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Functional Anatomy of the Prokaryotic Cell

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Title: Functional Anatomy of the Prokaryotic Cell


1
Functional Anatomy of the Prokaryotic Cell
  • Prokaryote means, before the nucleus.
    Prokaryotic cells are simpler cells than
    eukaryotes, but they are still able to carry on
    life processes.

2
Basic Characteristics of prokaryotes
  • DNA in a prokaryote is not membrane bound. In
    other words, there is no nucleus.
  • Unlike eukaryotes, which generally have multiple
    linear chromosomes, prokaryotes have one circular
    chromosome.
  • Prokaryotes do not have membrane-bound
    organelles.
  • The cell walls of prokaryotes almost always
    contain structure called peptidoglycan.
  • Prokaryotes divide by binary fission.

3
Structures External to Cell Wall
  • Prokaryotes have three different types of
    appendages that Prokaryotes can have.
  • 1. Flagella for motility
  • 2. Fimbriae for attachment
  • 3. Pili for DNA transfer
  • Prokaryotes use only flagella for motility.
    However, keep in mind that not all prokaryotes
    are motile.

4
  • Flagella can be arranged 4 different ways in
    Prokaryotes.
  • 1. Monotrichous, meaning single polar flagellum.
  • 2. Amphitrichous, meaning tuft of flagella at
    each end of cell
  • 3. Lophotrichous, meaning two or more flagella
    at one pole (or end of the cell)
  • 4. Peritrichous, meaning the flagella are
    distributed over entire cell, much like cilia
    would be on a eukaryotic cell.
  • Flagella in prokaryotes move in a circular motion
    like a propellar instead of the whip like motion
    used by eukaryotic flagella.

5
  • Motility in Prokaryotes consists of runs and
    tumbles (See Fig. 4.5 in your textbook for an
    explanation of this concept.)
  • Motility enables the microbe to move towards
    favorable conditions or away from unfavorable
    conditions.
  • Dont be fooled though. Microbes are not
    thinking entities. They move as a result of
    chemical messages that the cell receives from the
    environment.
  • Spirochetes, a particular shape of bacteria, us a
    periplasmic flagella for motility.
  • It is anchored at one end of the cell and
    rotates to produce propelling motion similar to a
    cork screw or winding telephone cord. Imagine
    taking a telephone cord and winding it until it
    cant wind any more. When you let it go, it
    would rapidly unwind and move in many directions.
    This is similar to how the periplasmic flagellum
    works.

6
  • Fimbriae are hair-like appendages used for
    attachment. There are generally many of them
    that surround the cell.
  • Again, not all prokaryotes have fimbriae.
  • Neisseria gonorrhoeae uses fimbriae to colonize
    mucous membranes. It is the organism responsible
    for gonorrhoea.
  • Pili (sometimes fimbriae and pili used
    interchangeably in some textbooks)
  • Pili are usually longer than fimbriae and number
    only 1 or 2 per cell.
  • Pili are long hollow tubes that can attach one
    cell to another for a brief period of time.
  • Join bacterial cells in preparation to transfer
    DNA from one cell to another (also referred to as
    sex pili)
  • The Pilus is the actual tube through which the
    DNA is transferred.

7
  • Like in eukaryotes, prokaryotes can have a
    glycocalyx. Again the glycocalyx is a sticky
    substance that surrounds the cells and is used
    for attachment.
  • For example, streptococci that coat your teeth
    adhere to the teeth using the glycocalyx.
  • There are two forms the glycocalyx can take.
  • 1.Capsule
  • Slime layer
  • A capsule is a sugar coat that is thick and gummy
    that surrounds the cell. A capsule is generally
    an indicator of virulence in bacteria and aids in
    attachment and colonization of the host.
  • A slime layer is a loose shield around the
    bacteria that helps prevent water and nutrient
    loss. Slime layers also help form biofilms
    (layers of bacteria that are impenetrable by
    antibiotics and other chemicals).

8
Cell Wall
  • Almost all organisms have cell walls
  • (Mycobacteria is an exception)
  • The function of the cell wall in prokaryotes is
    to prevent the cell from rupturing when the
    pressure inside cell is greater than pressure
    outside cell.
  • The cell wall is composed of 2 main molecules
  • N-acetylmuramic acid (NAM)
  • N-acetylglucosamine (NAM)
  • Also known as peptidoglycan.

