Bacterial Cell structure and Function (1).ppt
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About This Presentation
all bout the cells
Slide Content
Bacterial Morphology Arrangement
Robert Hooke
(1635-1703)
English Scientist
First to use the
microscope to observe
cells
Coined the term “cell”
(1635-1703)
English Scientist
First to use the
microscope to observe
cells
Coined the term “cell”
Anton van Leeuwenhoek
1632-1723
Dutch scientist
Invented the first
compound microscope
First to observe
LIVING cells
Blood cells and
protists
1632-1723
Dutch scientist
Invented the first
compound microscope
First to observe
LIVING cells
Blood cells and
protists
Robert Brown
1773-1858
Scottish botanist
In 1831 he was the
first person to observe
the nucleus of a cell
1773-1858
Scottish botanist
In 1831 he was the
first person to observe
the nucleus of a cell
Schleiden & Schwann
1804-1881 1810-1882
1804-1881 1810-1882
Developing Cell Theory
1838
Schleiden
Said “all
plants are
made up of
cells”
Schwann
Said “all
animals are
made up of
cells”
1838
Schleiden
Said “all
plants are
made up of
cells”
Schwann
Said “all
animals are
made up of
cells”
Cell Theory Overview
1.All organisms are made of one or more cells
[Unicellular or Multicellular].
2.All cells carry on life activities.
3.New cells arise only from other living cells.
1.All organisms are made of one or more cells
[Unicellular or Multicellular].
2.All cells carry on life activities.
3.New cells arise only from other living cells.
Prokaryotic vs Eukaryotic
PROKARYOTIC
Simplest form
Lack membrane
bound structures
Lack true nucleus
Example: bacteria
and
cyanobacteria
EUKARYOTIC
Most common
Possess
membrane
bound structures
and a nucleus
Found in most
living things
PROKARYOTIC
Simplest form
Lack membrane
bound structures
Lack true nucleus
Example: bacteria
and
cyanobacteria
EUKARYOTIC
Most common
Possess
membrane
bound structures
and a nucleus
Found in most
living things
Sizes of Cells
Eukaryotic are
usually larger than
prokaryotic
Both nutrients and
wastes are
constantly entering
and exiting cells
Vary in size and
shape
Eukaryotic are
usually larger than
prokaryotic
Both nutrients and
wastes are
constantly entering
and exiting cells
Vary in size and
shape
Size relationships among
prokaryotes
prokaryotes
Bacterial Morphology Arrangement
1. Rod or Bacilli
a.Streptobacilli
b. Bacilli
2. Cocci
a. Cocci
b. Diplococci ( e.g. Neisseria meningitidis)
c. Streptococci ( e.g. Streptococcus pyogenes)
d. Staphylococci (e.g. Staphylococcus aureus)
e. Sarcina
f. tetrads ( Micrococcus species)
1. Rod or Bacilli
a.Streptobacilli
b. Bacilli
2. Cocci
a. Cocci
b. Diplococci ( e.g. Neisseria meningitidis)
c. Streptococci ( e.g. Streptococcus pyogenes)
d. Staphylococci (e.g. Staphylococcus aureus)
e. Sarcina
f. tetrads ( Micrococcus species)
12
Bacterial Shapes, Arrangements,
and Sizes
Variety in shape, size, and arrangement but typically
described by one of three basic shapes:
coccus -spherical
bacillus –rod
coccobacillus –very short and plump ( Brucella abortus)
Streptobacilli ( Bacillus subtilus)
diplobacilli
spirillum -helical, comma, twisted rod,
spirochete –spring-like-flexible ( Treponema pallidum)
vibrio –gently curved ( Vibrio cholera)
Spirilla-rigid ( Borreliaspecies)
Pleomorphic : variable in shape ( Corynebacterium)
Bacterial Shapes, Arrangements,
and Sizes
Variety in shape, size, and arrangement but typically
described by one of three basic shapes:
coccus -spherical
bacillus –rod
coccobacillus –very short and plump ( Brucella abortus)
Streptobacilli ( Bacillus subtilus)
diplobacilli
spirillum -helical, comma, twisted rod,
spirochete –spring-like-flexible ( Treponema pallidum)
vibrio –gently curved ( Vibrio cholera)
Spirilla-rigid ( Borreliaspecies)
Pleomorphic : variable in shape ( Corynebacterium)
13
14
Bacterial Shapes, Arrangements, and
Sizes
Arrangement of cells is dependent on pattern of
division and how cells remain attached after
division:
cocci:
singles
diplococci –in pairs
tetrads –groups of four
irregular clusters
chains
cubical packets
bacilli:
chains
Bacterial Shapes, Arrangements, and
Sizes
Arrangement of cells is dependent on pattern of
division and how cells remain attached after
division:
cocci:
singles
diplococci –in pairs
tetrads –groups of four
irregular clusters
chains
cubical packets
bacilli:
chains
15
Streptococcus sp.
