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Title: Lesson Overview


1
Lesson Overview
  • 20.2 Prokaryotes

2
THINK ABOUT IT
  • Imagine living all your life as a member of what
    you believe is the only family on your street.
    Then, one morning, you open the front door and
    discover houses and neighbors all around you.
  • Where did all the people come from? What if the
    answer turned out to be that they had always been
    thereyou just hadnt seen them? How would your
    view of the world change?

3
THINK ABOUT IT
  • When the microscope was first invented, we
    humans had just such a shock. Far from being
    alone, we share every corner of our world with
    microorganisms. Even a seemingly clean toothbrush
    contains a film of bacteria on its bristles!

4
Classifying Prokaryotes
  • How are prokaryotes classified?

5
Classifying Prokaryotes
  • How are prokaryotes classified?
  • Prokaryotes are classified as Bacteria or
    Archaeatwo of the three
  • domains of life.

6
Classifying Prokaryotes
  • The smallest and most abundant microorganisms on
    Earth are prokaryotesunicellular organisms that
    lack a nucleus.
  • Prokaryotes have DNA, like all other cells, but
    their DNA is not found in a membrane-bound
    nuclear envelope as it is in eukaryotes.
    Prokaryote DNA is located in the cytoplasm.
  • A bacterium such as E. coli has the basic
    structure typical of most prokaryotes.

7
Classifying Prokaryotes
  • Recently, biologists have divided prokaryotes
    into two very distinct groups Bacteria and
    Archaea.
  • These groups are very different from each other
    therefore, biologists now consider each group of
    prokaryotes as a separate domain. Eukaryotes are
    the third domain.

8
Bacteria
  • The larger of the two domains of prokaryotes is
    the Bacteria.
  • Bacteria include a wide range of organisms with
    lifestyles so different that biologists do not
    agree exactly how many phyla are needed to
    classify this group.

9
Bacteria
  • Bacteria live almost everywherein fresh water,
    in salt water, on land, and on and within the
    bodies of humans and other eukaryotes.
  • Escherichia coli, a typical bacterium that lives
    in human intestines, is shown.

10
Bacteria
  • Bacteria are usually surrounded by a cell wall
    that protects the cell from injury and determines
    its shape.
  • The cell walls of bacteria contain
    peptidoglycana polymer of sugars and amino acids
    that surrounds the cell membrane.
  • Some bacteria, such as E. coli, have a second
    membrane outside the peptidoglycan wall that
    makes the cell especially resistant to damage.

11
Bacteria
  • In addition, some prokaryotes have flagella that
    they use for movement, or pili, which in E. coli
    serve mainly to anchor the bacterium to a surface
    or to other bacteria.

12
Archaea
  • Under a microscope, archaea look very similar to
    bacteria. Both are equally small, lack nuclei,
    and have cell walls, but there are important
    differences.
  • The walls of archaea lack peptidoglycan, and
    their membranes contain different lipids.
  • The DNA sequences of key archaea genes are more
    like those of eukaryotes than those of bacteria.
  • Based on these observations, scientists have
    concluded that archaea and eukaryotes are related
    more closely to each other than to bacteria.

13
Archaea
  • Many archaea live in extremely harsh
    environments.
  • One group of archaea produce methane gas and
    live in environments with little or no oxygen,
    such as thick mud and the digestive tracts of
    animals.
  • Other archaea live in extremely salty
    environments, such as Utahs Great Salt Lake, or
    in hot springs where temperatures approach the
    boiling point of water.

14
Structure and Function
  • How do prokaryotes vary in their structure and
    function?

15
Structure and Function
  • How do prokaryotes vary in their structure and
    function?
  • Prokaryotes vary in their size and shape, in the
    way they move, and in the
  • way they obtain and release energy.

16
Size, Shape, and Movement
  • Prokaryotes range in size from 1 to 5
    micrometers, making them much smaller than most
    eukaryotic cells. Prokaryotes come in a variety
    of shapes.
  • Rod-shaped prokaryotes are called bacilli.
  • Spherical prokaryotes are called cocci.
  • Spiral and corkscrew-shaped prokaryotes are
    called spirilla.

17
Size, Shape, and Movement
  • Prokaryotes can also be distinguished by whether
    they move and how they move.
  • Some prokaryotes do not move at all. Others are
    propelled by flagella. Some glide slowly along a
    layer of slimelike material they secrete.

18
Nutrition and Metabolism
  • Prokaryotes need a supply of chemical energy,
    which they store in the form of fuel molecules
    such as sugars.
  • Energy is released from these fuel molecules
    during cellular respiration, fermentation, or
    both.

19
Nutrition and Metabolism
  • Prokaryotes vary in the ways they obtain energy
    and the ways they release it.
  • Looking at the two tables on the following
    slides, notice that some species are able to
    change their method of energy capture or release
    depending on the conditions of their environment.

