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Domain Bacteria
Kingdom Eubacteria
Quick Review
Remember from earlier this year that there
are two broad categories of organisms:
*Prokaryotes – have No membrane
bound organelle
*Eukaryotes – have membrane bound
organelle
General Characteristics
 Prokaryotes
(No membrane-bound organelle)
 Prokaryotes have a single, naked chromosome
 Some Prokaryotes have Plasmids, circular DNA
 Unicellular (single-cell)
 Cell Walls can contain peptidoglycan, not cellulose
 Cell Membranes made of bi-layered phospholipids
 First life forms, appeared approximately 3.5 BYA
 Flagella, if present, made up of Flagellin.
Typical Prokaryote Cell Structure
Internal Structure: Bacteria have a very simple
internal structure, and no membrane-bound
organelles.
Nucleoid
 DNA in the bacterial cell is generally confined to this central region.
Ribosomes
 Ribosomes give the cytoplasm of bacteria a granular appearance in electron micrographs.
Translate the genetic message in messenger RNA into the production of proteins.
Storage granules
 Stored foods in the cytoplasm in the form of glycogen, lipids, and sugars.
Endospore
 Some bacteria, like Clostridium botulinum, form spores that are highly resistant to
drought, high temperature and other harsh environmental hazards. Once the hazard is
removed, the spore germinates to create a new population.
Capsule

Protects the bacteria cell.
Outer membrane
 Bi-layer lipid found in Gram negative bacteria.
Cell wall
 Composed of peptidoglycan (polysaccharides + protein), the cell wall maintains the overall
shape of a bacterial cell. The three primary shapes in bacteria are coccus (spherical),
bacillus (rod-shaped) and spirillum (spiral). Mycoplasma are bacteria that have no cell
wall and therefore have no definite shape.
Plasma membrane
 This is a lipid bilayer much like the cytoplasmic (plasma) membrane of other cells. There
are numerous proteins moving within or upon this layer that are primarily responsible for
transport of ions, nutrients and waste across the membrane.
Pili

These hollow, hairlike structures made of protein allow bacteria to attach to
other cells. A specialized pilus, the sex pilus, allows the transfer from one
bacterial cell to another. Pili (sing., pilus) are also called fimbriae (sing.,
fimbria).
Flagella
 The purpose of flagella (sing., flagellum) is to move the cells. Flagella are long
strands which rotate by means of a "motor" located just under the cytoplasmic
membrane. Bacteria may have one, a few, or many flagella in different positions
on the cell.
Bacteria
Escherichia coli
E. coli
Oxygen Preferences for Bacteria
Obligate
aerobes are organisms which must
have oxygen to live.
Obligate
anaerobes cannot live in the
presence of oxygen.
Facultative
anaerobes can live with or
without oxygen.
Nutrition


Autotrophs- organisms that can make their own foods.
Photosynthetic autotrophs- use light energy H20 & CO2
to make their foods.
Chemosynthetic autotrophs - use inorganic compounds like
Hydrogen sulfide and ammonia.

