Morphology of Bacteria PDF

Summary

This document presents lecture notes on bacterial morphology and structure. The content covers classification, shape, and anatomy of bacteria. It also details functions of bacterial cell walls, and differences between Gram-positive and Gram-negative bacteria. This is a detailed overview of bacteria.

Full Transcript

Morphology of bacteria

Dr Anusha G
Professor
Department Of Microbiology
Pre- Test
 Learning objectives
Classification of bacteria depending on their morphology and Gram
staining property

Bacterial cell wall and cell wall appendages

Bacterial Growth Curve
 Shape of Bacteria

Depending - on shape, bacteria - classified into:
Cocci (meaning berry) - oval or spherical cells

Bacilli or rods - rod shaped.

Cocci - arranged in groups (clusters), pair or chains.

Bacilli - arranged in chain, pair, and some bacilli are curved, comma
shaped, or cuneiform shaped
 Cocci and bacilli - further classified - based on Gram staining into:

Gram-positive cocci

Gram-negative cocci

Gram-positive bacilli

Gram-negative bacilli.
 Bacterial cell anatomy

The outer layer/envelope - consists - (1)rigid cell wall (2) plasma
membrane

Cytoplasm contains - cytoplasmic inclusions (mesosomes, ribosomes,
etc) and a diffuse nucleoid containing single circular chromosome.
 Some bacteria - possess additional cell wall appendages -
capsule, flagella and fimbriae.
Classification of bacteria depending on their morphology
and Gram staining property
Bacteria Example
Gram-positive cocci arranged in
Cluster Staphylococcus
Chain Streptococcus
Pairs, lanceolate shaped Pneumococcus
Pair or in short chain, Enterococcus
spectacle shaped
Tetrads Micrococcus
Octate Sarcina
Gram-negative cocci arranged in
Pairs, lens shaped Meningococcus
Pairs, kidney shaped Gonococcus
Bacteria Example
Gram-positive bacilli arranged in
Chain (bamboo stick Bacillus anthracis
appearance)
Chinese letter or cuneiform Corynebacterium diphtheriae
pattern
Palisade pattern Diphtheroids
Branched and filamentous Actinomyces and Nocardia
form
Bacteria Example
Gram-negative bacilli arranged in
Pleomorphic (various shapes) Haemophilus, Proteus
Thumb print appearance Bordetella pertussis
Comma shaped (fish in stream Vibrio cholerae
appearance)
Curved Campylobacter (Gull-wing shaped)
and Helicobacter
Chain Streptobacillus
Spirally coiled, flexible Spirochetes
Rigid spiral forms Spirillum
Bacteria that lack cell wall Mycoplasma
BACTERIAL CELL WALL
 Tough and rigid structure - surrounding the bacterium.

10–25 nm thickness

Weighs about 20–25% of the dry weight of the cell.
 Functions of cell wall

Protection to cell against osmotic lysis

Confers rigidity - presence of peptidoglycan layer in the cell wall

Protect cell from toxic substances

Site of action of several antibiotics
 Contains - virulence factors (e.g. endotoxin) - contribute to
pathogenicity

Antibody against specific cell wall antigens (e.g. antibody to LPS) -
provide immunity against bacterial infection.
 Differences between gram-positive
and gram negative cell wall
Characters Gram-positive
wall cell Gram-negative cell wall

Peptidoglycan layer Thicker (16–80 nm) Thinner (2 nm)

Lipid content Nil or scanty (2–5%) Present (15–20%)

Lipopolysaccharide Absent Present (endotoxin)

Teichoic acid Present Absent

Variety of amino acids Few Several

Aromatic amino acids Absent Present
 Peptidoglycan

Thicker (50–100 layers thick, 16–80 nm) than gram-negative cell wall
Each layer - mucopeptide (murein) chain - alternate units of N-acetyl
muramic acid (NAM) and N-acetyl glucosamine (NAG) molecules -
cross linked via tetrapeptide side chains and pentaglycine bridges
3
Tetrapeptide side chain - from NAM molecule - composed of L-alanine-
D-glutamine - L-lysine - D-alanine
Structure of Gram- Peptidoglycan layer of Gram-
positive cell wall positive
 Teichoic Acid

Polymers of glycerol or ribitol - joined by phosphate groups.

Maintain - structure of cell wall.

Two types: (i) Cell wall teichoic acid and (ii) Lipoteichoic acid.

Absent in gram-negative bacteria.
 Peptidoglycan layer

Very thin (1–2 layer, 2 nm thick) - composed of a mucopeptide chain -
similar to gram-positive cell wall.

