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CHAPTER 27. PROKARYOTES AND THE ORIGINS OF METABOLIC DIVERSITY ... Transmitted by the rat flea to humans, it caused the bubonic plague. Helicobacter pylori ... – PowerPoint PPT presentation

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Title: Nerve activates contraction


1
CHAPTER 27 PROKARYOTES AND THE ORIGINS OF
METABOLIC DIVERSITY
Bacillus anthracis spores in lung bronchiole
E. coli on surface of human skin
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Theyre (almost) everywhere!
  • Prokaryotes were the earliest organisms on Earth
    and evolved alone for 1.5 billion years.

Vibrio cholerae - Gram-negative, facultatively
anaerobic, causes Asiatic cholera.
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Current taxonomy recognizes two prokaryotic
domains domain Bacteria and domain Archaea.
  • Domain Archae (Archaebacteria)
  • Lack peptidoglycan in c.w.
  • More than one RNA poly-ase
  • Histones assoc. with DNA.
  • Introns in some genes

Halophilic bacterium
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Domain Archae
  • Methanogens form CH4 from H2 and CO2 or
    acetate. Requires anaerobic conditions (bottom
    of pond, landfill, sewage digester)
  • Halophiles require extremes in salt (gt 10),
    contain pigment (bacteriorhodopsin) that can
    absorb light and create H gradient.
  • Thermoacidophiles found in geothermal springs
    (high heat) and low pHs.

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Alicyclobacillus spp. - an acidophilic,
thermophilic, spore forming bacterium
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Domain Bacteria (Eubacteria)
  • Contain peptidoglycan in c.w.
  • One type of RNA poly-ase.
  • Lack introns in genome.
  • Sensitive to antibiotics (streptomycin and
    chlroamphinicol)
  • Ex. Purple bacteria, free-living, enteric,
    mycoplasmas, actinomycetes (soil bacteria),
    cyanobacteria, spirochetes, chlamydias.

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Structure and Morphology
  • Most prokaryotes are unicellular some colonial
  • In nearly all prokaryotes, a cell wall maintains
    the shape of the cell, affords physical
    protection, and prevents the cell from bursting
    in a hypotonic environment.
  • The most common shapes among prokaryotes are
    spheres (cocci), rods (bacilli), and helices.

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Staphylococcus
Streptococcus
Diplococcus
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Nearly all prokaryotes have a cell wall external
to the plasma membrane
  • Most bacterial cell walls contain peptidoglycan,
    a polymer of modified sugars cross-linked by
    short polypeptides.
  • The walls of archaea lack peptidoglycan.
  • Chemistry of cell wall allows for identification
    and classification. Gram staining.

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  • Gram-positive bacteria have simpler cell walls,
    with large amounts of peptidoglycans and only one
    membrane. Stains purple.

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  • Gram-negative bacteria have more complex cell
    walls and less peptidoglycan. Have a double
    lipopolysaccharide membrane. Stains Pink.
  • An outer membrane on the cell wall contains
    lipopolysaccharides, carbohydrates bonded to
    lipids.

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  • Among pathogenic bacteria, gram-negative species
    are generally more threatening than gram-positive
    species.
  • The lipopolysaccharides on the walls are often
    toxic and the outer membrane protects the
    pathogens from the defenses of their hosts.
  • Gram-negative bacteria are commonly more
    resistant than gram-positive species to
    antibiotics because the outer membrane impedes
    entry of antibiotics.

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  • Many prokaryotes secrete another sticky
    protective layer, the capsule, outside the cell
    wall.
  • Composed of protein or polysaccharides.
  • Capsules adhere the cells to their substratum.
  • They may increase resistance to host defenses.
  • They glue together the cells of those prokaryotes
    that live as colonies.
  • i.e. R and S strains of Griffith experiment.

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  • Another way for prokaryotes to adhere to one
    another or to the substratum is by surface
    appendages called pili (or fimbriae).
  • Pili/fimbriae can fasten pathogenic bacteria to
    the mucous membranes of its host.
  • Formed from protein? Pilin
  • Sex Pili

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Many prokaryotes are motile
  • About half of all prokaryotes are capable of
    directional movement.
  • The action of flagella, scattered over the entire
    surface or concentrated at one or both ends, is
    the most common method of movement.
  • The flagella of prokaryotes differ in structure
    and function from those of eukaryotes.

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  • In a prokaryotic flagellum, chains of a globular
    protein wound in a tight spiral from a filament
    which is attached to another protein (the hook),
    and the basal apparatus.
  • Rotation of the filament is driven by the
    diffusion of protons into the cell through the
    basal apparatus after the protons have been
    actively transported by proton pumps in the
    plasma membrane.