Heterotrophs- obtain energy by consuming organic compounds,
they cannot make their own foods.
Most bacteria are “saprobes”, they get energy by eating
dead, decaying matter; they are also called
“decomposers”
Endospores
 thick-walled
structures that are
highly resistant to
harsh environmental
conditions (high
temperature, drying,
oxygen, etc.);
generally formed only
by bacilli, and then
each cell only forms
one.
endospore
Locomotion (Methods of Movement)
Bacterial
Flagellum- lacks microtubules
Classification
Considerations
Gram-staining characteristics
Cell shapes and Groups
Methods of obtaining energy
Chemical Composition of the Cell Walls
Gram Staining
 Gram-negative
cells lack the ability to retain
the deep violet dye because they have little, if
any, peptidoglycan in their cell walls.
 Gram-positive
cells have cell walls with large
amounts of peptidoglycan which retain the
deep violet dye and gives the cell a purple
color.
Gram Negative cell
Gram Positive Cells
Pink
Purple
Bacteria Photos
E. coli
Which of these cells are
Gram +, Gram - ?
Clostridium tetani
Bacteria Photos
Staphylococcus
aureus
Neisseria
gonorrhoeae
Cell Shapes and Groups
Spherical-shaped cells
Coccus (sng) , cocci (pl)
A Group of Two is referred to as:
Diplo…….. This is diplococccus
A Cluster of cells is referred to as:
Staphylo…. This is Staphylococcus
Staph Infection
Methicillin-resistant Staphylococcus aureus
….MRSA can mutate quickly to become resistant to the
newest “last resort” antibiotics
Bacteria are smart, antibiotics are dumb.
What a slide of Typical coccus
looks like in a microscope.
A Chain of cells is referred to as:
Strepto…. This is Streptococcus
Strep Throat
Rod-shaped cells
Bacillus (sng) , Bacilli (pl)
Typical Bacillus
Bacillus
http://er1.org/docs/photos/Anthrax/bacillus%20anthracis%20-03.jpg
Typical Bacillus in a Microscope
Spiral-shaped cells
Spirillum (sng) , Spirlli (pl)
Spirochetes
Cyanobacteria
 are
photosynthetic autotrophs that produce
carbohydrates and oxygen
 tend
to cling together in filaments or colonies
 The
“heterocysts contain enzymes that allow
them to “fix” atmospheric nitrogen
Filamentous: Chain of cells
http://www.spea.indiana.edu/joneswi/e455/Anabaena.jpg
Anabaena
_ http://www.bio.mtu.edu/~jkoyadom/algae_webpage/ALGAL_IMAGES/cyanobacteria/Anabaena_jason_dbtow17 2016.jpg
Some filamentous cyanobacteria have Heterocysts:
which are Nitrogen-fixing structures
http://www.people.vcu.edu/~elhaij/IntroBioinf/Scenarios/heterocyst2.JPG
Oscillatoria
http://botit.botany.wisc.edu:16080/images/130/Bacteria/Cyanobacteria/Oscillatoria/Oscillatoria_MC.jpg
Nitrogen-fixation
Some
soil bacteria live in the ground
and take in Nitrogen from the
surroundings
The
Nitrogen is combined with oxygen
to form nitrites and nitrates…. Plants
use the nitrates and nitrites to make
proteins…. (Grow !!)
Denitrification
Some
soil bacteria break down
the nitrogen compounds and
release the nitrogen back into
the environment.
Life
would not exist as we know it
without Nitrogen-fixing and
Denitrifying bacteria.
Asexual Reproduction
 Binary
Fission – cells grow in size the split in
two…. Genetically identical
Sexual Reproduction in Bacteria
(methods of exchanging DNA)
Conjugation
Two bacteria join together and transfer portions of DNA
Transformation
DNA from the environment is simply taken in
by a bacterium
Transduction
A
virus obtains DNA from a host bacterium
Virus
Bacterium
Beneficial Uses
 Chemical
 Used
recyclers (Nitrogen Cycle)
in the dairy industry to make cheese,
yogurts and sour cream.
 Genetic
Engineering of HGH, Insulin, Etc…
 Oil spill cleanup
 Synthesis
of Vitamins in your intestines
Symbiotic Relationships
– E. coli in the intestines of
mammals aid in digestion.
 Mutualism
– some bacteria are
parasites…. They live in a host and
eventually overpopulate…. As they do
they use the host’s food, water and
eventually starve the tissues.
 Parasitism
Antibiotics
How Antibiotics Work Many Ways….
•
Antibiotics can prevent bacteria from
making new cell walls.
•
Can disrupt Protein Synthesis
* Disrupt many cell metabolic reactions
Pathogens: disease-causing agents
Escherichia coli (E. coli) – found in the
intestines of mammals…. Can be deadly if
the wrong species is eaten.
Clostridium botulinum – causes “botulism”
….. food poisoning.
Clostridium tetani – causes tetanus.
Preventing Foodborne Diseases
 1.
Keep cooked and raw foods separate.
 2.
Wash fruits and vegetables before
eating them.
 3.
Refrigerate leftovers.