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Transcript
Chapter 27A:
Bacteria and Archaea
1. Extracellular Prokaryotic Structures
2. Intracellular Prokaryotic Structures
3. Genetic Diversity Prokaryotes
1. Extracellular Prokaryotic Structures
Prokaryotic Cell Shape
cocci
bacilli
spirilla
• spherical prokaryotes are
referred to as cocci
(singular = coccus)
• rod-shaped prokaryotes
are referred to as bacilli
(singular = bacillus)
Spherical
3 µm
1 µm
1 µm
• rod-shaped cells can also
be slightly curved (vibrio)
or spiral (spirillum) or highly
coiled (spirochete)
Rod-shaped
Spiral
vibrio
spirochete
Bacterial Cell Wall Structure
(a) Gram-positive bacteria
(b) Gram-negative
bacteria
Carbohydrate portion
of lipopolysaccharide
Cell
wall
Peptidoglycan
layer
Plasma
membrane
Peptidoglycan traps crystal violet,
which masks the safranin dye.
Cell
wall
Outer
membrane
Peptidoglycan layer
Plasma membrane
Crystal violet is easily rinsed away, revealing
the red safranin dye.
Gram Staining
A Gram stain is a very common stain to distinguish 2 bacterial types:
Gram negative
1
2
3*
4
• does NOT retain crystal violet,
only the safranin
Gram-negative
bacteria
Gram positive
Gram-positive
bacteria
• retains crystal violet due to
thick peptidoglycan layer
10 µm
* key step
A Gram stain of 2 distinct Bacterial Species
Capsules
A polysaccharide or protein layer called a capsule covers
many prokaryotes.
• mediates adhesion and
the formation of biofilms
Bacterial
cell wall
• protects the cell from
dessication (drying out)
and phagocytosis (being
consumed by cells of the
immune system)
Bacterial
capsule
Tonsil
cell
200 nm
Bacterial Flagella
• consist of a basal body,
hook & filament
Flagellum
Filament
Hook
Motor
Cell wall
Plasma
membrane
Rod
Peptidoglycan
layer
20 nm
• basal body
anchors flagellum
in the membrane
and cell wall, and
rotates the hook
& filament to
propel bacterium
Fimbriae
Some prokaryotes have fimbriae (aka “pili”), which allow them
to stick to their substrate or other individuals in a colony.
Fimbriae
1 µm
Sex Pilus
Sex pili are longer than fimbriae and allow prokaryotes to
exchange DNA through a process called conjugation.
Sex pilus
1 µm
2. Intracellular Prokaryotic Structures
Endospores
Some Gram-positive bacteria form metabolically inactive endospores
which can remain viable in harsh conditions for centuries.
Endospore
• inactive, dormant cells
enclosed in a highly
resistant spore coat
Coat
• remain dormant until
conditions improve
0.3 µm
• very resistant to heating,
freezing, dessication and
damaging radiation (e.g. UV)
Infoldings of the Cell Membrane
Some prokaryotes have highly folded membranes to increase
the surface area for processes such as cellular respiration and
photosynthesis.
1 µm
0.2 µm
• such membrane infoldings
are not considered to be
true organelles such as
those found in eukaryotes
Respiratory
membrane
Thylakoid
membranes
(a) Aerobic prokaryote
(b) Photosynthetic prokaryote
Prokaryotic Chromosome
Prokaryotes typically have 1 circular DNA molecule that is
the chromosome.
• the prokaryotic chromosome is
located in a region of the cell
called the nucleoid
Plasmids
Some bacteria have 1 or more small, extrachromosomal,
non-essential circular DNA molecules called plasmids.
Chromosome
Plasmids generally contain genes
that confer some sort of advantage
for survival and reproduction:
Plasmids
• protection from toxic substances
(antibiotic resistance)
1 µm
• toxins to kill competitors, enhance
disease
• gene transfer by conjugation
3. Genetic Diversity in Prokaryotes
Sources of Genetic Diversity in Prokaryotes
3 general factors contribute to prokaryotic diversity:
MUTATION
• changes in DNA sequences
RAPID REPRODUCTION
• some prokaryotes can reproduce every 20 minutes
HORIZONTAL GENE TRANSFER
• transfer of DNA from one cell to another
Horizontal vs Vertical Gene Transfer
Vertical
• transfer to the
next generation
Horizontal (or lateral)
• transfer within the
same generation
Mechanisms of Prokaryotic Gene Transfer
Bacteria can acquire DNA (i.e., new genes) in 3 basic ways:
1)
Transformation – the uptake and retention of external
DNA molecules
2)
Conjugation – direct transfer of DNA from one bacterium
to another
• “regular” conjugation
• HFR conjugation
3) Transduction – the transfer of DNA between bacteria by a virus
Transformation
Under the right conditions, bacteria
can “take in” external DNA fragments
(or plasmids) by transformation.
• DNA binding proteins transfer external
DNA across cell wall and membrane
• recombination with the chromosomal
DNA can then occur
Bacterial Conjugation
F plasmid
Bacterial
chromosome
F+ cell
F+ cell
(donor)
Mating
bridge
F− cell
(recipient)
1 One strand of
F+ cell plasmid
DNA breaks at
arrowhead.
Bacterial
chromosome
2 Broken strand
peels off and
enters F− cell.
F+ cell
3 Donor and
recipient cells
synthesize
complementary
DNA strands.
Conjugation and transfer of an F plasmid
4 Recipient
cell is now a
recombinant
F+ cell.
Hfr Conjugation
Hfr cell
(donor)
A+
A+
A+
A−
A+
F factor
A−
F−
cell
(recipient)
1 An Hfr cell
forms a
mating bridge
with an F− cell.
A−
2 A single strand
of the F factor
breaks and
begins to move
through the
bridge.
A+
A−
3 Crossing over
can result in
exchange of
homologous
genes.
A+
Recombinant
F− bacterium
4 Enzymes
degrade and
DNA not
incorporated.
Recipient cell
is now a
recombinant
F− cell.
Conjugation and transfer of part of an Hfr bacterial chromosome,
resulting in recombination
Phage DNA
1 Phage infects bacterial
donor cell with A+ and B+
alleles.
A+ B+
Donor cell
2 Phage DNA is replicated
and proteins synthesized.
A+ B+
3 Fragment of DNA with A+
allele is packaged within
a phage capsid.
A+
4 Phage with A+ allele
infects bacterial recipient
cell.
5 Incorporation of phage
DNA creates recombinant
cell with genotype A+ B−.
Transduction
Crossing
over
A+
A− B−
Recombinant
cell
Recipient cell
A+ B−
A bacteriophage virus can
transfer DNA fragments from
one host cell to another
followed by recombination:
• requires a virus to be
packaged with bacterial
DNA “by mistake”
• infection of another cell
by such a virus facilitates
the gene transfer followed
by recombination