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AP BIOLOGY:
Chapter Twenty-Nine Outline
THE CLASSIFICATION OF ORGANISMS
Early Naming of Organisms
Necessary as a point of reference for scientific discussions
Genus (genera, pl.): basic unit of grouping
Names written in, or given Latin form
Classification specialists called systematists or taxonomists
The Polynomial System
Additional descriptive terms added to genus names to designate a species
Polynomial name: string of Latin words and phrases
Extremely long and cumbersome
Lack of uniformity caused confusion
The Binomial System
Developed by Carl Linnaeus
Derived two-part naming system from polynomials
Example: Quercus phellos and Quercus rubra fig 29.1
Convenience of shorter names secured their use by scientists
Two-part name called a binomial
Format Genus species or G. species
Genus name is capitalized and may be abbreviated by initial
Species name is not capitalized and cannot be used alone
Names established by rigid set of rules
Provide uniform means of communication
Reduce confusion as local names may describe different organisms
THE TAXONOMIC HIERARCHY
Binomial Classification System Is Hierarchal
Family: unit one step more inclusive than a genus
A single genus includes many related species
A single family includes many related genera
Family Fagaceae: oaks, beeches, chestnuts and others
Family Sciuridae: tree squirrels, marmots and others fig 29.2
Certain features can be surmised from unit associations
Taxonomic System
Kingdom, phylum, class, order, family, genus, species fig 29.3
In plants, fungi and algae phylum also called division
Comparative hierarchal descriptions of various organisms tbl 29.1
Categories may include several or only one taxon
Taxon implies set of characteristics and group of organisms
Printing conventions
Genus capitalized, species not capitalized
Both genus and species italicized or underlined
All other taxonomic unit names capitalized, but no distinctive print style
What Is a Species?
Criteria not absolute
Individuals of one species may appear quite dissimilar
Capable of hybridizing with one another
Offspring may appear different from one another
Individuals from different species do not generally hybridize
Criteria apply for organisms that regularly outcross
Different characterizations for asexually reproducing organisms
Compare morphological features
Compare ecology and distribution
How Many Species Are There?
1.4 million species currently named and described
Some groups well known: flowering plants, vertebrate animals, butterflies
More than 90% of species in these groups already named
Other groups less well known only 5% of nematode, fungi, mite species recognized
Actual number of species estimated at 10 million
6 to 7 million in tropics alone
Only 400,000 tropical species now described
Estimates apply for eukaryotes only, functionally impossible to estimate number of prokaryote species
THE HISTORY OF LIFE ON EARTH
The Six- Kingdoms of Life
Originally only two kingdoms: animals and plants
Most biologists now identify six kingdoms
Four kingdoms are eukaryotic
Animalia and Plantae are mostly multicellular
Fungi contain multicellular forms and single-celled yeasts
Fundamental differences among multicellular kingdoms
Different morphology, motility and nutrition
Each kingdom evolved from different single-celled ancestor
Protists are unicellular
Arbitrary grouping
Include algae
Archaebacteria and Eubacteria contain prokaryotic organisms
The Evolution of Prokaryotes
Most fundamental differences not between plants and animals, but between prokaryotes and eukaryotes
Prokaryotes though to be uniform group lacking membrane-bound nucleus
Molecular DNA analysis
Shows distinction between Archaebacteria and Eubacteria
Indicates first eukaryotes evolved from Archaebacteria fig 29.4
Later forms acquired mitochondria in form of symbiotic Eubacteria
Similar acquisition of chloroplasts
Evolution of Eukaryotes
Only bacteria existed on earth for 2 billion years
First appeared 1.5 billion years ago
Fungi, plants and animals are well-defined evolutionary groups
Each stems from different single-celled ancestor
Largely multicellular, derived from ancestor classified as Protista
Greater metabolic diversity between two prokaryotic groups than among all eukaryotic groups
Unicellular eukaryotes lumped together in Protista, lacking rationale to put them with fungi, plants or animals
Characteristics of the six kingdoms tbl 29.2
Origins
Almost all modern eukaryotes possess mitochondria derived from purple sulfur bacteria
Some protists acquired chloroplasts and are photosynthetic
Chloroplasts derived from symbiotic cyanobacteria
Defining characteristic of groups that possess them
Endosymbionts evolved and adjusted to new environment
Lost redundant genes, kept only those needed for survival in cell
Both contain own ribosomes, more similar to bacterial ribosomes
