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Phylogeny and
Systematics
Chapter 26
Phylogeny

Phylogeny – the evolutionary history of a species or
group of related species.

Systematics – The classification of organisms and
determination of their evolutionary relationships (using
fossils, molecules, genes...)
Systematics
Connecting Classification to Phylogeny

Linnaen System of Taxonomy

2 main characteristics


2-part name (binomial) for each species

Genus + specific epithet

Underlined or italicized

Genus is capitalized, specific epithet is not
Hierarchical Classification of species into broader and broader groups of
organisms.

First level, and most specific, is species.

Last, and most comprehensive, is domain.

All levels beyond genus are capitalized.
Category
Domestic
Cat
Bobcat
Lion
Dog
Specific
epithet
cattus
rufus
leo
familiaris
Genus
Felis
Felis
Panthera
Canis
Family
Felidae
Felidae
Felidae
Canidae
Order
Canivora
Carnivora
Carnivora
Carnivora
Class
Mammalia
Mammalia
Mammalia
Mammalia
Phylum
Chordata
Chordata
Chordata
Chordata
Kingdom
Animalia
Animalia
Animalia
Animalia
2 main objectives
of taxonomy

To sort out and identify separate species.

To order species into broader taxonomic categories.
Taxon

Taxon – The named taxonomic unit at any level

Monophyletic – consists of an ancestral species and all its descendents
(taxon=clade).

Paraphyletic – consists of an ancestral species and some but not all of its
descendents.

Polyphyletic – includes taxa with different ancestors.
Monophyletic
Polyphyletic
Paraphyletic
Phylogenetic systematics
based on cladistic analysis

Phylogenetic systematics – classification based on
evolutionary history.

Fossil Record

Anatomical Comparison

Chemical/Molecular Comparison

Cladistic Analysis evaluates information and applies it to
tree building and classification (uses common ancestry as
the primary criterion).
Phylogenetic Tree/
Cladogram
Branching diagram representing a hypothesis
on the evolutionary history of a group of
organisms.
 Branching does not indicate the ages of
particular species, it only conveys patterns of
descent.
 Location of branch points symbolize the
relative times of origin for the different taxa.
 The degree of divergence between branches
represents how different two taxa have
become since branching from a common
ancestor.

Constructing a Cladogram

Taxonomists classify species into high taxa
based on the extent of similarities in
morphology and other characteristics.

Sorting Homology from Analogy
 Homology
– likeness due to shared ancestry.
 Analogy
– similarities due to convergent
evolution, not common ancestry.
 Ex.

bat and bird wings
Convergent Evolution – similar environmental pressures and natural selection
produce similar adaptations in organisms from different evolutionary
lineages.
Constructing a Cladogram

Generally, the greater amount of homology,
the more closely related the species are.

The more complex two similar structures
are, the less likely it is to have evolved
separately or independently.
Molecular Systematics

Protein Comparison

Primary structure of protein is genetically programmed.

Similar amino acid sequence from different species
indicates the genes for those proteins evolved from a
common gene present in a shared ancestor.
Molecular Systematics

DNA Comparison
 Comparing
the genes or genomes of two species
is the most direct measure of common
inheritance from shared ancestors.
Molecular Systematics

DNA Comparison
 Comparing
the genes or genomes of two species
is the most direct measure of common
inheritance from shared ancestors.
 Paralogous
genes – result from gene
duplication, found in more than one copy in the
same genome
 Ex.
olfactory gene family in humans
 Orthologous
genes – homologous genes found in
different species because of speciation
 Ex.
cytochrome c in humans and dogs
Molecular Systematics

**99% of the genes of humans and mice are orthologous.

**50% of human genes are orthologous with genes of
yeast.
 All living organisms share many biochemical and
developmental pathways.
Molecular Systematics

Molecular Clocks

Proteins evolve at different rates, although each type of protein
evolves at a relatively constant rate over time.

This information can be used to determine the relative time of the
divergence of the modern species from the ancestral.

The estimates are consistent with fossil evidence.