20
Nutrition and Metabolism Energy Capture
21
Nutrition and Metabolism Energy Release
22
Growth, Reproduction, and Recombination
  • When a prokaryote has grown so that it has
    nearly doubled in size, it replicates its DNA and
    divides in half, producing two identical cells.
    This type of reproduction is known as binary
    fission.

23
Growth, Reproduction, and Recombination
  • Because binary fission does not involve the
    exchange or recombination of genetic information,
    it is an asexual form of reproduction.
  • When conditions are favorable, prokaryotes can
    grow and divide at astonishing ratessome as
    often as once every 20 minutes!

24
Growth, Reproduction, and Recombination
  • When growth conditions become unfavorable, many
    prokaryotic cells form an endosporea thick
    internal wall that encloses the DNA and a portion
    of the cytoplasm.
  • Endospores can remain dormant for months or even
    years.

25
Growth, Reproduction, and Recombination
  • The ability to form endospores makes it possible
    for some prokaryotes to survive very harsh
    conditions. The bacterium Bacillus anthracis,
    which causes the disease anthrax, is one such
    bacterium.

26
Mutation
  • Mutations are one of the main ways prokaryotes
    evolve.
  • Mutations are random changes in DNA that occur
    in all organisms.
  • In prokaryotes, mutations are inherited by
    daughter cells produced by binary fission.

27
Conjugation
  • Many prokaryotes exchange genetic information by
    a process called conjugation.
  • During conjugation, a hollow bridge forms
    between two bacterial cells, and genetic
    material, usually in the form of a plasmid, moves
    from one cell to the other.

28
Conjugation
  • Many plasmids carry genes that enable bacteria
    to survive in new environments or to resist
    antibiotics that might otherwise prove fatal.
  • This transfer of genetic information increases
    genetic diversity in populations of prokaryotes.

29
The Importance of Prokaryotes
  • What roles do prokaryotes play in the living
    world?

30
The Importance of Prokaryotes
  • What roles do prokaryotes play in the living
    world?
  • Prokaryotes are essential in maintaining every
    aspect of the ecological
  • balance of the living world. In addition, some
    species have specific uses in
  • human industry.

31
Decomposers
  • Bacteria called actinomycetes are present in
    soil and in rotting plant material such as fallen
    logs, where they decompose complex organic
    molecules into simpler molecules.

32
Decomposers
  • By decomposing dead organisms, prokaryotes,
    supply raw materials and thus help to maintain
    equilibrium in the environment.
  • Bacterial decomposers are also essential to
    industrial sewage treatment, helping to produce
    purified water and chemicals that can be used as
    fertilizers.

33
Producers
  • Cyanobacteria in the genus Anabaena form
    filamentous chains in ponds and other aquatic
    environments, where they perform photosynthesis.

34
Producers
  • Photosynthetic prokaryotes are among the most
    important producers on the planet.
  • Food chains everywhere are dependent upon
    prokaryotes as producers of food and biomass.

35
Nitrogen Fixers
  • All organisms need nitrogen to make proteins and
    other molecules.
  • Nitrogen gas (N2) makes up 80 percent of Earths
    atmosphere, but only a few kinds of organismsall
    of them prokaryotescan convert N2 into useful
    forms.
  • The process of nitrogen fixation converts
    nitrogen gas into ammonia (NH3). Ammonia can then
    be converted to nitrates that plants use, or
    attached to amino acids that all organisms use.
  • Nitrogen-fixing bacteria and archaea provide 90
    percent of the nitrogen used by other organisms.

36
Nitrogen Fixers
  • Some plants have symbiotic relationships with
    nitrogen-fixing prokaryotes.
  • The bacterium Rhizobium grows in nodules, or
    knobs, on the roots of legume plants such as
    soybean.
  • The Rhizobium bacteria within these nodules
    convert nitrogen in the air into the nitrogen
    compounds essential for plant growth.

37
Nitrogen Fixers
  • The Rhizobium bacteria often live symbiotically
    within nodules attached to roots of legumes, such
    as clover, where they convert atmospheric
    nitrogen into a form that is useable by plants.

38
Human Uses of Prokaryotes
  • Prokaryotes, especially bacteria, are used in
    the production of a wide variety of foods and
    other commercial products.
  • Yogurt is produced by the bacterium
    Lactobacillus.
  • Some bacteria can digest petroleum and remove
    human-made waste products and poisons from water.
  • Other bacteria are used to synthesize drugs and
    chemicals through the techniques of genetic
    engineering.
  • Bacteria and archaea adapted to extreme
    environments may be a rich source of heat-stable
    enzymes that can be used in medicine, food
    production, and industrial chemistry.
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