This presentation answers the following questions!!
How Immune Cells communicate with each other?
Receptors of Immune System?
Receptors of Innate Immune System?
What are PRRS?
What are PAMPS?
What are DAMPS?
What is the structure of PRRS?
What is the mechanism of PRRS?
What are the types of PRRS?
What is the role of PRRS in Immunology?
6. Ligand
Receptor
Receptors are specialized proteins located on
the surface or within cells that are capable of
recognizing and binding to specific molecules,
such as hormones, neurotransmitters, antigens,
or other signaling molecules.
They play critical roles in various biological
processes by initiating cellular responses upon
ligand binding.
9. IMMUNE
RECOGITION
& RESPONSE
The immune system is our body's defense network
against a wide array of pathogens, including
bacteria, viruses, fungi, parasites etc, that seek to
invade and harm the body.
Immune recognition (detection of threats)
Immune response (activation of defense
mechanisms)
Challenges of immune system includes
elimination of antigen and communication with
other immune cells
12. Adaptive immunity is the third line of defense and provides a slow, specific response to any
foreign invader.
It is known as Specific Recognition as the recognition is against specific antigens unique to
individual pathogens or foreign substances.
It includes two type of responses
Humoral Response or Antibody-mediated Response on B-cells
Cell mediated Response on T-cells
13. T-CELL RECEPTORS
Cells: T-Cells
Receptors: TCR (T-Cell Receptors)
Nature of Receptors: Always membrane bounded
Human T- cell (From SEM) Binding of T-cell receptor with Antigen
Structure of T- cell Receptor
18. Innate immunity is the first line of defense and provides a rapid, non-specific response to any
foreign invader.
Innate immune system includes all aspects of the host’s immune defense mechanisms that are
encoded in their mature functional forms by the germ-line genes of the host.
These include Barrier Defense (First Line of Defense)
Internal Defense (Second Line of Defense)
20. Pattern Recognition Receptors (PRRs) are a class of
proteins that play a crucial role in the innate immune
system's ability to detect and respond to pathogens.
PRRs are specialized in recognizing conserved
molecular patterns, known as Pathogen-Associated
Molecular Patterns (PAMPs), which are commonly
found on the surface of various microorganisms.
26. Extracellular Domain:
Many PRRs have an extracellular domain that is
responsible for ligand recognition.
Transmembrane Domain:
PRRs that are located on the cell surface or within
endosomes typically have a transmembrane
domain that anchors them to the cell membrane.
Cytoplasmic Domain:
The cytoplasmic domain of PRRs is involved in
signal transduction following ligand binding.
30. Pathogen-Associated Molecular Patterns (PAMPs) are conserved molecular structures
commonly found on pathogens but not on host cells.
These patterns are recognized by Pattern Recognition Receptors (PRRs) of the innate
immune system, triggering immune responses aimed at eliminating the invading
pathogens.
PAMPs are essential components of the host-pathogen interaction and play a crucial
role in the initiation of the innate immune response.
33. Damaged-Associated Molecular Patterns (DAMPs)
are endogenous molecules that are released by
stressed, injured, necrotic or dying cells.
These patterns are also recognized by Pattern
Recognition Receptors (PRRs) of the innate immune
system, triggering immune responses ad alerting the
presence of cellular damage or stress.
For example intracellular DNA, RNA can act as
DAMP when released into extracellular space.
35. Recognition and Binding of Pathogen-Associated Molecular Patterns (PAMPs)
• PRRs recognize specific molecular patterns known as PAMPs, which are commonly found on pathogens
but are absent or rare in host cells.
Activation and Signaling
• Upon binding to their specific ligands (PAMPs), PRRs undergo conformational changes that lead to the
activation of downstream signaling pathways.
• This activation triggers a series of intracellular events, including the recruitment of adaptor proteins and
the activation of transcription factors like NF-κB and IRFs (interferon regulatory factors).
36. Cytokine and Chemokine Production
• Activated PRRs induce the production of pro-inflammatory cytokines (e.g., interleukins, tumor
necrosis factor) and chemokines that orchestrate the recruitment and activation of immune cells to
the site of infection.
• These mediators amplify the immune response and coordinate the elimination of pathogens.
Antimicrobial Responses
• PRR activation leads to the induction of antimicrobial mechanisms, such as the production of
antimicrobial peptides, reactive oxygen species (ROS), and nitric oxide (NO), which directly target
and kill pathogens.
Inflammatory Responses
• PRR activation also contributes to the initiation of inflammation, which is a crucial component of
the immune response against pathogens.
• Inflammation helps to contain and eliminate the infection but must be carefully regulated to avoid
excessive tissue damage.
Linking Innate and Adaptive Immunity
• PRR activation bridges the innate and adaptive immune responses by influencing antigen
presentation, co-stimulatory molecule expression, and cytokine production, which are essential for
the activation and regulation of adaptive immune cells (e.g., T and B lymphocytes).
41. Discovered 1st in the family of PRR in Drosophila.
It is a pattern recognition molecule of innate immune system.
STRUCTURE:
NATURE: Type I transmembrane proteins
DOMAINS:
N-terminal domain (NTD):
Located outside the membrane
Middle single helix transmembrane domain:
Traverses the membrane
C-terminal domain (CTD):
Located towards the cytoplasm
43. LIGAND: It recognizes Peptidoglycan, Flagellin, viral nucleic acids (RNA and DNA), lipoproteins, and
other microbial components.
RESPONSE: Upon ligand binding, TLRs initiate signaling cascades leading to the activation of
transcription factors like NF-κB and IRF3/7 that results in the production of pro-inflammatory cytokines,
type I interferons, and other molecules that mediate the immune response.
45. It is a pattern recognition molecule of innate
immune system.
STRUCTURE: CLRs are a diverse group of
proteins characterized by the presence of one or
more C-type lectin-like domains (CTLDs),
which are involved in carbohydrate recognition.
.
46. PRESENCE: Expressed on plasma
membrane of various immune cells.
TYPES: CLRs can be further classified
based on their structure and function into
several subgroups, including simple CLRs,
transmembrane CLRs, and soluble CLRs
47. LIGAND: CLRs recognize a wide
range of carbohydrate structures,
including mannose, fructose, and
galactose residues present on
pathogens (PAMPs) and self-antigens.
Some CLRs can also recognize
glycosylated proteins and lipids.
RESPONSE: Upon ligand binding,
CLRs can trigger various immune
responses, including phagocytosis,
cytokine production, antigen
presentation, and modulation of
immune cell activation and
differentiation.
49. It is a pattern recognition molecule of innate immune system.
STRUCTURE: NLRs are characterized by the presence of a central nucleotide-
binding and oligomerization domain (NACHT), which is involved in oligomerization
and signaling.
They also contain leucine-rich repeats (LRRs) at the C-terminus, which are
responsible for ligand recognition, and a variable N-terminal effector domain that
determines their downstream signaling functions.
.
50. PRESENCE: Cytoplasmic receptors
LIGAND & RESPONSE: NLRs play a
crucial role in the recognition of
intracellular pathogens, as well as in the
sensing of endogenous danger signals.
Upon activation by microbial
components or cellular stress signals,
NLRs can oligomerize and initiate
signaling cascades that lead to the
production of inflammatory cytokines
and the induction of antimicrobial
responses.
55. Detection of Pathogens
Initiation of Immune Responses
Linking Innate and Adaptive Immunity
Tolerance and Autoimmunity
Tissue Repair and Resolution of Inflammation