9
Cell Wall Cont.
  • Many disease causing bacteria can be grouped into
    one of two categories based on their cell wall
    structure.
  • These two groups are called gram positive (G)
    and gram negative (G-).
  • G bacteria have a very thick and rigid cell
    wall it is composed of a very thick layer of
    peptidoglycan
  • Peptidoglycan is made up of repeating units of
    NAG and NAM bound together and layered on top of
    each other. (See fig.4.13 b)
  • G- bacteria have a more complex cell wall
    structure. It is composed of an outer memb.
    (lipid bylayer) that contains LPS
    (lipopolysaccharide) on the outside of the
    outermembrane and phospholipids on the inside of
    the outer membrane.
  • Next is a thin layer of peptidoglycan that is
    loosely attached to the inside of the
    outermembrane.
  • Surrounding the peptidoglycan on the top and
    bottom is the periplasmic space
  • See fig. 4.14 (We will revisit this concept over
    and over throughout this class so make sure you
    understand it.)

10
Structures Internal to Cell Wall
  • Cell Membrane (cytoplasmic memb)
  • Encloses the cytoplasm of cell. Like eukaryotes,
    the cytoplasm contains a lot of water, unlike
    eukaryotes it does not have microtubules or
    microfilaments.
  • It is a typical phospholipid bilayer. Therefore,
    what is the charge on this membrane?
  • It also contains proteins like those discussed
    with eukaryotes. Keep in mind though that the
    protein structure is different between eukaryotes
    and prokaryotes. Thats an important concept
    when talking about drug treatments for disease.
  • Fluid Mosaic Model is what we use to describe the
    cell membrane.
  • It state that the membrane is vicous or fluid.
    It allows the proteins within the membrane to
    move throughout the phospholipids freely.
  • The function of the cell membrane is to
    selectively allow materials such as nutrients and
    wastes to enter and exit.
  • The cell membrane is also site of cellular
    respiration.

11
Structures Internal to Cell Wall
  • Cytoplasm substance w/in cell membrane.
  • It is 80 water.
  • It contains the nuclear area (remember there are
    no membrane bound organelles inside a prokaryotic
    cell).
  • It contains ribosomes.
  • It contains inclusions

12
Structures Internal to Cell Wall
  • Nuclear area
  • The nuclear area contains the single circular
    chromosome found in prokaryotes.
  • Sometimes plasmids are also found in the nuclear
    area.
  • Plasmids are small, circular pieces of DNA that
    contain extra genes that the cell can use.
  • Sometimes they carry genes for antibiotic
    resistance or for toxins
  • They are also used very frequently for genetic
    engineering because they are easily manipulated
    and can be easily moved into a cell.
  • Ribosomes
  • Ribosomes in prokaryotes are free.
  • Like ribosomes in eukaryotes, they are the site
    for protein synthesis
  • There is a difference in the structure and mass
    of the ribosomes in eukaryotes and prokaryotes.
    This is important to know because it helps to
    treat bacterial infections.

13
Structures Internal to Cell Wall
  • Inclusions
  • Storage for reserve nutrients
  • Polysaccharide granules store glycogen and
    starch
  • Lipid inclusions
  • Sulfur granules
  • Carboxysomes store enzymes for carbon fixation
    from carbon dioxide
  • Gas vacuoles control buoyancy to receive
    sufficient oxygen, light and nutrients
  • Magnetosomes store iron oxide, act like magnet
    to reach attachment sites

14
Endospores
  • Some bacteria, such as Bacillus and Clostridium,
    form resting cells called endospores upon
    depletion of nutrients in the environment.
  • Endospores are essentially highly durable
    dehydrated cells, similar to a plant seed. It
    contains all the genetic information of the
    original cell and will form a living cell again
    once the environmental conditions are right.
  • Endospores are formed inside the cell and then
    released into the environment when the cell dies.
  • Upon release, endospores can survive extreme
    heat, lack of water, exposure to many toxic
    chemicals, and radiation.
  • 25 million year old endospores trapped in amber
    germinated when placed in nutrient media.

