Lecture 2: Structure of Bacterial Cell PDF

Summary

This document is a lecture on the structure of bacterial cells. It covers the four main components of bacterial cells: cell wall, cell membrane, cytoplasm, and nucleoid. Also included are discussions of peptidoglycan, teichoic acid, outer membrane, lipoproteins, and periplasmic space. This detailed microbiology lecture is a great learning resource.

Full Transcript

General Microbiology and
Immunology
Lecture 2: Structure of Bacterial cell

Dr./ Shimaa Mohamed Ali
Sphinx University
 Structure of Bacterial Cell
Smaller and simpler in structure than eukaryotic cells, with no recognizable
organelles.
All the activities performed by organelles also take place in bacteria, but they
are not carried out by specialized structures.
The small size, simple design, and broad metabolic capabilities of bacteria
allow them to grow and divide very rapidly and to inhabit and flourish in almost
any environment.
They were first seen under a microscope by Anton van Leeuwenhoek in 1676.
As microscopes have improved, scientists have come to understand bacterial
cell structure better.
Bacterial cell structure

❑Four main essential components of the bacterial cell :
1. Cell wall.
2. Cell or cytoplasmic membrane( plasma membrane).
3. Cytoplasm.
4. Nucleoid.
 1. Cell wall

It is a rigid structure which retains bacterial cell shape in the face of all physical
and chemical treatments.
Most of the metabolic activities of the cell depend on its structure.
Structure of bacterial cell wallː
A. Peptidoglycan layer.
B. Teichoic acid layer (only in Gram-positive bacteria).
C. Outer membrane (only in Gram-negative bacteria).
D. Lipoprotein molecules.
 A. Peptidoglycan layer
Peptidoglycan = (polysaccharides +
protein)
The backbone of the peptidoglycan molecule
is composed of two derivatives of glucose
arranged in long chain :
N-acetylglucosamine (NAG)
N-acetyl muramic acid (NAM).
The NAG and NAM strands are connected by
inter peptide bridges.
Its synthesis inhibited by penicillins and
cephalosporins and it is degraded by
lysozyme.
Amount and location of peptidoglycan in
the cell wall determines whether a
bacterium is Gm +ve or Gm -ve.
In Gram-Positive Bacteria Cell Wall:

Peptidoglycan layer forms
about 50% of the cell wall
material.
There are as many as 40 sheets
of peptidoglycan in Gm +ve cell
wall.
 In Gram-Negative Bacteria Cell Wall:

Peptidoglycan makes up only 5 – 20%
of the cell wall (one or two sheets) and
is not the outermost layer but lies
between the plasma membrane and an
outer membrane.
 It gives rigid support to the cell.

Function of
Peptidoglycan??? Protect against osmotic pressure.
(Prevent cell lysis and cell
?????? dehydration)

It confers Gram reaction.
( Gram +ve or Gram –ve)
 B. Teichoic acid layer
Teichoic acids is perpendicular to the peptidoglycan sheets
which are unique to the Gram-positive cell wall.
It is a major surface component composed of a polymer of
glycerol or ribitol phosphate.
❑Function:
Major surface antigen in Gm +ve bacteria only.
Induces TNF –α, IL-1 production.
TNF –α , IL-1
Chemical messenger induce inflammation.
Secreted by inflamatory cell like mature macrophage.
Attachment of Gram-positive bacteria to mucosal cells (
host).
C. Outer membrane
❑Found in the structure of cell wall of Gram-Negative bacteria only.
❑An outer layer of lipopolysaccharides (LPS) contain very tiny pores
called Porins.
lipopolysaccharides (LPS) which composed of 3 units:
A phospholipid called lipid A (responsible for the toxic effects).
A core polysaccharide.
An outer polysaccharide (somatic or O antigen).
▪ These differences in structure can produce differences in antibiotic
susceptibility
▪ Ex: Vancomycin can kill only Gram +ve bacteria and is ineffective against
Gram -ve pathogens.
 Function of outer membrane (LPS)
1.Endotoxin: It is responsible for shock; it is released only when bacterial cells are
lysed.
2.Can bind specifically to receptors to activate macrophages.
3.Can nonspecifically activate B cells without the help of T cells.
4.Can be serotyped to classify bacteria⟾ Somatic antigen (O - antigen).
Porins:
Tiny holes or openings found in outer membrane (Gram –ve).
Porins function:
1.Transport channels across outer membrane.
2.block the entrance of harmful chemicals and antibiotics, making Gm-ve bacteria
much more resistant than Gm+ve bacteria.
 D. Lipoprotein molecules (LPP)

