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Chapter
17
Organizing Life’s Diversity
17.1 The History of Classification
Early Systems of Classification
 Biologists use a
system of
classification to
organize
information about
living things.
Chapter
17
Organizing Life’s Diversity
17.1 The History of Classification
Aristotle’s System
 Aristotle classified organisms as either
animals or plants.
 Often times used many descriptive terms
Chapter
17
Organizing Life’s Diversity
17.1 The History of Classification
Linnaeus’s System
 Linnaeus’s system of classification was the
first formal system of taxonomy.
Perching bird
Bird of prey
Wading bird
Chapter
17
Organizing Life’s Diversity
17.1 The History of Classification
Binomial Nomenclature
 Linnaeus’s method of naming organisms,
called binomial nomenclature, gives each
species a scientific name with two parts.
 The first part is the genus name, and the
second part is the species.
Ex. Ursus americanus
Chapter
17
Organizing Life’s Diversity
17.1 The History of Classification
 Why classify?
 Biologists use
scientific names
for species
because common
names vary in
different areas of
the world.
 Establishes a
“standard”
Ursus americanus
American black bear
Chapter
17
Organizing Life’s Diversity
17.1 The History of Classification
 Rules for scientific naming:
 The first letter of the genus name always is
capitalized, but the rest of the genus name and all
letters of the species are lowercase.
 If a scientific name is written in a printed book or
magazine, it should be italicized.
 When a scientific name is written by hand, both
parts of the name should be underlined.
 After the scientific name has been written
completely, the genus name will be abbreviated to
the first letter in later appearances
(e.g., C. cardinalis).
Chapter
17
Organizing Life’s Diversity
17.1 The History of Classification
Taxonomic Categories
 The taxonomic
categories are part of a
hierarchal system.
 Each category is
contained within
another, and they
are arranged from broadest to most specific.
Chapter
17
Organizing Life’s Diversity
17.1 The History of Classification
Species and Genus
 A named group of organisms is called a taxa.
 A genus is a group of species that are closely
related and share a common ancestor.
Chapter
17
Organizing Life’s Diversity
17.1 The History of Classification
Family
 A family is the next higher taxon, consisting
of similar, related genera.
Chapter
17
Organizing Life’s Diversity
17.1 The History of Classification
Higher Taxa
 An order contains related families.
 A class contains related orders.
 A phylum contains related classes.
 The taxon of related phyla or divisions is a
kingdom.
 The domain is the broadest of all the taxa and
contains one or more kingdoms.
Grizzly bear
Black bear
Giant
panda
Red fox
Abert
squirrel
Coral
snake
Sea star
KINGDOM Animalia
PHYLUM Chordata
CLASS Mammalia
ORDER Carnivora
FAMILY Ursidae
GENUS Ursus
SPECIES Ursus arctos
Chapter
17
Organizing Life’s Diversity
17.1 The History of Classification
Species and Genus
 A named group of organisms is called a taxa.
 A genus is a group of species that are closely
related and share a common ancestor.
Chapter
17
Organizing Life’s Diversity
17.2 Modern Classification
Typological Species Concept
 Aristotle and Linnaeus thought of each
species as a distinctly different group of
organisms based on physical similarities.
Chapter
17
Organizing Life’s Diversity
17.2 Modern Classification
Biological Species Concept
 How do scientists tell these species apart
to classify them?
 Think back to speciation!
 biological species a species as a group
of organisms that is able to interbreed and
produce fertile offspring.
Chapter
17
Organizing Life’s Diversity
17.2 Modern Classification
Biological Species Concept
 However, these barriers are not always
complete & different species can interbreed
to form viable offspring: hybrids
Hybrid
Panthera leo x Panthera tigris
P. leo x P. tigris
Hybrids
Equus caballus
x
Equus asinus
E. Caballus x E. asinus
Classification
• But making
evolutionary
connections based on
similar traits can be
misleading
• Organisms can look
similar but not share a
common ancestor
• So how do we
distinguish between
such relationships?
Chapter
17
Organizing Life’s Diversity
17.2 Modern Classification
Phylogenic Species Concept
 Phylogeny is the evolutionary history of a
species.
