L1 Bacterial Structure & Growth Classification PDF

Summary

This document is a lecture on bacterial structure and growth classification, covering topics such as bacterial cells, their structures, and the classification of bacteria. It also includes information on the properties, composition, nomenclature, and classification of bacterial cells, along with physical and nutritional requirements and concepts related to pathogenesis of infection.

Full Transcript

Bacterial Structure & Growth +
Classification

Dr. Ardita Dewi Roslani
Microbiology
IMS
 TOPIC LEARNING OUTCOMES
TLO1: Describe the characteristics & properties of the
bacterial cell which make them unique pathogens.
TLO2: Discuss the structure and composition of medically-
important bacterial cells.
TLO3: Explain the nomenclature and classification of
bacterial cells.
TLO4: Discuss in brief the physical and nutritional
requirements of bacteria.
TLO5: Explain the terms related to pathogenesis of infection.
 Bacteria
Content:
STRUCTURE OF BACTERIA:
1. Cytoplasmic Structures (Nucleoid, Inclusion Bodies, Volutin Granule)
2. Cell envelope
3. Cell membrane
4. Cell wall (Differences between Gram-positive & Gram-negative)
5. Glycocalyx, capsule & slime layer
6. External Structures (Flagella, Pili, Fimbriae, Endospores)

CLASSIFICATION OF BACTERIA:
I. Taxonomy of Bacteria (Identification, Classification, Nomenclature)
II. Criteria for Identification (Growth on Media, Bacterial Microscopy,
Nutrition, Biochemical & Immunological Tests, Genetic Diversity).
TERMS RELATED TO PATHOGENESIS OF INFECTIONS
Figure 1 Diagrammatic structure of a typical bacterial cell.
 Structure of Bacteria
Bacteria are single-celled prokaryotes; their DNA forming a long circular
molecule not contained within a defined nucleus. Many are motile, using
a unique pattern of flagella. A bacterial cell is surrounded by a complex
cell wall and often a capsule. They reproduce by binary fission.

1. Cytoplasmic Structures of Bacterial Cells:
a) The Nucleoid:
Prokaryotes have no true nuclei; instead they package their DNA in a
structure known as the nucleoid. The DNA is neutralized by magnesium
ions, but histone-like proteins (HLP) exist in bacteria – bind DNA;
regulatory function etc.
Rapidly-growing bacteria have more nucleoids per cell than slowly-
growing ones.
A

FIGURE 2 The nucleoid. A: Colour-enhanced transmission electron micrograph of
Escherichia coli with the DNA shown in red. B: Chromosome released from a gently
lysed cell of E. coli. Note how tightly packaged the DNA must be inside the bacterium.
 Structure of Bacteria
b) Inclusion Bodies:
They are insoluble granules which bacteria often use to store energy and
as a reservoir of structural building blocks. Inclusion bodies are bounded
by a thin lipid membrane to separate them from the cytoplasm.

c) Volutin Granules:
Many bacteria accumulate large reserves of inorganic phosphate in the
form of granules of polyphosphate. These granules are sources of
phosphate for nucleic acid synthesis to support growth. These granules
are sometimes termed metachromatic granules. They are characteristic
features of corynebacteria.
 Structure of Bacteria
2. Cell Envelope:
Prokaryotic cells are surrounded by complex envelope
outermost layers - differ in composition among the major
groups. These structures protect the organisms from hostile
environments, such as extreme osmolarity, harsh chemicals, and
even antibiotics, maintains its shape and enable cell processes.

The envelope consists of:
a. The cytoplasmic (cell) membrane
b. The cell wall
+/- outer membrane (if present e.g. Gram-negatives)
 Structure of Bacteria
3. Cell Membrane:
The bacterial cell / cytoplasmic membrane, is a typical “unit membrane”
composed of phospholipids and upward of 200 different kinds of
proteins. The major functions of the cytoplasmic membrane are:

(1) Selective permeability and transport of solutes;
(2) Electron transport and oxidative phosphorylation in aerobic species;
(3) Excretion of hydrolytic exoenzymes;
(4) Bearing the enzymes and carrier molecules for biosynthesis of DNA;
(5) Bearing the receptors of chemotactic and other transduction systems.
FIGURE 3 The structure of a prokaryotic cytoplasmic membrane: a phospholipid bilayer.
 Structure of Bacteria