Set of membrane protein linked by lipid.
In gram –ve bacteria it cross-link the peptidoglycan layer and the LPS layer.
Function:
1.Adhesion to host tissue during infection.
2.Virulence.
3.Antibiotic resistance
4.Cell division
Periplasmic space.
Present only in Gm-ve bacteria

a concentrated gel-like
It's the site of B-
matrix in the space
lactamases that degrade
between the inner
penicillins and other B-
cytoplasmic membrane
lactam drugs
and the bacterial outer
(cephalosporine).
membrane.
 It's a rigid structure that maintains

Functions shape of bacteria.
Protects the cytoplasmic membrane
of the cell from bursting in hypotonic solutions.
wall Detects the response to Gram stain.
Play a role in cell division.
Structure of
bacterial cell
wall
 Cell wall deficient bacteria
A. Protoplast, spheroplast, L. forms:
There are bacteria which are treated to remove the cell wall to reproduce new generation
lacking the cell wall. The process can be induced by:
1. Destruction of the cell wall by treating the organism with an enzyme i.e. lysozyme.
2.Cultivation of the organism in presence of penicillin which inhibits the synthesis of cell-
wall substance without interfering with the growth of the organism.
If such treated cells are liberated from Gram positive cells, they are called protoplasts.
If such treated cells are liberated from Gram negative cells, they are called spheroplasts.
If these cell wall deficient cells are allowed to grow and divide, they are called L-forms.
L-forms can revert to the parental form upon removal of cell wall inhibitor.
B. Mycoplasma:
The only bacterial species that is naturally deficient in cell wall. Hence, they are pleomorphic
and resistant to penicillin.
External structures
1. The Capsule
2. Flagella
3. Pili (fimbriae)
1. The Capsule
Functions of capsules:
1. Virulence factor of many bacteria as it protects bacteria against
phagocytosis.
2. It is an immunogenic.( stimulate immune response of host )
3.used for specific identification of organisms.
4. Capsular polysaccharide used as antigens in certain vaccines ⟾
Capsular antigen (K- antigen)
5. Capsule and slime layers may play a role in the adherence of bacteria;
e.g. adherence of Viridans streptococci to the surface of teeth which lead to
the formation of plaque and dental caries.
2. Flagella
These are long, delicate, appendages attached to the bacterial cell.
They are composed of protein (flagellin) have antigenic charecters ⟾ Flagellar
antigen (H- antigen)
They are organs of locomotion (but some organisms like the spirochaetes may
move without flagella).
They are several times the length of the bacterium.
Functions of flagella:
1.Motility of bacteria towards nutrients and other attractants.
2.Identification of some bacteria by antibodies against flagellar proteins
(Flagellar antigen (H- antigen)
 Arrangement and Types of Bacterial Flagella
There are six types of flagellar arrangement:

Monotrichous: Single polar flagellum e.g. Vibrio
cholerae, Campylobacter spp.
Amphitrichous: Single flagellum at both
ends e.g. Alcaligenes faecalis
Lophotrichous: Tuft of flagella at one ends
e.g. Spirilla spp.
Cephalotrichous: Tuft of flagella at both ends
Peritrichous : Flagella surrounding the bacterial
cell. All the members of family Enterobacteriaceae,
e.g. Salmonella Typhi, Escherichia coli, Proteus spp.
Atrichous: has no flagella.
 These are very thin and short thread-like structure
found on the surface of Gram-negative bacterial
cells.
It is composed of subunits of a protein called pilin.
These are two types of pili:
3. Pili (fimbriae) a) Sex pili (Fertility-pili):
They are highly specialized hair-like structure found
in many bacteria e.g. E. coli. They play a role in the
transfer of part of the genetic material from one cell to
another thus giving rise to a simple form of sexual
reproduction.
a) Ordinary pili ( common pili):
(colonization antigens)
They mediate adherence of bacteria to specific
receptors on human cell surface which is a necessary
step in initiation of infection of some organisms.
Cytoplasmic membrane
(Cell membrane)

