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Classification

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Classification This is Panorpa japonica. Commonly known as the scorpion fly. Developing the scientific naming system Binomial Nomenclature. Before Carolus Linnaeus ... – PowerPoint PPT presentation

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Title: Classification


1
Classification
This is Panorpa japonica. Commonly known as the
scorpion fly.
2
Developing the scientific naming system Binomial
Nomenclature.
  • Before Carolus Linnaeus introduced his scientific
    naming system, naturalists named newly discovered
    organisms however they wanted.
  • Because they had no agreed-upon way to name
    living thingsit was difficult for naturalists to
    talk about their findings with one another.

3
Carolus Linnaeus
  • Swedish botanist and doctor
  • Got his medical degree in 6 days and specialized
    in the treatment of syphilis.
  • Created the classification system and binomial
    nomenclature.
  • http//cmapspublic3.ihmc.us/rid1JHS4QF2G-PKSLMW-5
    1M/loganl20biology20semester20220c20map.cmap

4
Binomial Nomenclature
  • Binomial nomenclature is a system that gives each
    species a two-part scientific name using Latin
    words.
  • The first part of the name is the genus.
  • A genus includes one or more physically similar
    species that are thought to be closely related.
  • Genus names are always capitalized.
  • The second part of the name is the species.
  • It can refer to a trait of the species, the
    scientist who first described it, or its native
    location.
  • It is always lowercase.

5
Taxonomy
  • Taxonomy is the science of naming and classifying
    organisms.
  • Taxonomy gave scientists a standard way to refer
    to species and organize the diversity of living
    things.

6
Linnaeus classification system has seven levels
  • From the most general to the most specific
  • Kingdom
  • Phylum (Division for plants and fungi)
  • Class
  • Order
  • Family
  • Genus
  • Species.
  • The Linnaean system is a nested hierarchy.
  • This means that if gray wolves are in the same
    genus, Canis, as dogs and coyotes, they are also
    in the same family, order, class, phylum, and
    kingdom.

7
Cladistics
  • The most common method used to make evolutionary
    trees is called cladistics.
  • Cladistics is classification based on common
    ancestry.
  • The goal of cladistics is to places species in
    the order in which they descended from a common
    ancestor.
  • A cladogram is an evolutionary tree that proposes
    how species may be related to each other through
    common ancestors.

8
Derived Characters
  • The traits that can be used to figure out
    evolutionary relationships among a group of
    species are those that are shared by some species
    but are not present in others.
  • These are derived characters.
  • Cladograms are made by figuring out which derived
    characters are shared by which species.
  • The more closely a related species are, the more
    derived characters they will share.
  • A group of species that shares no derived
    characters with the other groups being studied is
    called an outgroup.

Derived Characters Organisms that branch off
after a hash mark share the derived character
represented by the hash mark. A bony skeleton is
a derived character. Sharks do not have this
derived character.
9
Interpreting a Cladogram
  • Derived Characters
  • Groups of species are placed in order by the
    derived characters that have added up in their
    lineage over time.
  • This order is hypothesized to be the order in
    which they descended from their common ancestor.
  • Derived characters are shown as hash marks
    between the branches of a cladogram.
  • All species above a hash mark share the derived
    character it represents.

Derived Characters
10
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11
Interpreting a Cladogram
  • Nodes
  • Each place where a branch splits is called a
    node.
  • Nodes represent the most recent common ancestor
    shared by a clade.
  • Identifying Clades
  • You can identify clades by using the snip rule.
  • Whenever you snip a branch under a node, a
    clade falls off.
  • A clade is a group of organisms that share
    certain traits derived from a common ancestor.

Nodes In a cladogram, a node is the intersection
of two branches. This node represents the most
recent common ancestor shared by the entire
mammalian clade.
Clade A clade is a group of organisms that share
certain traits derived from a common ancestor.
12
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13
The Linnaean classification system has
limitations.
  • The Linnaean system focuses on physical
    similarities alone.
  • Physical similarities between two organisms are
    not always a result of species being closely
    related. (convergent evolution)
  • Today, scientists use genetic research to help
    classify organisms.
  • Genetic similarities between two organisms are
    more likely than physical similarities to be due
    to a common ancestor.
  • EX. Giant panda and raccoon. (not related)
  • EX. Red panda and raccoon. (related)

14
Phylogeny
  • The evolutionary history for a group of species
    is called phylogeny.
  • To classify species according to how they are
    related, scientists must look at more than just
    physical traits.
  • They use living species, the fossil record, and
    molecular data.
  • Phylogenies can be shown as branching tree
    diagrams.
  • They are similar to family trees.
  • The branches of an evolutionary tree show how
    different groups of species are related to each
    other.