Bacterial morphologies (1)
Bacterial morphologies (2)
Bacterial morphologies (3)
Bacterial Morphology Arrangement
3 Spirl
a. Vibrio
b. Spirillum
c. Spirochete
3 Spirl
a. Vibrio
b. Spirillum
c. Spirochete
Bacterial morphologies (4)
Borrelia (spirochete)
Bacterial Cell Structures &
Functions
Pili
Functions
Pili
Bacterial Cell Structure
Appendages -flagella, pili or fimbriae
Surface layers -capsule, cell wall, cell membrane
Cytoplasm -nuclear material, ribosome, mesosome,
inclusions etc.
Special structure -endospore
Appendages -flagella, pili or fimbriae
Surface layers -capsule, cell wall, cell membrane
Cytoplasm -nuclear material, ribosome, mesosome,
inclusions etc.
Special structure -endospore
Appendages
1. flagella
Some rods and spiral form have this.
a). function: motility
b). origin: cell membrane flagella attach to the cell by hook and
basal body which consists of set(s) of rings and rods
Gram -: 2 sets of ring and rods, L, P, S, M rings and
rods . e.g. E. coli
Gram + : S, M rings and rods .e.g. B. megaterium
1. flagella
Some rods and spiral form have this.
a). function: motility
b). origin: cell membrane flagella attach to the cell by hook and
basal body which consists of set(s) of rings and rods
Gram -: 2 sets of ring and rods, L, P, S, M rings and
rods . e.g. E. coli
Gram + : S, M rings and rods .e.g. B. megaterium
Flagella
Motility -movement
Swarming occurs with some bacteria
Spread across Petri Dish
Proteusspecies most evident
Arrangement basis for classification
Monotrichous; 1 flagella
Lophotrichous; tuft at one end
Kophotrichous; tuft at both ends
Amphitrichous; both ends
Peritrichous; all around bacteria
Motility -movement
Swarming occurs with some bacteria
Spread across Petri Dish
Proteusspecies most evident
Arrangement basis for classification
Monotrichous; 1 flagella
Lophotrichous; tuft at one end
Kophotrichous; tuft at both ends
Amphitrichous; both ends
Peritrichous; all around bacteria
Structure of the flagellum
c).Origin (continued)
–The structure of the bacterial flagella allows it to spin like a
propeller and thereby propel the bacterial cell; clockwise or
counter clockwise wave like motion.
–Bacterial flagella provides the bacterium with mechanism for
swimming toward or away from chemical stimuli, a behavior
is knows as CHEMOTAXIX , chemosenors in the cell
envelope can detect certain chemicals and signal the flagella
to respond.
d). structure
protein in nature: subunit flagellin ( globular protein)
–The structure of the bacterial flagella allows it to spin like a
propeller and thereby propel the bacterial cell; clockwise or
counter clockwise wave like motion.
–Bacterial flagella provides the bacterium with mechanism for
swimming toward or away from chemical stimuli, a behavior
is knows as CHEMOTAXIX , chemosenors in the cell
envelope can detect certain chemicals and signal the flagella
to respond.
d). structure
protein in nature: subunit flagellin ( globular protein)
Flagella movement(1)
Flagella movement(2)
2. Fimbriae and Pili
Fimbriae: Shorter than flagella and straighter ,
smaller, hairlike appendages . Only on some
gram-bacteria.
a). function: adhere. Not involve in motility.