15
Endospores
  • Sporulation is the process of endospore
    formation.
  • Endospores return to a vegetative state (living
    cell) by a process called germination.
  • Sporulation does not increase the number of cells
    but rather preserves the genetic information of
    the parent cell until conditions are right for it
    to grow again.
  • Endospores are important to the food industry.
    They are can be responsible for food
    contamination.
  • Endospores can survive boiling water for several
    hours
  • Endospores can germinate and produce toxins when
    conditions are right.
  • For example, botulism is caused by an endspore
    forming bacteria, Clostridium botulinum. This
    organism grows in environments without oxygen.
    So during the canning process if endospores are
    introduced to the food and correct cooking
    temperatures and times are not observed the
    endospores can survive. Once the cans or bottles
    are sealed an oxygenless, or anaerobic
    environment is created. The endospore can now
    germinate and form toxins. The toxins are
    responsible for the symptoms and illness caused
    in botulism.

16
Shape and Arrangement of Bacterial Cells
  • Bacterial cells come in all kinds of shapes and
    sizes and arrangements.
  • Coccus, single ball shaped cell (cocci, many ball
    shaped cells)
  • Diplococci, two ball shaped cells connected
    together.
  • Streptococci, chains of ball shaped cells.
  • Tetrads, four ball shaped cells bound together.
  • Sarcinae, groups of eight ball shaped cells
    connected together
  • Staphylococci, balled shaped bacteria connected
    together in what look like grape clusters

17
  • Bacillus (bacilli) is rod shaped bacteria
  • Diplobacilli, two rods connected together.
  • Streptobacilli, chains of rods connected end to
    end.
  • Coccobacilli, short fat rods that look similar to
    cocci.
  • (Bacillus has to meanings. Bacillus, the genus
    name of bacteria and bacillus, the cellular shape
    of a bacterium.)
  • Other shapes
  • Vibrio, comma shape.
  • Spirilla, spirochetes and others. See figure
    4.22 for great diagrams of each shape.

18
Taxonomy
  • A new classification system now divides all life
    into three domains instead of two.
  • This classification system is based on the
    phylogeny of each group of organisms. Phylogeny
    is the evolutionary history of a group of
    organisms. In other words, how are they related?
  • New Classification system consists of the 3
    Domains
  • 1. Eukarya animals, plants, fungi, protists
  • 2. Bacteria pathogenic, nonpathogenic,
    photoautrophic
  • 3. Archaea prokaryotic type single celled
    organism without peptidoglycan in its cell wall.
    Interestingly, archaea are more closely related
    to eukaryotes than to prokaryotes.

19
  • Archaea generally live in extreme environments
  • Methanogens (produce methane from carbon dioxide
    and hydrogen)
  • Extreme halophiles (live in high salt
    concentrations)
  • Hyperthermophiles (hot, acidic environments)
  • These are all examples of archaea.
  • The current scientific theory is that the 3
    domains arose from one single organism called the
    universal ancestor. (See fig. 1.15)
  • Classification of each organism is important
    because it provides us with valuable information,
    such as cellular shape, metabolic functions,
    growth characteristics, etc. about each one.

20
  • This is a brief review of the classification
    system used for all organisms. (I will never ask
    you to reproduce this list but it will help you
    to understand how prokaryotes are classified and
    named.)
  • Domain
  • Kingdom
  • Phylum
  • Class
  • Order
  • Family
  • Genus
  • Species
  • A Eukaryotic Species is a group of closely
    related org. that breed among themselves.
  • Dogs are a great example of this.

21
  • A Prokaryotic Species is a population of cells
    with similar characteristics (notice, they dont
    breed with each other like the eukaryotic
    species.)
  • Staphylococcus epidermidis and Staphylococcus
    aureus are cells that belong to the same genus,
    Staphylococcus but the species are different.
    That means that they might look different from
    each other when grown on a plate or they might
    make different enzymes or one might cause disease
    more frequently than the other.
  • A Prokaryotic Strain is a member of same species
    that is not exactly identical to the rest of the
    species.
  • Lets say that our Staphylococcus aureus develops
    resistance to Penicillin. It still has all of
    the same characteristics of Staph. Aureus but it
    now has an additional characteristic that sets it
    apart from the rest of the species.

22
  • Bacterial organisms are named using both Genus
    and Species names.
  • Sometimes organisms are named using the name of
    scientist who discovered the organism.
  • For examaple, Eschericia coli discovered by a
    scientist who had the last name Eschericia.
  • When writing the name of an organism it is proper
    to capitalize the genus name and italicize both
    the genus and species names. If the names are
    hand written then it is proper to underline both
    name.
  • Now your ready to complete Homework 3. Homework
    3 is due Monday, Sept. 11 by midnight.
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