This slide covers briefly how intracellular and extracellular bacteria elicits an immune response, how bacteria evade from the immune system, what complement system is, opsonization, neutralisation, septic shock, sepsis, superantigens, phagocytosis, interleukins, Toll-like receptors, a list of diseases caused by bacterias and their names etc.
1. Immunity Against infectious
diseases by Bacteria
NOIDA INSTITUTE OF ENGINEERING AND TECHNOLOGY, GREATER NOIDA
By: Rohit Satyam, 2nd Year, Department of Biotechnology
2. Group Members
1. Aqueel Haider
2.Nishtha Singh
3.Rohit Satyam
4.Srishti Singh
5.Rohit Panchal
Bac . teria: The Back door
of cafeteria.
3. .
IMMUNITY TO EXTRACELLULAR BACTERIA
Extracellular bacteria are capable of replicating outside host
cells, for example, in the blood, in connective tissues, and in
tissue spaces such as the lumens of the airways and
gastrointestinal tract
Disease is caused by two principal mechanisms.
1. First, these bacteria induce inflammation, which results in
tissue destruction at the site of infection.
2. Second, bacteria produce toxins, which have diverse
pathologic effects. The toxins may be endotoxins, which are
components of bacterial cell walls, or exotoxins, which are
secreted by the bacteria. The endotoxin of gram-negative
bacteria, also called lipopolysaccharide (LPS) is a potent
activator of macrophages, dendritic cells, and endothelial
cells
4. For instance
1. Diphtheria toxin shuts down protein synthesis
in infected cells.
2. cholera toxin interferes with ion and water
transport.
3. tetanus toxin inhibits neuromuscular
transmission.
4. Anthrax toxin disrupts several critical
biochemical signalling pathways in infected
cells.
5. Innate Immunity to
Extracellular
Bacteria
The principal mechanisms of
innate immunity to
extracellular bacteria are
complement activation,
phagocytosis, and the
inflammatory response.
Fig 1: Phagocytosis
6. 1. Opsonization is a term that refers to an immune
process where particles such as bacteria are targeted
for destruction by an immune cell known as a
phagocyte .
The process of opsonization is a means of identifying
the invading particle to the phagocyte.
Eg: opsonin include: C3b, Antibodies
Know the Technical Jargons First
7.
8. 2. What is the complement system?
Ans: The complement system is a set of over 20 different
protein molecules always found in the blood. There are no
cells in the system. With an infection, this system of
molecules is activated, leading to a sequence of events on
the surface of the pathogen that helps destroy the
pathogen and eliminate the infection.
It activates immune system, kill cells and participate in
opsonisation
9. How is the complement system activated?
It can be activated in two main ways:
1. Classical Pathway: It is the second and most
potent means in a specific immune response
when antibodies (IgG or IgM) binds to antigen at
the surface of a cell. This exposes the Fc region
of the antibody in a way that allows the first
complement protein (C1) to bind.
2. Alternative Pathway: It is the first means of
activation and is a part of the innate immune
response. (i.e.; neither antibodies nor T cell
receptors are involved.) For example, certain
polysaccharides found on the surface of bacteria
can activate the system (by directly binding to
C3b). This can occur immediately and does not
require prior exposure to the molecules.
11. Notice how complement
C3 is cleaved
into C3b and C3a. C3b
remains bound to the
complex at the surface of
the microorganism. This
not only activates the
next step, but also C3b is
a good opsonin. The
small peptide, C3a
diffuses away and acts as
a chemotactic factor and
an inflammatory factors.
Next, complement protein C5 is cleaved into C5b and C5a. The C5b remains bound
to complex on the surface of the cell while the C5a diffuses away and acts much like
C3a.
Classical Pathway
12.
13. What happens as a result of
the activation?
But in either case, a cascade of events follows, in
which each step leads to the next. At the center of
the cascade are steps in which the proteolysis of a
complement protein leads to a smaller protein and
a peptide.
The smaller protein remains bound to the complex
at the surface of the microorganism, while the
peptide diffuses away.
14.
15. 3. What is neutralisation?