One of the invasive mechanism on bacteria.
Some pathogens cause diseases due to this
(Antigenic characteristic). Prevent phagocytosis.
Fimbriae: Shorter than flagella and straighter ,
smaller, hairlike appendages . Only on some
gram-bacteria.
a). function: adhere. Not involve in motility.
One of the invasive mechanism on bacteria.
Some pathogens cause diseases due to this
(Antigenic characteristic). Prevent phagocytosis.
pili -sex factor. If they make pili, they are +or
donors of F factor.
It is necessary for bacterial conjugation
resulting in the transfer of DNA from one cell to
another.
It have been implicated in the ability of
bacteria to recognize specific receptor sites on
the host cell membrane.
donors of F factor.
It is necessary for bacterial conjugation
resulting in the transfer of DNA from one cell to
another.
It have been implicated in the ability of
bacteria to recognize specific receptor sites on
the host cell membrane.
Conjugation in E. coli
b). Origin: Cell membrane
c). Position: common pili , numerous over the cell, usually called sex pile,
1-4/cell
d). Structure: composed of proteins which can be dissociated into smaller
unit Pilin. It belongs to a class of protein Lectin which bond to cell
surface polysaccharide.
c). Position: common pili , numerous over the cell, usually called sex pile,
1-4/cell
d). Structure: composed of proteins which can be dissociated into smaller
unit Pilin. It belongs to a class of protein Lectin which bond to cell
surface polysaccharide.
II. CELL SURFACE LAYER
1. Glycocalyx: Capsule or slime layer
Many bacteria are able to secrete material that adheresto the bacterial
cell but is actually external to the cell.
It consists of polypeptide and polysaccharideon bacilli. Most of them
have only polysaccharide. It is a protective layer that resists host
phagocytosis. Medically important ( Streptococcus pneumonia).
1. Glycocalyx: Capsule or slime layer
Many bacteria are able to secrete material that adheresto the bacterial
cell but is actually external to the cell.
It consists of polypeptide and polysaccharideon bacilli. Most of them
have only polysaccharide. It is a protective layer that resists host
phagocytosis. Medically important ( Streptococcus pneumonia).
Capsule and Slime layer
The layer is well organized and not easily
washed off, it is capsule
Slime layer, unorganized material that is
easily removed.
They give mucoid growth on agar plate
B. anthracishas a capsule of poly-D-glutamic
acid, while S. pyogenesmade of Hyaluronic
acid.
Function: Resistant phagocytosis, Protect
against desiccation, Attachment to surface of
solid objects.
The layer is well organized and not easily
washed off, it is capsule
Slime layer, unorganized material that is
easily removed.
They give mucoid growth on agar plate
B. anthracishas a capsule of poly-D-glutamic
acid, while S. pyogenesmade of Hyaluronic
acid.
Function: Resistant phagocytosis, Protect
against desiccation, Attachment to surface of
solid objects.
Axial Filaments
Present in spirochetes ( Treponema pallidumcause
syphilis)
Function is motility –gliding motility
Bundles of fibrils that arise at the ends of the cell
Present in spirochetes ( Treponema pallidumcause
syphilis)
Function is motility –gliding motility
Bundles of fibrils that arise at the ends of the cell
Spirochetes
Axial filament
Structurally similar to flagella
Unique location under an outer membrane
Axial filament
Structurally similar to flagella
Unique location under an outer membrane
2. Bacterial Cell Wall
General structure: mucopolysaccharide
i.e. peptidoglycan. It is made by N-
acetylglucosamine and N-acetylmuramic acid.
tetrapeptide ( L-alanine-isoglutamine-lysine-
alanine) is attached. The entire cell wall
structure is cross linked by covalent bonds.
This provide the rigiditynecessary to maintain
the integrity of the cell.
N-acetylmuramic acidis unique to
prokaryotic cell.
General structure: mucopolysaccharide
i.e. peptidoglycan. It is made by N-
acetylglucosamine and N-acetylmuramic acid.
tetrapeptide ( L-alanine-isoglutamine-lysine-
alanine) is attached. The entire cell wall
structure is cross linked by covalent bonds.