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  • A second motility mechanism is found in
    spirochetes, helical bacteria.
  • Two or more helical filaments under
    (internalized) the cell wall are attached to a
    basal motor attached to the cell.
  • When the filaments rotate, the cell moves like a
    corkscrew. Useful in thick fluids.
  • A third mechanism occurs in cells that secrete a
    jet of slimy threads that anchors the cells to
    the substratum.
  • The cell glides along at the growing end of
    threads.

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  • In a relatively uniform environment, a
    flagellated cell may wander randomly.
  • In a heterogenous environment, many prokaryotes
    are capable of taxis, movement toward or away
    from a stimulus.
  • With chemotaxis, binding between receptor cells
    on the surface and specific substances results in
    movement toward the source (positive chemotaxis)
    or away (negative chemotaxis).
  • Other prokaryotes can detect the presence of
    light (phototaxis) or magnetic fields
    (magnetotaxis).

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Growth, reproduction and genetic exchange
Endospore
  • Binary fission Conjugation Transduction
    Transformation
  • Endospore formation. Resting structures that
    withstand high heat, radiation, desiccation,
    toxins. Allow survival for hundreds of years.
    Form during unfavorable conditions. Low in water
    content (15 vs. 90 of normal cell). Tough wall
    forms that is one of the toughest biological
    structures.

Clostridium botulinum - Causes botulism.
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Metabolic Diversity
  • Nutritional modes depend on how an organism
    obtains energy and a carbon source from the
    environment to build the organic molecules of
    cells.

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  • Photoautotrophs are photosynthetic organisms that
    harness light energy to drive the synthesis of
    organic compounds from carbon dioxide.
  • Among the photoautotrophic prokaryotes are the
    cyanobacteria.
  • Among the photosynthetic eukaryotes are plants
    and algae.

Cyanobacteria
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  • Chemoautotrophs need only CO2 as a carbon source,
    but they obtain energy by oxidizing inorganic
    substances, rather than light.
  • These substances include hydrogen sulfide (H2S),
    ammonia (NH3), and ferrous ions (Fe2) among
    others. Use these to form H gradient then ATP.
  • This nutritional mode is unique to prokaryotes.
  • Symbionts with tubeworms at hydrothermal vents

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  • Photoheterotrophs use light to generate ATP but
    obtain their carbon in organic form.
  • This mode is restricted to prokaryotes.
  • Chemoheterotrophs must consume organic molecules
    for both energy and carbon.
  • This nutritional mode is found widely in
    prokaryotes, protists, fungi, animals, and even
    some parasitic plants.

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The majority of known prokaryotes are
chemoheterotrophs.
  • These include saprobes, decomposers that absorb
    nutrients from dead organisms, and parasites,
    which absorb nutrients from the body fluids of
    living hosts.
  • Some of these organisms (such as Lactobacillus)
    have very exacting nutritional requirements,
    while others (E. coli) are less specific in their
    requirements.

Lactobacillus sp.
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  • Prokaryotes are responsible for the key steps in
    the cycling of nitrogen through ecosystems.
  • Some chemoautotrophic bacteria convert ammonium
    (NH4) to nitrite (NO2-).
  • Others denitrify nitrite or nitrate (NO3-) to
    N2, returning N2 gas to the atmosphere.
  • A diverse group of prokaryotes, including
    cyanobacteria, can use atmospheric N2 directly.
  • During nitrogen fixation, they convert N2 to
    NH4, making atmospheric nitrogen available to
    other organisms for incorporation into organic
    molecules.

Nitrosomonas spp
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  • Nitrogen fixing cyanobacteria are the most
    self-sufficient of all organisms.
  • They require only light energy, CO2, N2, water
    and some minerals to grow.

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  • The presence of oxygen has a positive impact on
    the growth of some prokaryotes and a negative
    impact on the growth of others.
  • Obligate aerobes require O2 for cellular
    respiration.
  • Facultative anerobes will use O2 if present but
    can also grow by fermentation in an anaerobic
    environment.
  • Obligate anaerobes are poisoned by O2 and use
    either fermentation or anaerobic respiration.
  • In anaerobic respiration, inorganic molecules
    other than O2 accept electrons from electron
    transport chains.

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  • Gram-negative, facultatively anaerobic, rod.
  • Transmitted by the rat flea to humans, it caused
    the bubonic plague.

Yersinia pestis
  • Gram-negative, tiny flagella at the end of the
    cell.
  • main cause of chronic superficial gastritis,
    associated with both gastric and duodenal ulcers
  • lives in the interface between the surface of
    gastric epithelial cells (the lining of the
    stomach).

Helicobacter pylori
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