15
Molecular evidence reveals species relatedness.
  • An evolutionary tree is always a work in process.
  • Hormones, proteins, and genes are all used to
    help learn about evolutionary relationships.
  • DNA is considered to be the last word when
    figuring out how related two species are to each
    other.
  • The more similar to each other the genes of two
    species are, the more closely related the species
    are likely to be.

Bonobo
Chimpanzee
16
Molecular Clocks
  • Molecular clocks are models that use mutation
    rates to measure evolutionary time.
  • Mutations are nucleotide substitutions in DNA,
    some of which cause amino acid substitutions in
    proteins.
  • These mutations tend to add up at a constant rate
    for a group of related species.
  • The more time that has passed since two species
    have diverged from a common ancestor, the more
    mutations will have built up in each lineage, and
    the more different the two species will be at the
    molecular level.

17
Linking molecular data with real time.
  • Scientists must find links between molecular data
    and real time.
  • A geologic event that is known to have separated
    the species scientists are studying, allows
    scientists to give a real date to the rate of
    mutation.
  • For example Scientists know that the marsupials
    of Australia and those of South America diverged
    about 200 million years ago, when these two
    continents split.
  • A link can also come from fossil evidence.
  • Molecular data can be compared to the first
    appearance of each type of organism in the fossil
    record.

South American Monito del MonteMonkey of the
Mountains. A marsupial.
Austrailian bandicoot. A marsupial.
18
Mitochondrial DNA (mtDNA)
  • Mitochondrial DNA is found only in mitochrondria.
  • The mutation rate of mtDNA is about ten times
    faster than that of nuclear DNA, which makes
    mtDNA a good molecular clock.
  • mtDNA is always inherited from the mother.
  • mtDNA from sperm cells is lost after
    fertilization.
  • mtDNA is passed down unshuffled through many
    generations.
  • Mutations in mtDNA have been used to study the
    migration routes of humans over the past 200,000
    years.

19
Ribosomal RNA (rRNA)
  • Ribosomal RNA is found only in the ribosomes of
    cells.
  • rRNA is useful for studying distantly related
    species.
  • rRNA accumulates mutations VERY slowly.
  • Over long periods of geologic time, mutations
    that do build up in the rRNA of different
    lineages are relatively clear and can be compared.

20
Classification is always a work in progress.
  • 1753two kingdoms
  • Animalia and Plantae
  • 1866three kingdoms
  • Animalia, Plantae, Protista
  • 1938four kingdoms
  • Animalia, Plantae, Protista, Monera
  • 1959five kingdoms
  • Animalia, Plantae, Protista, Monera, Fungi
  • 1977six kingdoms
  • Animalia, Plantae, Protista, Archaea, Bacteria,
    Fungi

This is wrong! ?
21
The Three Domains
  • Bacteria
  • Single-celled prokaryotes.
  • Largest groups of organisms on Earth.
  • There are more bacteria in your mouth than there
    are people that have ever lived!
  • Archaea
  • Single-celled prokaryotes.
  • Cell walls are chemically different from
    bacteriaallows achaea to live in extreme
    environments.
  • Archaea are found in deep sea vents, hot geysers,
    Antarctic waters, salt lakes, and in the middle
    of volcanoes.
  • Eukarya
  • All organisms with eukaryotic cells.
  • May be single-celled, colonial, or multicellular.
  • Includes the kingdoms Protista, Plantae, Fungi,
    and Animalia.

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23
Dichotomous Keys
  • Dichotomous keys are used to identify objects or
    organisms that have already been described by
    another scientist.
  • A dichotomous key is made up of paired
    statements. (di two)
  • Each object must fit into one category or the
    other, but not both.

24
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