It is a semipermeable
phospholipid double layered
structure around the cytoplasm.
It lies inside the peptidoglycan
layer of the cell wall.
Functions:
1. Active transport of molecules into
the cell.
2. Energy generation by oxidative
phosphorylation (ATP).
3. Synthesis of precursors of cell wall.
4. Secretion of enzymes and toxins.
5. It plays a role in DNA replication.
Cytoplasm
Constituents of Cytoplasm

▪ Proteins including enzymes
▪ Vitamins
▪ Ions
▪ Nucleic acids and their precursors
▪ Amino acids and their precursors
▪ Sugars, carbohydrates and their derivatives
▪ Fatty acids and their derivatives
 Nucleoid
Unlike the eukaryotic (true)
cells, bacteria do not have a
membrane enclosed nucleus.
The nucleoid is a region of
cytoplasm where the
chromosomal DNA is located.
 Plasmids
Small extra-chromosomal DNA.
Contain genes for antibiotic resistance or virulence.
Structure:
Similar to most bacterial chromosomes, but considerably smaller.
Plasmids are covalently closed circular DNA.
In a few species linear plasmids found.
Size:
Chromosomal DNA is typically about 4000 kbp.
Plasmid DNA ranges from 1-200 kbp.
Number of plasmids: 1-700 copies of plasmid in a cell.
 Ribosomes
Consists of RNA and protein
Abundant in cytoplasm
Often grouped in long chains called
polyribosomes.
Smaller than the ribosomes in
eukaryotic cells-but have a similar
function
Bacterial ribosomes have
sedimentation rate of 70S; their
subunits have rates of 30S and 50S.
Function: responsible for protein
synthesis.
Mesosome
Mesosome are covonluted or multilaminated
membranous bodies visible by the electron
microscope.
They develop by complex invagination of
cytoplasmic membrane into the cytoplasm.
Function:
Functioning in the compartment of DNA at cell
division and at sporulation.
Having a function analogous to the eukeryotic
cell----providing a cell membranous support for
respiratory enzyme.
Bacterial Spores
They are highly resistant structures formed under unfavorable conditions by two
medically important genera of Gram-positive bacilli, the genus bacillus and the
genus clostridium.
Sporulation and germination :
Spores are formed in adverse environmental condition.
( temp., humidity, oxyen level, depletion of carbon and nitrogen , pH )
The spores are formed inside the cell and contain bacterial DNA, small amount of
cytoplasm, cell membrane, peptidoglycan and a thick keratin like coat responsible
for resistance to heat, dehydration, radiation and chemicals.
Protein and calcium dipicolinate are found in the spore core.
Once formed, the spore has no metabolite activity and can remain dormant for
many years.
When water and nutrients are available, specific enzymes degrade the coat, so
nutrients enter and germination to vegetative cell occurs.
Medical importance of spores:

The medical importance of spores is due to their resistance to heat as
they can be sterilized only by autoclave for at least 20 minutes.

1. Spores are used as indicator of sterilization process to ensure complete
sterilization.
2. Spores are used as biological weapon.

NB: Spores are not seen in clinical specimens from infected patients
because the supply of nutrients is adequate.
Try to solve
1.Enumerate bacterial structures which act as
adherence factors.
2.Mention cell structures play a role in
bacterial antigenic classification.
3.Compare between Gm –ve and Gm +ve
bacteria from the point of:
1. cell wall
2. antibiotic resistance
4.Illustrate the function of LPP.
5.Describe the plasmid , porins.
6.Write on medical importance of spores.
Thank You