4. Cell Wall:
i. Peptidoglycan layer (in both Gram-positives & negatives):
Bacterial cell wall owes its strength to a layer composed of a substance
referred to as PEPTIDOGLYCAN. Peptidoglycan is a complex polymer
consisting of three parts:
a backbone of N-acetylglucosamine & N-acetylmuramic acid;
identical tetrapeptide side chains attached to N-acetylmuramic acid;
identical peptide cross-bridges.
Bacteria are classified according to their response to the Gram-staining
process of this cell wall. Gram-positive bacteria look purple under the
microscope, and Gram-negative bacteria look red (pink).
The Gram staining process involves 2 stains and 2 other reagents.
STEPS FOR
GRAM-
STAINING

Fixes
TABLE 1 Comparison of Features of Gram-Positive & Gram-Negative Bacteria.
Figure 3.1 (a) The Gram-positive cell wall has a thick layer of peptidoglycan and
lipoteichoic acids that anchor the wall to the cytoplasmic membrane.
Figure 3.1 (b) The Gram-negative cell wall has a thin layer of peptidoglycan and an
outer membrane composed of lipopolysaccharide (LPS), phospholipids, and proteins.
 Structure of Bacteria

ii. Teichoic and teichuronic acids (Special components of Gram-positive
cell walls):
Most Gram-positive cell walls contain considerable amounts of
teichoic and teichuronic acids, which may contain a variety of sugars.
There are two types of teichoic acids: wall teichoic acid (WTA) and
membrane lipoteichoic acids (LTA).

iii. Polysaccharides: Hydrolysis of Gram-positive walls has yielded
sugars such as mannose & arabinose; these sugars exist as subunits of
polysaccharides in the cell wall. Some polysaccharides may serve as a
functional replacement for wall teichoic acids.
 Structure of Bacteria

5. OUTER MEMBRANE (Special components of Gram-negative
cells)
It is a bilayered structure; its inner leaflet composition resembles that of
the cell membrane, and its outer leaflet contains a distinctive component,
a lipopolysaccharide (LPS). As a result, the leaflets of this membrane are
asymmetrical.
 Structure of Bacteria

a. Lipopolysaccharide (LPS): consists of a complex glycolipid, called lipid
A. Each Gram-negative species contains a unique repeat unit (referred to
as O antigen). LPS is extremely toxic - called the endotoxin of Gram-
negative bacteria - it is released only when the cells are lysed.

b. Lipoprotein: The most abundant protein of Gram-negative cells. It
stabilizes the outer membrane and anchors it to peptidoglycan layer.

c. The periplasmic space: The space between the inner and outer
membranes, which contains the thin peptidoglycan layer and a gel-like
solution of proteins.
Figure 4 Lipopolysaccharide structure. A: The lipopolysaccharide from Salmonella.
B: Molecular model of an Escherichia coli lipopolysaccharide.
 Structure of Bacteria
6. Glycocalyx:
Glycocalyx - the polysaccharide-containing material produced inside the
cell and extruded onto the cell’s surface when growing in their natural
environments.
The glycocalyx plays a role in the adherence of bacteria to surfaces in
their environment, forming BIOFILMS. Glycocalyx includes both slime
layers + capsule (polysaccharide)

Slime layer & Capsule polysaccharide:
Capsule: thick; tightly-packed organised layer; tightly-associated with
envelope; contributes to the invasiveness of pathogenic bacteria
(virulence factor); protects from phagocytosis.
Slime layer: thin; loosely or unorganised layer; loosely-associated with
cell.
 Structure of Bacteria
7. External Structures of Bacterial Cells:
a) Flagella:
Flagella are thread-like appendages composed of several thousand
protein subunits called flagellin. The flagellin of different bacterial
species differ in structure. They are highly antigenic (H antigens), and
some of the immune responses to infection are directed against them.