Consists - alternate NAM and NAG molecules
 Outer Membrane

Phospholipid layer - lies outside the thin peptidoglycan layer

Serves as - protective barrier to the cell

Outer membrane proteins (OMP) or porin proteins - specialized proteins
 Lipopolysaccharide (LPS)
Consists of three parts:
Lipid A or the endotoxin
Core polysaccharide
O side chain (or O antigen or somatic antigen)

Periplasmic Space
Space between the inner cell membrane and outer membrane. It
encompasses the peptidoglycan layer.
 CELL MEMBRANE
Essential for - survival of the bacteria.

5–10 nm thick -bilayered phospholipid - several proteins are embedded -
integral proteins and peripheral proteins
 Lacks sterols -such as cholesterol (except in Mycoplasma).

Contain pentacyclic sterol-like molecules - hopanoids
 Functions of cell membrane
Semi permeable membrane

Transport system -nutrient uptake, and waste excretion

Site for metabolic processes
 CYTOPLASMIC MATRIX
Bacterial cytoplasm, lacks membrane-bound organelles.

Composed of water (70%)

Packed with ribosomes, storage granules - inclusions and cell
membrane invaginations - mesosomes.

Plasma membrane and everything within it - called as protoplast.
 Ribosomes
Sites for protein synthesis.

Composed of rRNA and ribosomal proteins.

Integrated with the mRNA to form polysomes

At this site - genetic codons of the mRNA -
translated into peptide sequences.

Each 70 S unit - consists of a 30 S and a 50 S
subunits.
 Intracytoplasmic Inclusions
Storage sites of nutrients/energy

Formed by bacteria under nutritional deficiency conditions and disappear
when the deficient nutrients are supplied.

Two types of inclusions:
Organic inclusion bodies
Inorganic inclusion bodies
 Mesosomes
Invaginations of plasma membrane - in the shape of vesicles, tubules, or
lamellae.

Prominent in gram-positive bacteria.
Involved in:
Bacterial respiration
Cell wall formation
Chromosome replication
 Nucleoid
Bacteria do not have a true nucleus - genetic material - located in an
irregularly shaped region called - nucleoid.

Bacteria possess a single haploid chromosome.

Comprises of super coiled circular double stranded DNA

Seen by electron microscopy or on staining with Feulgen stain

Bacteria also possess extrachromosomal DNA - plasmids
 CELL WALL APPENDAGES
Composed of:

Capsule and Slime Layer

Flagella

Fimbriae or Pili
 Capsule and Slime Layer
Layer of amorphous viscid material lying outside the cell wall called
glycocalyx.

Capsule -well organized and not easily washed off

Slime layer - diffuse, unorganized loose material that can be removed
easily
Capsulated bacteria Composition
Pneumococcus Polysaccharide
Meningococcus Polysaccharide
Haemophilus influenzae Polysaccharide
Klebsiella pneumoniae Polysaccharide
Pseudomonas aeruginosa Polysaccharide
Bacteroides fragilis Polysaccharide
Bacillus anthracis Polypeptide (glutamate)
Streptococcus pyogenes (some Hyaluronic acid
strains)
 Functions of capsules
Bacterial virulence
Prevent cell from drying out (desiccation)

Protects the bacterium from the action of lysozyme and bacteriophages.

Toxic to the host cells and induces abscess formation (e.g. Bacteroides
fragilis)
 Capsules as vaccine

Capsular vaccines are available for bacteria such as Pneumococcus,
Meningococcus and Haemophilus influenzae serotype-b.
 Biofilm Formation

Biofilm - living ecosystem made of millions of adherent bacterial
cells embedded within a self-produced matrix of extracellular
polymeric substance

Capable of adherence to damaged tissues and plastic surfaces.

Adhesion is a first step in colonization and sometimes leads to
disease
 Demonstration of Capsule
Capsule can be detected by various methods:

Negative staining by India ink and nigrosin stain

M’Faydean capsule stain

Serological test
Quellung reaction
Capsular antigen
 Flagella
Thread-like appendages - protruding from the cell wall

Confer motility to the bacteria

5–20 µm in length and 0.01 - 0.02 µm in thickness.
 Arrangement of Flagella
Monotrichous - e.g. Vibrio cholerae,
Pseudomonas and Campylobacter

Lophotrichous - e.g. Spirillum

Peritrichous - e.g. Salmonella Typhi,
Escherichia coli

Amphitrichous - e.g. Alcaligenes faecalis.
 Ultrastructure of Flagella
On electron microscope - bacterial flagellum is - composed of three parts
1. Filament - longest portion of the flagellum that extends from the cell
surface to the tip.

2. The basal body

3. Hook
 Detection of Flagella
Direct demonstration of flagella:
Tannic acid staining (Leifson’s method)
Electron microscopy.