 The phylogenic species concept shows
evidence of a pattern of ancestry and
descent.
Chapter
17
Organizing Life’s Diversity
17.2 Modern Classification
Morphological Characters
 Shared morphological characters suggest that
species are related closely and evolved from a
recent common ancestor.
 Analogous characters  the same function
but different underlying construction.
 Homologous characters  different functions, but
show an anatomical similarity inherited from a
common ancestor.
Chapter
17
Organizing Life’s Diversity
17.2 Modern Classification
Biochemical Characters
 Scientists use biochemical characters, such
as amino acids and nucleotides, to help
them determine evolutionary relationships
among species.
 DNA and RNA analyses are powerful tools
for reconstructing phylogenies.
Chapter
17
Organizing Life’s Diversity
17.2 Modern Classification
Phylogenetic Reconstruction
 Cladistics reconstructs phylogenies based on
shared characters.
 Scientists consider two main types of characters
when doing cladistic analysis.
 An ancestral character is found within the entire
line of descent of a group of organisms.
 Derived characters are present members of one
group of the line but not in the common ancestor.
Chapter
17
Organizing Life’s Diversity
17.2 Modern Classification
Cladograms
 The greater the
number of derived
characters shared
by groups, the
more recently the
groups share a
common ancestor.
Section 18-2
Traditional Classification Versus Cladogram
Appendages
Crab
Conical Shells
Barnacle
Limpet
Crustaceans
Crab
Barnacle
Gastropod
Limpet
Molted
exoskeleton
Segmentation
CLASSIFICATION
BASED ON VISIBLE
SIMILARITIES
Tiny free-swimming larva
CLADOGRAM
Chapter
17
Organizing Life’s Diversity
17.3 Domains and Kingdoms
Grouping Species
 The three domains are
Bacteria, Archaea, and
Eukarya.
 The six kingdoms are
Eubacteria, Archaebacteria,
Protista, Fungi, Plantae,
and Animalia.
Chapter
17
Organizing Life’s Diversity
17.3 Domains and Kingdoms
Domain Bacteria
 Eubacteria are
prokaryotes whose cell
walls contain
peptidoglycan.
Chapter
17
Organizing Life’s Diversity
17.3 Domains and Kingdoms
Domain Archaea
 Archaea are thought to be more ancient than
bacteria and yet more closely related to our
eukaryote ancestors.
 Cell walls without
peptidoglycan
 They are called extremophiles because
they can live in extreme environments.
Chapter
17
Organizing Life’s Diversity
17.3 Domains and Kingdoms
Domain Eukarya
 All eukaryotes are classified in Domain
Eukarya.
 Domain Eukarya contains Kingdom
Protista, Kingdom Fungi, Kingdom Plantae,
and Kingdom Animalia.
Chapter
17
Organizing Life’s Diversity
17.3 Domains and Kingdoms
Kingdom Protista
 Protists are eukaryotic organisms that can
be unicellular, colonial,
or multicellular.
 Protists are
classified into three
different groups—
plantlike, animallike, and
funguslike.
Chapter
17
Organizing Life’s Diversity
17.3 Domains and Kingdoms
Kingdom Fungi
 A fungus is a unicellular or multicellular
eukaryote that
absorbs
nutrients from organic
materials in its
environment.
 Member of Kingdom
Fungi are
heterotrophic, lack motility, and have cell
walls.
Chapter
17
Organizing Life’s Diversity
17.3 Domains and Kingdoms
Kingdom Plantae
 Members of Kingdom Plantae form the base
of all terrestrial habitats.
 All plants are
multicellular and have
cell walls composed of
cellulose.
 Most plants are
autotrophs, but some are heterotrophic.
Chapter
17
Organizing Life’s Diversity
17.3 Domains and Kingdoms
Kingdom Animalia
 All animals are heterotrophic, multicellular
eukaryotes.
 Animal organs often are
organized into complex
organ systems.
 They live in the water,
on land, and in the air.
Making a Cladogram
Chapter
17
Organizing Life’s Diversity
17.3 Domains and Kingdoms