The flagellum is attached to the bacterial cell by a complex structure
consisting of a hook & basal body. There are 4 flagellar arrangements:
Monotrichous (single polar flagellum on one side)
Amphitrichous (single polar flagellum on both sides)
Lophotrichous (a tuft of multiple polar flagella)
Peritrichous (flagella distributed over the entire cell).
 Gram + Gram -

FIGURE 5 Proximal structure of bacterial flagella. (a) Detail of flagellar structure of
a Gram-positive cell. (b) Detail of flagellum of a Gram-negative bacterium.
 Structure of Bacteria
Bacteria move with alternating series of:
TUMBLEs - clockwise flagellar rotations that produce movements
where each flagellum rotates independently.
RUNS - counterclockwise flagellar rotations that produce “bundled”
flagella, leading to movements of cell in one direction
Movement toward a favorable stimulus is positive taxis, whereas
movement away from an unfavorable stimulus is negative taxis.

Spirochetes (subgroup of bacteria) have endoflagella at both ends that
spiral tightly around the cell. Rotation of endoflagella causes the axial
filament to rotate around the cell, causing a “corkscrew” movement.
FIGURE 6 Motion of a peritrichous bacterium. In peritrichous bacteria, runs occur
when all of the flagella rotate counterclockwise and become bundled. Tumbles occur
when the flagella rotate clockwise, become unbundled, and the cell spins randomly.
 Structure of Bacteria
b) Pili:
They are surface appendages shorter than flagella and composed of
protein subunits termed PILINS. There are TWO types of pili:

 Ordinary pili: responsible for the adherence of bacteria to host cells;
 Sex pili: responsible for the attachment of donor and recipient cells
during the process of bacterial conjugation.

The virulence of certain pathogenic bacteria depends on the production
of these “colonization antigens” i.e. ordinary pili that provide the cells
with adherent properties. These pili elicit the formation of host
antibodies.
*Antibodies against pili of one bacterial species will NOT prevent the attachment of
another species.
 Structure of Bacteria
c) Fimbriae:
Fimbriae are rod-like proteinaceous extensions. These sticky, bristle-like
projections adhere to one another and to substances in the environment.
There may be hundreds of fimbriae per cell.

*e.g. Neisseria gonorrhoeae is a bacterium with fimbriae able to colonise
the mucous membrane of the reproductive tract.

Fimbriae also have an important function in biofilms (slimy masses or
communities of microbes, enclosed in polymeric matrix, adhering to a
substrate or foreign surface, via fimbriae). They act as electrical wires,
conducting electrical signals among cells in a biofilm.
FIGURE 7 Proteus vulgaris FIGURE 8 Two Salmonella cells
has flagella and fimbriae. are connected by a pilus.
 Structure of Bacteria
d) Endospores:
Bacillus spp. and Clostridium spp. are capable of forming endospores.
They undergo a cycle of differentiation in response to environmental
conditions: The process of ‘sporulation’, is triggered by near depletion of
several nutrients (carbon, nitrogen, or phosphorous).

Each cell forms a single internal spore - liberated when the mother cell
undergoes autolysis.

The spore is highly resistant to heat and chemical agents; when returned
to favorable nutritional & environmental conditions, the spore
germinates to produce a single vegetative cell.
Vegetative cell Spore
FIGURE 9 The formation of an endospore. The steps depicted occur over a period of 8–10 hours.
 Classification of Bacteria
I. Taxonomy of Bacteria:
The following are interrelated areas of bacterial taxonomy:
Identification: is the use of a classification scheme to
(I) isolate and distinguish specific organisms among the mix of complex
microbial flora,
(II) verify the special properties of a culture in a clinical setting, and
(III) isolate the causative agent of a disease.

Classification: is the categorisation of organisms into taxonomic groups
by using morphological, biochemical and genetic properties.

Nomenclature: is the naming of an organism by an established group of
scientific and medical professionals.
Figure 10 How the structural and biological characteristics of bacteria can
be used in classification, taking Gram-positive bacteria as an example.
 Classification of Bacteria
II. Criteria for Identification
a) Growth on Media (Culture):
Bacterial classification includes growth on different types of
bacteriological culture media which can be classified into several types:
e.g. enriched media such as blood agar, selective media such as bile salt
agar, and differential media such as MacConkey agar.