This provide the rigiditynecessary to maintain
the integrity of the cell.
N-acetylmuramic acidis unique to
prokaryotic cell.
Cell walls of bacteria(2)
Cell walls of bacteria(3)
Cell walls of bacteria(4)
Cell walls of bacteria(1)
Structure of peptidoglycan(1)
Structure of peptidoglycan(2)
a). Gram positive bacterial cell wall
Thick peptidoglycan layer
pentaglycin cross linkage.
Teichoic acid (TA): Polymer of ribitol
& glycerol joined by phosphate groups
Some have peptioglycan teichoic acid.
All have lipoteichoic acid.
Thick peptidoglycan layer
pentaglycin cross linkage.
Teichoic acid (TA): Polymer of ribitol
& glycerol joined by phosphate groups
Some have peptioglycan teichoic acid.
All have lipoteichoic acid.
Function of Teichoic acids:
* Antigenic determinant
* Participate in the supply of Mg to
the cell by binding Mg++
* regulate normal cell division.
For most part, protein is not found as
a constituent of the G+cell wall except
M protein on group streptococci
* Antigenic determinant
* Participate in the supply of Mg to
the cell by binding Mg++
* regulate normal cell division.
For most part, protein is not found as
a constituent of the G+cell wall except
M protein on group streptococci
Structure of the Gram-positive
Cell Wall
Cell Wall
(b) Gram negative bacterial cell wall:
Thin peptidoglycan
Tetrapeptide cross linkage
A second membrane structure: protein and
lipopolysaccharide (LPS).
Toxicity : endotoxin on lipid A of LPS.
glucosamine-glucosamine-long
polysaccharide-repeated sequences of a few sugars
(e.g. gal-mann-rham) n=10-20 O antigen
Thin peptidoglycan
Tetrapeptide cross linkage
A second membrane structure: protein and
lipopolysaccharide (LPS).
Toxicity : endotoxin on lipid A of LPS.
glucosamine-glucosamine-long
polysaccharide-repeated sequences of a few sugars
(e.g. gal-mann-rham) n=10-20 O antigen
Structure of peptidoglycan(3)
Toxicity : endotoxin on lipid A of
lipopolysaccharide.
glucosamine-glucosamine-long
FAFA FA FA
polysaccharide-repeated sequences of
a few sugars (e.g. gal-mann-rham)
n=10-20 O antigen
lipopolysaccharide.
glucosamine-glucosamine-long
FAFA FA FA
polysaccharide-repeated sequences of
a few sugars (e.g. gal-mann-rham)
n=10-20 O antigen
Chemistry of LPS
The Gram-negative outer membrane(1)
The Gram-negative outer membrane(2)
58
Atypical Cell Walls
Some bacterial groups lack typical cell wall
structure i.e. Mycobacterium and Nocardia
Gram-positive cell wall structure with lipid mycolic
acid(cord factor)
pathogenicity and high degree of resistance to certain
chemicals and dyes
basis for acid-fast stainused for diagnosis of infections
caused by these microorganisms
Some have no cell wall i.e. Mycoplasma
cell wall is stabilized by sterols
pleomorphic
Atypical Cell Walls
Some bacterial groups lack typical cell wall
structure i.e. Mycobacterium and Nocardia
Gram-positive cell wall structure with lipid mycolic
acid(cord factor)
pathogenicity and high degree of resistance to certain
chemicals and dyes
basis for acid-fast stainused for diagnosis of infections
caused by these microorganisms
Some have no cell wall i.e. Mycoplasma
cell wall is stabilized by sterols
pleomorphic
2. Cell Membrane
Function:
a. control permeability
b. transporte’s and protons for cellular metabolism
c. contain enzymes to synthesis and transport
cell wall substance and for metabolism
d. secret hydrolytic enzymes
e. regulate cell division.
Fluid mosaic model. phospholipid bilayer and
protein (structure and enzymatic function). Similar
to eukaryotic cell membrane but some differs. e.g.
sterols such as cholesterol in Euk not in Prok.
Function:
a. control permeability
b. transporte’s and protons for cellular metabolism
c. contain enzymes to synthesis and transport
cell wall substance and for metabolism
d. secret hydrolytic enzymes
e. regulate cell division.