Indirect means by demonstrating the motility:
Craigie tube method
Hanging drop method
Semisolid medium, e.g. mannitol motility medium
Dark ground or phase contrast microscopy.
 Types of motility shown by
different bacteria
Types of motility Bacteria

Tumbling motility Listeria

Gliding motility Mycoplasma

Stately motility Clostridium

Darting motility Vibrio cholerae, Campylobacter

Swarming on agar plate Proteus, Clostridium tetani

Corkscrew,
motility lashing, flexion extension Spirochete
 Fimbriae or Pili
Short, fine, hair-like appendages - help in bacterial adhesion.

Special type of pili (called sex pilus) - helps in conjugation.

Pili - made up of protein called pilin

Antigenic; but, the antibodies against pilin antigens are not protective.

Not related to motility
 Type of Pili
According to functions, pili are of two types.

1. Common pili or fimbriae

2. Sex pili

A B
 Detection of Fimbriae
Electron microscope

Surface pellicle - thin layer formed at the surface of a liquid culture of
strongly aerobic bacteria such as Pseudomonas.
 Atypical Forms of Bacteria
Involution forms: Swollen and aberrant forms of bacteria (e.g.
gonococci and Yersinia pestis) formed in ageing cultures in high salt
concentration

Pleomorphic bacteria: Exhibit great variation in the shape and size of
individual cells, e.g. Proteus and Haemophilus.
 L Form (Cell Wall Deficient
Forms)
Discovered by E. Klieneberger, while studying Streptobacillus
moniliformis.

Named it as L form - after its place of discovery, i.e. Lister Institute,
London (1935)

L forms play a role in the persistence of pyelonephritis and other chronic
infections.
 Bacterial Spores
Spores are highly resistant resting (or dormant) stage of the bacteria.

Formed in unfavorable environmental conditions - as a result of the
depletion of exogenous nutrients.
 Bacterial spore comprises of several layers.

From innermost towards the outermost, the layers are: core → cortex →
coat → exosporium
 Sporulation
Refers to - process of formation of spores from vegetative stage of
bacteria.

Not a method of reproduction - because bacteria do not divide during
sporulation.

Complex process and takes about 10 hours.

Mature spore formed is extremely resistant to heat and disinfectant
 Germination
Transformation of dormant spores into active vegetative cells when

grown in a nutrient-rich medium.
 Shape and Position of Spores
For a given species, the precise position, shape and relative size of the
spore are constant.

Position: Central, subterminal or terminal

Shape: Oval or spherical in shape

Width: Diameter of spore may be same or less than the width of
bacteria
A. Non-bulging, oval and terminal; B. Non-bulging, round, and subterminal;
C. Non-bulging, oval and central; D. Bulging, round and terminal;
E. Bulging, oval and terminal; F. Bulging, oval, and central
 Sporicidal Agents
Spores are resistant to most of the routinely used disinfectants.

Only limited agents called as sterilants are capable of killing the spores,
e.g. autoclave, or ethylene oxide sterilizer, etc.
 Demonstration of Spores
Gram staining: Spores appear as unstained refractile bodies within the
cells

Modified Ziehl–Neelsen staining: Spores are weakly acid-fast and
appear red color.

Special techniques for endospore staining include the Schaeffer–Fulton
stain and the Moeller stain
 Applications of spores
Indicators of proper sterilization.

Spores of Geobacillus stearothermophilus - sterilization control for
autoclave and plasma sterilizer

Spores of Bacillus atrophaeus - sterilization control for hot air oven
and ethylene oxide sterilizer.

Used as agents of bioterrorism
PHYSIOLOGY OF BACTERIA

64
 Bacterial Growth Requirement

▪ Water constitutes - 80% of total bacterial cell.

▪ Minimum nutritional requirements - essential for growth and multiplication of
bacteria include - sources of carbon, nitrogen, hydrogen, oxygen and some
inorganic

65
 Bacterial Cell Division
▰ Bacteria divide by a relatively simple form of cell division, i.e. by binary fission

⮚ Nuclear division

⮚ Cytoplasmic division

66
 Rate of Multiplication in Bacteria

Generation time is the time required for a bacterium to give rise to two daughter cells
under optimum condition.

⮚ Escherichia coli and most of the other pathogenic bacteria -20 minutes;

⮚ Mycobacterium tuberculosis - 20 hours

⮚ Mycobacterium leprae - 20 days

67
Bacterial Count
▰ Total count: Indicates total number of bacteria (live or dead) in the specimen. This

is done by counting the bacteria under microscope using counting chamber.

▰ Viable count: Measures the number of living (viable) cells in the given specimen.

Viable count may be obtained by a technique called as pour plate method.

68
Bacterial Growth Curve

▰ When a bacterium is inoculated into a suitable liquid culture medium and

incubated, its growth follows a definite course.