FIGURE 11 Bacterial
colonies on a blood agar
Differences in colony
size, shape, and color
indicate the presence of
different species.
 Classification of Bacteria
b) Bacterial Microscopy:
The Gram stain, together with visualization by light microscopy, has
been among the most informative methods for classifying bacteria. This
staining divides bacteria on the basis of fundamental differences in the
structure of their cell walls (Gram negative or positive).

c) Biochemical Tests: Many types
i. The oxidase test is used to distinguish organisms on the basis of the
presence or absence of a respiratory enzyme, e.g. Enterobacteriaceae
[-] from other Gram-negative rods.
ii. The catalase test is used to distinguish between the Gram-positive
cocci (i.e. staphylococci [+] and streptococci [-]).
Figure 12 The three basic
shapes of bacterial cells.
 Classification of Bacteria
d) Nutritional Requirements:
All bacteria obtain energy by oxidizing proteins & carbohydrates from
their environment. There are TWO types of metabolism:
1. Aerobic metabolism is the complete utilization of an energy source.
2. Anaerobic metabolism is the incomplete utilization of an energy
source.

e) Immunological Tests:
The word “sero” indicates the use of antibodies that react with specific
bacterial cell surface structures such as LPS, flagella, or capsule
(antigens). The terms “serotype,” “serogroups,” and “serovars” use the
specificity of these antibodies to sub-divide bacterial strains. During an
epidemic, it is important to identify a particular strain by these methods.
OTHER IMPORTANT JARGONS/ TERMS RELATED
TO THE PATHOGENESIS OF INFECTION
Nonpathogen:
o A microorganism that does not cause disease;
may be part of the normal flora.
Pathogen:
o A microorganism capable of causing disease.
Opportunistic pathogen:
o A microorganism capable of causing disease only
when the host's resistance is impaired
(when the patient is "immunocompromised").
Carrier:
o A person or animal with asymptomatic infection,
that can be transmitted to another susceptible
person or animal.
Adherence (adhesion, attachment):
o The process by which bacteria stick to the
surfaces of host cells.
o Once bacteria have entered the body, adherence is
a major initial step in the infection process.

Invasion:
o The process whereby bacteria, viruses and
fungi enter the host cells or tissues and spread
in the body.
Toxigenicity:
o The ability of a microorganism to produce a
toxin that contributes to the development of
disease.

Virulence:
o The quantitative ability of a microorganism to
cause disease. – measured relative to a
standard (another microbe/host)
o Virulent organisms cause disease when
introduced into the host in small numbers.
Virulence involves adherence, invasion and
toxigenicity.
Pathogenicity:
o The ability of an infectious microorganism to
cause disease.
Infection:
o Multiplication of an infectious microorganism
within the body. However:
 Multiplication of the bacteria that are part of the
normal flora of the GIT, skin, etc. is generally not
considered an infection.
 Multiplication of pathogenic bacteria even if
the person is asymptomatic, is deemed an
infection.
How Do Bacteria Cause Disease?
Bacterial pathogens often have special structures
or physiological characteristics that improve the
chances of successful host invasion and infection.
Virulence factors are structural or physiological
characteristics that help organisms to cause
infection and disease.
Examples of Virulence factors include:
1) Adherence factors – e.g. pili
2) Bacterial exotoxins & endotoxins
3) Enzymes
# Tissue-degrading enzymes – e.g. coagulase
# IgA1 proteases
4) Antiphagocytic factors – e.g. capsule, surface antigens
5) Intracellular pathogenicity – ability to survive within
phagocytes
6) Antigenic heterogeneity / genetic variation
7) Requirement for iron (essential nutrient for mircroorganisms;
affects virulence)
8) Bacterial biofilms
 References
Carroll K.C., Morse S.A., Mietzner T., Miller S. (2016). Jawetz, Melnick & Adelberg’s
Medical Microbiology (27th Edition). SECTION I: Fundamentals of Microbiology. (pp 1-
126). USA: McGraw Hill.

Goering R.V., Dockrell H.M., Zuckerman M., Roitt I.M., Chiodini P.L. (2013). Mims'
Medical Microbiology (5th Edition). SECTION 1: The Adversaries – Microbes. (pp 3-63).
USA: Elsevier Saunders.

Bauman R.W. (2015). Microbiology with Diseases by Body System (4th Edition). (pp 56-
94). USA: Pearson Education.