Covering an antigen in antibodies make it less
infectious and less pathogenic. Neutralisation
or neutralization in the immunological sense refers
to the ability of specific antibodies to block the
site(s) on bacteria and their toxins or viruses that
they use to enter their target cell.
16. Neutralization is mediated by high-affinity IgG, IgM,
and IgA isotypes, the latter mainly in the lumens of
mucosal organs.
Opsonization is mediated by some subclasses of
IgG, and complement activation is initiated by IgM
and subclasses of IgG.
17. 4. Interleukins
•These are a group of cytokines (secreted proteins and signal molecules) that
were first seen to be expressed by white blood cells (leukocytes).
•The function of the immune system depends in a large part on interleukins,
and rare deficiencies of a number of them have been described, all
featuring autoimmune diseases or immune deficiency. The majority of
interleukins are synthesized by helper CD4 T lymphocytes, as well as
through monocytes, macrophages, and endothelial cells. They promote the
development and differentiation of T and B lymphocytes,
and hematopoietic cells.
•There are IL1……IL17 families of IL
NOTE: IL-17: differentiation and proliferation of lymphoid progenitor cells,
involved in B, T, and NK cell survival, development, and homeostasis, ↑pro-
inflammatory cytokines
18.
19.
20. •Some surface antigens of bacteria such as gonococci and Escherichia coli are
contained in their pili, which are the structures responsible for bacterial
adhesion to host cells.
•The major antigen of the pili is a protein called pilin. The pilin genes of
gonococci undergo extensive gene conversion, because of which the progeny
of one organism can produce up to 106 antigenically distinct pilin molecules.
•This ability to alter antigens helps the bacteria evade attack by pilin-specific
antibodies, although its principal significance for the bacteria may be to
select for pili that are more adherent to host cells so that the bacteria are
more virulent.
•Changes in the production of glycosidases lead to chemical alterations in
surface LPS and other polysaccharides, which enable the bacteria to evade
humoral immune responses against these antigens.
21.
22. Injurious Effects of Immune Responses to
Extracellular Bacteria
The principal injurious consequences of host responses to
extracellular bacteria are inflammation and septic shock.
Septic shock is a serious medical condition that occurs
when sepsis, which is organ injury or damage in response
to infection, leads to dangerously low blood pressure and
abnormalities in cellular metabolism
23. Sepsis is a life-threatening condition that arises when the body's response
to infection injures its own tissues and organs.Common signs and
symptoms include fever, increased heart rate, increased breathing rate,
and confusion
The early phase of septic shock is caused by cytokines produced by
macrophages that are activated by bacterial cell wall components,
including LPS (Lipo-Polysaccharide) and peptidoglycans.
Tumor necrosis factor (TNF), IL-6, and IL-1 are the principal cytokine
mediators of septic shock, but IFN-γ (Interferon Gama) and IL-12 may
also contribute.
This early burst of large amounts of cytokines is sometimes called a
cytokine storm.
24. Superantigens (SAgs) :
Are a class of antigens that cause non-specific activation of T-cells resulting
in polyclonal T cell activation and massive cytokine release. SAgs are produced
by some pathogenic viruses and bacteria most likely as a defence mechanism
against the immune system.
Active T Cells(excess) (Excess)cytokines esp. Interferon gamma (IFN-
ɣ) (Excess) Macrophage Activation pro-inflammatory
cytokines (TNF, IL-1, IL-6)
In normal circumstances it is released locally in low levels and helps the
immune system defeat pathogens. However, when it is systemically released in
the blood and in high levels (due to mass T-cell activation resulting from the
SAg binding), it can cause severe and life-threatening symptoms,
including shock and multiple organ failure.
25.
26.
27.
28. There is some evidence that the progression of septic shock is
associated with defective immune responses, perhaps related to
depletion or suppression of T cells, resulting in unchecked
microbial spread.
29. Immune Evasion by Extracellular Bacteria
They know how to befool your Security System
Bacteria with polysaccharide-rich capsules resist phagocytosis
and are therefore much more virulent than strains lacking a
capsule. The capsules of many pathogenic Gram-positive and
Gram-negative bacteria contain sialic acid residues that inhibit
complement activation by the alternative pathway.