▰ When bacterial count of such culture is determined at different intervals and plotted
in relation to time, a bacterial growth curve is obtained.

69
Bacterial growth curve comprises of four phases.

⮚ Lag phase

⮚ Log phase

⮚ Stationary phase

⮚ Phase of decline

70
 Lag Log Stationary Decline
Bacteria No Yes Yes No
divide
Bacterial No No Yes Yes
death
Total count Flat Raises Raises Flat
Viable count Flat Raises Flat Falls
Special Accumulation of Uniformly stained Gram variable. Produce:
features enzymes and Metabolically active Produce: Involution forms
metabolites Attains Small size Granules spores,
maxi- mum size exotoxin,
antibiotics,
bacteriocin
71
Lag phase
▪ Period between inoculation and beginning of
multiplication of bacteria.

▪ Bacteria increase in size due to accumulation
of enzymes and metabolites.

▪ Bacteria reach their maximum size at the end
of lag phase.

72
Log phase
Bacteria divide exponentially so that the growth
curve takes a shape of straight line. At this stage,
the bacterium is:

▰ Smaller in size

▰ Biochemically active

▰ Uniformly stained

73
Stationary phase

▰ Number of viable cells remain stationary as

there is a balance between the dying cells and
the newly formed cells. But the total count
keeps raising.

74
In this phase:

▪ Bacterium becomes gram-variable

▪ More storage granules are formed

▪ Sporulation occurs in this phase

▪ Bacteria produce exotoxins, antibiotics and
bacteriocins

75
Decline phase

▰ Bacteria stop dividing completely; while the

cell death continues due to exhaustion of
nutrients, and accumulation of toxic products.

▰ Involution forms are seen.

76
 Factors Affecting Growth of Bacteria
There are several environmental factors that affect the growth of the bacteria.
▪ Oxygen
▪ Carbon dioxide
▪ Temperature
▪ pH
▪ Light
▪ Osmotic Effect
▪ Mechanical and Sonic Stresses
▪ Moisture and Desiccation

77
Oxygen
Classification Explanation Examples

Obligate aerobes Can grow only in the Pseudomonas,
presence of oxygen Mycobacterium
tuberculosis, Bacillus,
Brucella and Nocardia

Facultative anaerobes They are aerobes that can Most of the pathogenic
also grow anaerobically bacteria, e.g. E.coli,
S.aureus
Facultative aerobes They are anaerobes that Lactobacillus
can also grow aerobically

78
Classification Explanation Examples
Microaerophilic bacteria Can grow in the presence Campylobacter,
of low oxygen tension, i.e., Helicobacter,
5-10% of oxygen Mycobacterium bovis
Obligate anaerobes These bacteria can grow Clostridium
only in the absence of
oxygen. Oxygen is lethal
to these bacteria
Aerotolerant anaerobe Tolerate oxygen for some Clostridium histolyticum
time, but do not use it

79
Carbon dioxide

▪ Organisms that require higher amounts of carbon dioxide (5–10%) for growth are
called capnophilic bacteria.

▪ Examples - Brucella abortus, Streptococcus pneumoniae, etc

80
Temperature
▪ Psychrophiles: Grow at temperatures below 20°C; example, most of the
saprophytes, e.g. Pseudomonas

▪ Mesophiles: Grow within a temperature range 25°C - 40°C; example, most of the
pathogenic bacteria

▪ Thermophiles: Grow at a high temperature range of 55°C–80°C, e.g. Geobacillus
stearothermophilus.

81
pH

▪ Most pathogenic bacteria grow between pH 7.2 -7.6.

▪ Very few bacteria (e.g. lactobacilli) can grow at acidic pH below pH 4

▪ Vibrio cholerae are capable of growing at alkaline pH (8.2–8.9).

82
Light

▪ Bacteria (except phototrophs) grow well in darkness.

▪ They are sensitive to ultraviolet rays and other radiations in light.

▪ Photochromogenic mycobacteria produce pigments only on exposure to light.

83
Osmotic Effect

▪ Bacteria are able to withstand a wide range of external osmotic variation because of
the mechanical strength of the cell wall.

▪ Sudden exposure to hypertonic saline may cause cell shrinkage (plasmolysis)

▪ Exposure to distilled water may cause cell swelling and rupture (plasmoptysis).

84
Bacterial Metabolism

▪ Process by which a microbe obtains the energy and nutrients (e.g. carbon) for its
survival and reproduction.

85
Bacterial Metabolism
▪ Autotrophs
▪ Heterotrophs
▪ Lithotrophs
▪ Organotrophs
▪ Chemotrophs
▪ Phototrophs

86
Post - Test
Thank you