Download Diversity of Life

DIVERSITY OF LIFE
Chapter 12
Chapters 13-15 included
ORGANIZING LIFE ON EARTH
• To make sense out of life’s diversity organisms are classified and
named based on their characteristics
• Phylogeny
• The evolutionary history and the relationships among a species or group of
species
• Systematics
• The study of organisms with the purpose of deriving their relationships
• Taxonomy
• The science of classifying organisms
ORGANIZING LIFE ON EARTH
• Taxonomy is based on the work of Karl von Linne (Linnaeus)
• Organisms are grouped based on shared characteristics
• Individual organisms are identified as a species
• Morphologically different from other groups
• Do not interbreed with other groups
ORGANIZING LIFE ON EARTH
• Taxonomy
• One or more species which share characteristics are placed in a
group called a taxon (plural is taxa)
• The first taxon is the genus
• Each species is assigned a name based on their genus plus a
descriptive specific epithet
• Genus species
• Italics
• The genus is capitalized, species is not
• Binomial naming system designed by Linneaus
ORGANIZING LIFE ON EARTH
• Taxonomy
• Taxa are then placed in broader
more inclusive categories (still
based on shared characteristics
ORGANIZING LIFE ON EARTH
• Taxonomy
• The levels of taxa from the most inclusive/broad to the most
exclusive are:
• Domain, Kingdom, Phylum, Class, Order, Family, Genus, Species
ORGANIZING LIFE ON EARTH
• Taxonomy of a house fly
• From most exclusive or specific to the most inclusive
• Species = Musca domestica
ORGANIZING LIFE ON EARTH
• Taxonomy of a house fly
• From most exclusive or specific to the most inclusive
• Species = Musca domestica
• Genus: Musca
ORGANIZING LIFE ON EARTH
• Taxonomy of a house fly
• From most exclusive or specific to the most inclusive
• Species = Musca domestica
• Genus = Musca
• Family = Muscidae
ORGANIZING LIFE ON EARTH
• Taxonomy of a house fly
• From most exclusive or specific to the most inclusive
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Species = Musca domestica
Genus = Musca
Family = Muscidae
Order = Diptera
ORGANIZING LIFE ON EARTH
• Taxonomy of a house fly
• From most exclusive or specific to the most inclusive
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Species = Musca domestica
Genus = Musca
Family = Muscidae
Order = Diptera
Class = Insecta
ORGANIZING LIFE ON EARTH
• Taxonomy of a house fly
• From most exclusive or specific to the most inclusive
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Species = Musca domestica
Genus = Musca
Family = Muscidae
Order = Diptera
Class = Insect
Phylum = Arthropoda
ORGANIZING LIFE ON EARTH
• Taxonomy of a house fly
• From most exclusive or specific to the most inclusive
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Species = Musca domestica
Genus = Musca
Family = Muscidae
Order = Diptera
Class = Insect
Phylum = Arthropoda
Kingdom = Animalia
ORGANIZING LIFE ON EARTH
• Taxonomy of a house fly
• From most exclusive or specific to the most inclusive
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Species = Musca domestica
Genus = Musca
Family = Muscidae
Order = Diptera
Class = Insect
Phylum = Arthropoda
Kingdom = Animalia
Domain = Eukarya
DETERMINING EVOLUTIONARY
RELATIONSHIPS
• Organisms that share similar physical features (morphology) and
genetic sequences tend to be more closely related than those
that do not
• Homologies
• Features overlap morphologically and genetically
• Arrangement of bones in the wing of a bird and the arm of a human
DETERMINING EVOLUTIONARY
RELATIONSHIPS
• Organisms that share similar physical features (morphology) and
genetic sequences tend to be more closely related than those
that do not
• Analogies
• Characteristic is superficially similar, but is not genetically similar
• Comparison of wings between birds and insects
• Lead to mis-classification of organisms
DETERMINING EVOLUTIONARY
RELATIONSHIPS
• Molecular comparisons
• Relatedness is now determined on more than just morphology
• Cell type, cell wall, reproduction, nutrition, motility, etc.
• Most importantly—genetic similarities
• Genetic relatedness
• Genetic information is compared
• Species A:
AACTAGCGCGAT
• Species B: AACTAGCGCCAT
• Species C:
T T CTAGCGG TAT
• Shows evolutionary relatedness (phylogenetic)
DETERMINING EVOLUTIONARY
RELATIONSHIPS
• Molecular comparisons
• Genetic analysis of many organisms resulted in three distinct
lineages or Domains
• Bacteria
• Archae
• Eukarya
QUESTIONS
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What is the correct way to write a scientific binomial name?
What is taxonomy?
Which is the most inclusive taxon?
Which is the most exclusive taxon?