A mechanism used by bacteria to evade humoral immunity is
variation of surface antigens.
30. The innate immune response to intracellular bacteria
is mediated mainly by phagocytes and natural killer
(NK) cells.
Phagocytes, initially neutrophils and later macrophages,
ingest and attempt to destroy these microbes, but
pathogenic intracellular bacteria are resistant to degradation
within phagocytes.
Innate Immunity against Intracellular
Bacteria
31. Toll-like receptors (TLRs) are a class of proteins that play a
key role in the innate immune system. They are single,
membrane-spanning, non-catalytic receptors usually
expressed in APCs such as macrophages and dendritic cells
.
Once these microbes have breached physical barriers such
as the skin or intestinal tract mucosa, they are recognized
by TLRs, which activate immune cellresponses.
TLRs
32. Bacteria may enter mammalian cells by phagocytosis or
by facilitating their own uptake, termed invasion. During
the process of phagocytosis or invasion, innate immune
sensors like the Toll-like receptors (TLRs) or Nod-like
receptors (NLRs) may be triggered by bacterial ligands.
The signalling pathways activated by TLRs and NLRs have
been extensively reviewed elsewhere and predominantly
lead to expression and activation of pro-inflammatory
cytokines
33. Intracellular bacteria activate NK cells by inducing expression of
NK cell–activating ligands on infected cells and by stimulating
dendritic cell and macrophage production of IL-12 and IL-15,
both of which are NK cell– activating cytokines.
The NK cells produce IFN-γ, which in turn activates
macrophages and promotes killing of the phagocytosed
bacteria.
Thus, NK cells provide an early defense against these microbes,
before the development of adaptive immunity.
34. Adaptive Immunity to Intracellular Bacteria
The major protective immune response against intracellular
bacteria is T cell–mediated recruitment and activation of
phagocytes (cell-mediated immunity).
Individuals with deficient cell-mediated immunity, such as
patients with AIDS, are extremely susceptible to infections with
intracellular bacteria (as well as intracellular fungi and viruses).
35.
36. As we know, T cells provide defence against infections by two
types of reactions:
1. CD4+ T cells activate phagocytes IFN-γ and other factors,
resulting in killing of microbes that are ingested by and
survive within phagocytes. These stimuli activate
macrophages to produce several microbicidal substances,
including reactive oxygen species, nitric oxide, and
lysosomal enzymes. CD4+ T cells differentiate into TH1
effectors under the influence of IL, which is produced by
macrophages and dendritic cells.
2. CD8+ cytotoxic T lymphocytes (CTLs) kill infected cells,
eliminating microbes that escape the killing mechanisms of
phagocytes.
37. Phagocytosed bacteria stimulate CD8+ T cell responses if
bacterial antigens are transported from phagosomes into the
cytosol or if the bacteria escape from phagosomes and enter
the cytoplasm of infected cells.
In the cytosol, the microbes are no longer susceptible to the
microbicidal mechanisms of phagocytes, and for eradication of
the infection, the infected cells have to be killed by Cytotoxic
TLs.
Thus, the effectors of cell-mediated immunity, namely, CD4+ T
cells that activate macrophages and CD8+ Cytotoxic TLs,
function cooperatively in defense against intracellular bacteria
38. Immune Evasion by Intracellular Bacteria
Intracellular bacteria have developed various strategies to resist
elimination by phagocytes. These include
1. Inhibiting phagolysosome fusion
2. Escaping into the cytosol, thus hiding from the microbicidal
mechanisms of lysosomes, and directly inactivating microbicidal
substances such as reactive oxygen species.
Resistance to phagocyte-mediated elimination is also the reason that
such bacteria tend to cause chronic infections that may last for years,
often recur after apparent cure, and are difficult to eradicate.
39.
40.
41. Refrences:
1.Wikepedia
2.Abul K. Abbas Andrew H. H. Lichtman Shiv
Pillai-Cellular and Molecular Immunology
3.NCBI
4. McGraw-Hill Global Education Holdings, LLC