Fluid mosaic model. phospholipid bilayer and
protein (structure and enzymatic function). Similar
to eukaryotic cell membrane but some differs. e.g.
sterols such as cholesterol in Euk not in Prok.
60
Functions of
the cytoplasmic membrane(1)
the cytoplasmic membrane(1)
Functions of
the cytoplasmic membrane(2)
the cytoplasmic membrane(2)
Transport proteins
Classes of membrane
transporting systems(1)
transporting systems(1)
Classes of membrane transporting
systems(2)
systems(2)
66
Bacterial Internal Structures
Cell cytoplasm:
dense gelatinous solution of sugars, amino acids, and salts
70-80% water
serves as solvent for materials used in all cell functions
Bacterial Internal Structures
Cell cytoplasm:
dense gelatinous solution of sugars, amino acids, and salts
70-80% water
serves as solvent for materials used in all cell functions
67
Bacterial Internal Structures
Chromosome
single, circular, double-stranded DNA molecule that contains all the
genetic information required by a cell
DNA is tightly coiled around a protein, aggregated in a dense area
called the nucleoid.
Bacterial Internal Structures
Chromosome
single, circular, double-stranded DNA molecule that contains all the
genetic information required by a cell
DNA is tightly coiled around a protein, aggregated in a dense area
called the nucleoid.
The bacterial chromosome and
supercoiling
supercoiling
69
Bacterial Internal Structures
Plasmids
small circular, double-stranded DNA
free or integrated into the chromosome
duplicated and passed on to offspring
not essential to bacterial growth and metabolism
may encode antibiotic resistance, tolerance to toxic metals, enzymes and
toxins
used in genetic engineering-readily manipulated and transferred from
cell to cell
Bacterial Internal Structures
Plasmids
small circular, double-stranded DNA
free or integrated into the chromosome
duplicated and passed on to offspring
not essential to bacterial growth and metabolism
may encode antibiotic resistance, tolerance to toxic metals, enzymes and
toxins
used in genetic engineering-readily manipulated and transferred from
cell to cell
70
Bacterial Internal Structures
Ribosomes (70 S)
made of 60% ribosomal RNA and 40% protein
consist of two subunits: large and small
procaryotic differ from eucaryotic ribosomes in size and number of
proteins
site of protein synthesis
present in all cells
Bacterial Internal Structures
Ribosomes (70 S)
made of 60% ribosomal RNA and 40% protein
consist of two subunits: large and small
procaryotic differ from eucaryotic ribosomes in size and number of
proteins
site of protein synthesis
present in all cells
71
3. Mesosomes ( mostly in Gram +ve)
A large invaginations of the plasma membrane,
irregular in shape.
a. increase in membrane surface, which may be
useful as a site for enzyme activity in respiration
and transport.
b. may participate in cell replication by serving as a
place of attachment for the bacterial chromosome.
A large invaginations of the plasma membrane,
irregular in shape.
a. increase in membrane surface, which may be
useful as a site for enzyme activity in respiration
and transport.
b. may participate in cell replication by serving as a
place of attachment for the bacterial chromosome.
4. Inclusions
Not separate by a membrane but distinct.
Granules of various kinds:
* glycogen ( used as carbon source),
*polyhydroxybutyric acid droplets (PHB)
i.e. fat droplets and have Lipid inclusion
* inorganic metaphosphate (metachromatic granules or
Volutin granules) -in general, starvation of cell for almost
any nutrients leads to the formation of this to serve as an
intracellular phosphate reservoir ( Corynebacterium).
Not separate by a membrane but distinct.
Granules of various kinds:
* glycogen ( used as carbon source),
*polyhydroxybutyric acid droplets (PHB)
i.e. fat droplets and have Lipid inclusion
* inorganic metaphosphate (metachromatic granules or
Volutin granules) -in general, starvation of cell for almost
any nutrients leads to the formation of this to serve as an
intracellular phosphate reservoir ( Corynebacterium).
PHB
5. Chromatophores
Only in photosynthetic bacteria and blue green algae.
Prok. no chloroplast, pigment found in lamellae
located beneath the cell membrane.
