
Protista – most microorganisms (one or only few cells)
Fungi – mushrooms, yeasts, mold
Plantae – plants
Animalia - animals

37. Eubacteria Common term: bacteria Cell type: prokaryote
# of cells: unicellular
Cell walls: present; with peptidoglycan
Type of nutrition: autotroph or heterotroph

38. Eubacteria
Examples
E. coli
Streptococcus

39. Archaebacteria
Common term: none, this is a rare type of organism that lives in extreme places like hot springs
Cell type: prokaryote
# of cells: unicellular
Cell walls: present; without peptidoglycan
Type of nutrition: autotroph or heterotroph

40. Archaebacteria Examples Halobacterum (loves salt)
Thermoproteus (likes hot water)

41. Protista Common terms: protists or single-celled organisms
Cell type: eukaryote
# of cells: most unicellular; some colonial; some multicellular
Cell walls: some have cellulose cell walls and chloroplasts
Type of nutrition: autotroph or heterotroph

42. Protista
Poorly classified group (basically, if an organsisms doesn’t fit anywhere else, they put it here
Examples
Amoeba
Paramecium
Algae

43. Fungi Common term: fungus Cell type: eukaryote
# of cells: most multicellular; some unicellular
Cell walls: present; made of chitin
Type of nutrition: heterotroph

44. Fungi
Examples
Mushrooms
Yeast
Mold

45. Plantae Common term: plant Cell type: eukaryote
# of cells: multicellular
Cell walls: present; made of cellulose; chloroplasts present
Type of nutrition: autotroph (use photosynthesis)

46. Plantae
Examples
Mosses
Ferns
Pine trees
Flowering plants
Grass

48. Animalia Common term: animal Cell type: eukaryote
# of cells: multicellular
Cell walls: no cell wall or chloroplasts
Type of nutrition: heterotroph

49. Animalia
Examples
Sponge
Insects
Spiders
Fish
Birds
Reptiles
Mammals