Manufacture own membranes
Divide independently of cell
Contain chromosomes similar to those found in bacteria
Other symbionts: basal bodies, centrioles, flagella, cilia
Multicellularity
Bacteria occur in nearly every habitat
Protists diverse in form and biochemistry fig 29.5
Multicellularity allows novel adaptations to environment
Distinct cell differentiation possible
Greater complexity of activities
True multicellularity
Occurs only in eukaryotes
Coordinates activities of individual cells
Bacteria and some protists may form colonial aggregates
Some protists exhibit simple multicellularity fig 29.6
Green algal protists were ancestors of plants
Fungi and animals arose from unicellular ancestors
Groups giving rise to these kingdoms still exist
Sexuality
Major characteristic of eukaryotes
Process is regular, results are predictable
Alternation between syngamy and meiosis
Syngamy: produces cell with two sets of chromosomes
Meiosis: produces cells with one set of chromosomes
Differs greatly from genetic exchange in bacteria
Cells of animals and plants are diploid during some part of life cycle
Few eukaryotes complete life cycle in haploid condition
Offspring of sexual eukaryotic organisms vary widely
Due to segregation during meiosis
Resulting from crossing over in meiosis
Provides raw material for evolution
Sexual organisms evolve rapidly in relation to demands of environment
Protist sexual reproduction
May only occur in times of stress
Many are haploid throughout entire life, an ancestral condition
Life cycles fig 29.7
Zygotic meiosis
Zygote is the only diploid cell
Zygote immediately undergoes meiosis
All other stages are haploid
Gametic meiosis
Gametes are only haploid cell
Gametes fuse giving rise to a zygote
Sporic meiosis: alternation of generation
Exhibited by plants
Multicellular diploid form undergoes meiosis to produce haploid spores
Spores give rise to haploid phase
Haploid form produces haploid gametes
Gametes fuse to produce diploid zygote
Viruses: A Special Case
Viruses not classified as living organisms
Viruses not included in any kingdom
Capable of replication within a cell
Machinery of host cells directed to manufacture viral material
Nucleic acid fragments derived from prokaryotes or eukaryotes
Non-living when outside of host fig 29.8
EVOLUTIONARY TAXONOMY
Should Taxonomy Reflect History?
Not an old, inactive science, but active and controversial
Defining its role in biology
Linnaean approach of classifying and naming
Darwinian approach of tracing evolutionary history
Classifying by Morphological Similarity
Observations of characteristics to distinguish and name new species
Must make subjective judgement on which characteristics are more important
Numerical taxonomy, phenetics, applies numbers to evaluation of characteristics
Use as many characteristics as possible
No additional emphasis initially prescribed to any one character
Avoids confusion associated with parallel evolution
Analogous characteristics are only small set of the whole
Homologous characteristics associated with common evolutionary descent
Subsequent applications assign weight (emphasis) to certain characteristics
Classifying by Evolutionary Relationships
Cladistic school of taxonomy at opposite end of spectrum from phenetic school
Cladistics consider only evolutionary relatedness, not morphological comparisons
Classifies organisms by historical order in which evolutionary branches arise through history of group
Employs specialized analytical methods to determine significant characters
Results in testable hypotheses
Complex comparisons requires use of computers
Both phenetics and cladistics use biochemical characteristics along with morphology
Basic object of cladistics
Ascertain characteristics that indicate common ancestry
Construct hypotheses about group's ancestral condition and derived characters
Derived characters are shared by all members of branch, but not existent before branch
Example: vascular plant cladogram (evolutionary tree)
All vascular plants have vascular tissue, others don't fig 29.9
All seed plants on same branch of vascular plant cladogram
Flowers are unique characteristic of angiosperms
Ancestral angiosperm had two cotyledons, specialized monocots have one, a derived character
Construction of accurate cladograms requires correct interpretation of features
Cladistic approach seems most appropriate to analyze evolutionary history
Cladistics shows order of descent, not extent of divergence
Taxonomy Today
Utilizes information from phenetics and cladistics
Accounts for degree of differences and evolutionary history
Example of conflicts
Birds in own class, crocodiles grouped with reptiles
Crocodiles more closely related to birds, share derived features fig 29.10
Birds retain own class due to degree of divergence from common ancestor with crocodiles
A LOOK AHEAD
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