Give an example of a homology
Name one domain
PHYLOGENETIC TREE
• Cladogram (a type of phylogenetic tree)
• Depicts relatedness of organisms which are arranged on
“branches”
• Those close to one another are more closely related
PHYLOGENETIC TREE
• Cladogram
• Branch points represent where a single lineage evolved into distinct
new ones
• Common ancestor is represented by the single branch point at the
base
PHYLOGENETIC TREE
• Cladogram
• Organisms are indicated at the end of each branched line
• Closely related: Rabbit and Lizard/3 and 4
• Less closely related: Rabbit and Lancelet/1 and 5
PHYLOGENETIC TREE
• Cladogram
• Significant character changes are indicated
• Must be quantifiable and heritable (Physical, behavioral, physiological, or
molecular trait)
PHYLOGENETIC TREE
• Cladogram
• Shared ancestral character (symplesiomorphy)
• All members of the lineage have this character
• Vertebral column/Letter A
PHYLOGENETIC TREE
• Cladogram
• Shared derived characters (synapomorphies) are traits that
• Arose since common ancestry
• Define each branching point
• Hinged jaw, legs, etc/Letters B-H
PHYLOGENETIC TREE
• Cladogram
• Outgroup shares only the ancestral character (symplesiomorphy)
• Derived characters (synapomorphies) arose later evolutionarily
• Lancelet/#5
• Clade: groups (taxa) that share a synapomorphy
PHYLOGENETIC TREE
• Cladogram
• Idealy taxonomists will be able to create
monophylogentic cladograms containing
• A common ancestor
• All the descendants
• Many cladograms are still either poly- or paraphylogenetic as there is missing information
about species, relatedness, and evolutionary
history
QUESTIONS
• Symplesiomorphy
Single ancestor and all its descendants
• Synapomorphy
Groups that share a synapomorphy
• Outgroup
Character common to all members of a lineage
• Character
Shares only the first character with the other group members
• Monophylogenetic
Character which has arisen since common ancestry with the outgroup
• Clade
Similar traits used to group organisms
DICHOTOMOUS KEY
• Dichotomous keys are used to identify organisms
• Consist of a series of questions
• Each question has two possible answers
• Based on the answer, you will be directed to the next question or
given the name of the organism
DICHOTOMOUS KEY
1. Sex female
Sex male
---------------------------------2
---------------------------------5
2. Hair color red -----------------------------Sally
Not red
---------------------------------3
3. Hair blond
Hair black
-----------------------------Julie
---------------------------------4
4. Glasses
No glasses
----------------------Deanna
--------------------------Leslie
5. High-tops
------------------------Joseph
not high-tops--------------------------------6
6. Hair blond
Hair brown
-----------------------Michael
--------------------------David
•Who is the male student
with brown hair wearing
cowboy boots?
•Start at #1: because he is
male, we need to go to # 5
•#5: his shoes are not hightops, go to #6
•#6: brown hair would lead
us to the name David
DICHOTOMOUS KEY
1. Sex female
Sex male
---------------------------------2
---------------------------------5
2. Hair color red -----------------------------Sally
Not red
---------------------------------3
3. Hair blond
Hair black
-----------------------------Julie
---------------------------------4
4. Glasses
No glasses
----------------------Deanna
--------------------------Leslie
5. High-tops
------------------------Joseph
not high-tops--------------------------------6
6. Hair blond
Hair brown
-----------------------Michael
--------------------------David
• Imagine that you meet a
blond male member of this
class wearing sandals. Who is
it?
• Imagine that his girl friend
has black hair but doesn't
wear glasses. Who is he
dating?