Sulfur Granules: Mainly in Thiobacillus, convert H2S
to S
Only in photosynthetic bacteria and blue green algae.
Prok. no chloroplast, pigment found in lamellae
located beneath the cell membrane.
Sulfur Granules: Mainly in Thiobacillus, convert H2S
to S
76
IV. Special Structure
*Endospores
Spore former: Sporobactobacilliand Sporosarcinae
(Gram + cocci)-no medical importance.
BacillusandClostridium( Gram + Rod) have medical
importance. Coxiella( Gram –ve Rod) cause Q fever.
*Position: median, sub-terminal and terminal have
small water, high calcium content and dipicolinic acid
(calcium dipicolinate)
Extremely resistant to heat, UV, chemicals etc. may be
due to many S containing A.A for disulfide groups.
*Endospores
Spore former: Sporobactobacilliand Sporosarcinae
(Gram + cocci)-no medical importance.
BacillusandClostridium( Gram + Rod) have medical
importance. Coxiella( Gram –ve Rod) cause Q fever.
*Position: median, sub-terminal and terminal have
small water, high calcium content and dipicolinic acid
(calcium dipicolinate)
Extremely resistant to heat, UV, chemicals etc. may be
due to many S containing A.A for disulfide groups.
•After the active growth period approaching the stationary growth
phase, a structure called forespore develops within the cells.
•It consists of coat, cortex and nuclear structure.
The process of endospore
formation
phase, a structure called forespore develops within the cells.
•It consists of coat, cortex and nuclear structure.
The process of endospore
formation
Negatively Stained Bacillus: (A) Vegetative Cell(B)Endospore
Dipicolinic acid
82
Detailed steps
in endospore formation(1)
in endospore formation(1)
Detailed steps
in endospore formation(2)
in endospore formation(2)
Detailed steps
in endospore formation(3)
in endospore formation(3)
PROCARYOTIC vs.
EUCARYOTIC CELLSProperty Procaryotes Eucaryotes
Membrane-bound nucleus Absent Present
DNA complexed with histones No Yes
Number of chromosomes One > One
Nucleolus Absent Present
Mitosis No Yes
Genetic recombination Partial Meiosis
unidirectionalfusion of gametes
EUCARYOTIC CELLSProperty Procaryotes Eucaryotes
Membrane-bound nucleus Absent Present
DNA complexed with histones No Yes
Number of chromosomes One > One
Nucleolus Absent Present
Mitosis No Yes
Genetic recombination Partial Meiosis
unidirectionalfusion of gametes
PROCARYOTIC vs.
EUCARYOTIC CELLSProperty ProcaryotesEucaryotes
Mitochondria Absent Present
Chloroplasts Absent Present
Endoplasmic reticulum Absent Present
Golgi apparatus Absent Present
EUCARYOTIC CELLSProperty ProcaryotesEucaryotes
Mitochondria Absent Present
Chloroplasts Absent Present
Endoplasmic reticulum Absent Present
Golgi apparatus Absent Present
PROCARYOTIC vs.
EUCARYOTIC CELLSProperty Procaryotes Eucaryotes
Plasma membrane sterolsUsually no Yes
Flagella SubmicroscopicMembrane bound
(1 fiber)20 microtubules
(9+2)
Microtubules Absent or rare Present
EUCARYOTIC CELLSProperty Procaryotes Eucaryotes
Plasma membrane sterolsUsually no Yes
Flagella SubmicroscopicMembrane bound
(1 fiber)20 microtubules
(9+2)
Microtubules Absent or rare Present
PROCARYOTIC vs.
EUCARYOTIC CELLS Property Procaryotes Eucaryotes
70S (30S+50S)
80S (40S+60S)
Lysosomes, peroxisomes Absent Present
Cell walls
Ribosomes
Complex; peptidoglycanSimple; no peptidoglycan
70S (30S+50S)
EUCARYOTIC CELLS Property Procaryotes Eucaryotes
70S (30S+50S)
80S (40S+60S)
Lysosomes, peroxisomes Absent Present
Cell walls
Ribosomes
Complex; peptidoglycanSimple; no peptidoglycan
70S (30S+50S)
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