BIODIVERSITY
• Characters used to differentiate Domains and Kingdoms
• Type of cell
• Prokaryotic cells lack a nucleus, are very small, and are simple
• Domains Archaea and Bacteria
• Eukaryotic cells have a nucleus, tend to be larger, and are complex with
multiple organelles and cellular structures
• Domain Eukarya
• Presence or absence of a cell wall
• Material used to build the cell wall
• Uni- or multi- cellular
BIODIVERSITY
• Characters used to differentiate Domains and Kingdoms
• Nutrition (how they acquire energy)
• Autotroph or heterotroph
• Motility
• Can they move on their own
• What method do they use for movement
BIODIVERSITY
• Characters used to differentiate Domains and Kingdoms
• Mode of reproduction
• Sexual, asexual, both
• Life cycle
ARCHAEBACTERIA
• Domain Archae: Kingdom Archaebacteria
• Prokaryotic cells with a cell wall (built with pseudomurine or other)
• Microscopic uni-cellular organisms
• Many are autotrophs
• chemosynthesis and some forms of photosynthesis
• Those that can move use flagella
• Reproduce asexually using prokaryotic fission
ARCHAEBACTERIA
• Classification is based on
• Extreme habitats
• Halophiles
• Thermophiles
• Physiology
• Energy source
Two types of archaebacteria from a hydrothermal vent
BACTERIA
• Domain Bacteria: Kingdom Bacteria
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Prokaryotic cells with a cell wall (built with peptidoglycan)
Microscopic uni-cellular organisms
Diverse forms of acquiring energy
Those that can move use flagella mostly
Reproduce asexually using prokaryotic fission
BACTERIA
• Classification is based on
• Form of nutrition
• Autotroph
• Heterotroph
• Habitat
• Shape
• Coccus
• Bacillus
• Spirillium
BACTERIA
• Classification is based on
• Gram stain
• A staining method that results in two different colors depending on the
thickness of the bacteria’s cell wall
• Thick = Purple (called Gram+)
• Thin = Pink (called Gram-)
PROTISTA
• Domain Eukarya: Kingdom Protista
• Eukaryotic cells
• Some protists have cell walls (constructed with a
variety of molecules)
• They do not represent a monophylogenetic
group
• Taxonomy is changing
• All of Domain Eukarya can be divided into six
supergroups containing all the protists, animals,
plants, and fungi
PROTISTA
• Most are microscopic and uni-cellular
• Even though unseen, they play a significant role in life
• Photosynthesis
• Diatoms
• Green, red, and brown algae
• Diseases
• Trypanosomes cause African Sleeping Sickness, Chagas Disease, and
Leishmaniasis
• Plasmodium causes malaria
PROTISTA
• Most are microscopic and uni-cellular
• Even though unseen, they play a significant role in life
• Pond life
• Paramecium
• Commercial use
• Diatomaceous earth
• Toothpaste, reflective paint
• Carrageenan
• Gelling, thickening, stabilizing
• Agar
PLANTAE
• Domain Eukarya: Kingdom Plantae
• Eukaryotic cells
• cell walls constructed with cellulose
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Plants are multi-cellular and macroscopic
Photosynthetic autotrophs
Non-motile
Reproduce sexually
• Form spores or seeds
PLANTAE
• Classification is based on
• Absence or presence of
• Vascular tissues
• Conduct water (xylem) and
photosynthesized sugars
(phloem) through the plant
• Seeds
• Flowers and fruit
PLANTAE
• Taxa of the Plantae
• Bryophytes
• Mosses: simple small plants
• No vascular tissue, seeds, or flowers
PLANTAE
• Taxa of the Plantae
• Ferns
• Have vascular tissue
• No seeds or flowers
PLANTAE
• Taxa of the Plantae
• Gymnosperms (evergreen, cone bearing)
• Have vascular tissue and seeds (develop in cones)
• No flowers or fruit
PLANTAE
• Taxa of the Plantae
• Angiosperms (flowering plants)
• Have vascular tissue, seeds, and flowers and fruit
FUNGI
• Domain Eukarya: Kingdom Fungi
• Eukaryotic cells
• cell walls constructed with chitin
• Some fungi are microscopic but most are larger
• Most are multicelled
• Yeasts are uni-cellular
• Heterotrophs
• Non-motile
• Reproduce sexually and asexually
• Release spores following reproduction
FUNGI
• Important impacts of fungi
• Disease
• Mold
• Mycoses
• Ring worm
• Coccidiodomycosis
• Histoplasmosis
• Ecosystems
• Decomposition
• Lichens (fungus + algae)
• Food
• Yeast (bread, fermentation)
• Mushrooms
ANIMALIA
• Domain Eukarya: Kingdom Animalia
• Eukaryotic cells
• No cell walls
• Range in size from microscopic rotifers up to the blue whale
• All are multicellular
• Heterotrophs
• Movement based on contractile tissues (muscles) and a skeleton
• Reproduce sexually
• Form ova and sperm for reproduction
• A few species can reproduce asexually
ANIMALIA
• Classification is based on
• Level of development
• tissues, organs, organ systems
• Symmetry
• Type of skeleton
• Several other criteria
ANIMALIA
• Taxa of animalia
• Sponges
• Simplest and least complex
• Cnidarians
• Jelly fish, anemones
• Flat worms
• Tape worms
• Round worms
• Hook worms, filarial worms, ascaris
• Segmented worms
• Earthworm
ANIMALIA
• Taxa of animalia
• Mollusca
• Clams, snails, squid
• Arthropoda
• Spiders, crustaceans, insects
• Echinodermata
• Sea Stars, Sea Urchins
• Chordata
• Vertebrates
• Fish, amphibians, reptiles, birds, and mammals
QUESTIONS
• Archaebacteria
Chitin cell walls
• Bacteria
Photosynthetic
• Protista
Peptidoglycan cell walls
• Plantae
Extreme habitats
• Fungi
No cell walls
• Animalia
Includes plasmodium which causes malaria
SUMMARY
• Classification
• Nomenclature
• Taxonomy
• Dichotomous keys
• Cladograms
• Biodiversity
• Kingdoms