Session 2 PDF - Immune System

Summary

This document is a presentation on immune system receptors, signaling, and cytokines. It includes diagrams of the process and several questions to prompt further discussion and understanding among learners.

Full Transcript

Sensations:
Receptors and
signalling
Dr. Chirag C. Sheth
supporting literature

Kuby Chapters Research
Chapter 3 AP-1 NF-kB NFAT Pathways
Innate Lymphoid Cells

CXC44 and HIV TCR / TLR
HIV-membrane Fusion Overview of TCR
CXCR4-HIV TLR Minireview
discuss…
01.
What are the cytoplasmic signalling
molceules, and what do they do?.

02.
What are the principal functions of TNF?

03.
What are the three main transcription
factors participating in antigen-dependent
T-cell activation, and how do they work?
session 2

"Good communication is as
stimulating as black coffee, and
just as hard to sleep after." -
Anne Morrow Lindbergh
let’s bond... 01 non-covalency
In immunology, cell-to-cell
communication occurs via receptor-
ligand interactions (non-covalent)

affinity
02 Normally, the strength of the
individual bonds tend to be weak

avidity
03 Multiple bonds occur, resulting in a
high cumulative bind strength

valency
04 Increasing valency of the receptors is a
mechanism to increase avidity
““We are only as strong
as we are united, as weak
as we are divided.”
— J. K. Rowling
‘Harry Potter and the Goblet of Fire’
 space
Receptor expression can be
targeted and oriented in response
to external cues.

time
Receptor expression can change
during the course of an infection
process.
when receptor meets ligand…
When a ligand
binds to a receptor, In turn, these
it causes*: changes in the
receptor result in*:
Conformational change
Enzyme activation
Dimerization + clustering
Intracellular remodelling
Changes in membrane
location
Relocation of molecules
Covalent modifications
*any combination
*any combination
benefits of
multimerization
Cell-cell interactions rely on a
binding affinity to maintain contact
over long periods of time

Extended contact facilitates signal
transduction and exchange of
cytokine signals
adaptive immune receptors
 Ig BCR
Immune receptors bear The B-cell receptor binds
immunoglobulin domains foreign antigens. It is known as
an antibody when secreted.

Quick Tm | Cs | Se TCR
Immune receptors can be The T-cell receptor recognises
reference transmembrane, cytosolic foreign or self-peptides
or secreted presented on MHC molecules

COO- CD4 | CD8
The carboxyl terminus is These are T-cell co-receptors
lacking in secreted that help to define T-cell subset
immunoglobulins functions.
co-receptors are key
Antigen-immune system receptor interactions are enhanced by co-
receptor binding

These are separate receptor-ligand interactions that may
take place near the original interaction

Often times, a single type of interaction may be insufficient
to lead to an activation event

A co-receptor interaction may provide a second signaling
interaction to further signal the cell to proceed with activation
immunoglobulin
2-D model space-fill model

Two heavy chains (variable and constant regions)
Two light chains (variable and constant regions)
Held together by intra-/interchain disulfide covalent bonds
 structural differences
Secreted antibodies are grouped into
five major isotypes (classes)

IgA: alpha (α) heavy chain
IgD: delta (δ) heavy chain
IgE: epsilon (ε) heavy chain
IgG: gamma (γ) heavy chain
IgM: mu (μ) heavy chain

Each class performs different functions
during immune responses

Light chain isotypes are
Kappa (κ)
Lambda (λ)
immunoglobulin (BCR)
Extend the “arms” of Antigen binding domain
the antibody away Each Ab can bind two
from the hinge region antigen molecules

Glycosylation helps Contains proline, making it
spread heavy-chain flexible
domains apart Also cysteine, facilitating
Also play a functional heavy-chain dimerization
role through interchain disulfide
bond formation

Membrane-bound Ab has an extracellular hydrophilic 26 amino acid “spacer”, a 25 amino acid
hydrophobic transmembrane segment and a very short three amino acid cytoplasmic tail
Secreted Ab is formed by alternative RNA splicing mechanisms that remove/replace these regions
T-cell receptor
Contains immunoglobulin domains (similar to
BCR)

Two subunits, α and β, each have a
Constant region and Variable region

Variable regions have three CDRs forming
peptide specific binding site

Constant regions each contain
transmembrane regions

Two TCR types, αβ (more common) and γδ, have
diverse antigen binding characteristics
 TCR
signal transduction via CD3 complex.
Receptor-associated molecules CD4
(avidity) and CD28 (required for naive
cell activation).

BCR
signal transduction via Iga and Igb.
Receptor-associated molecules CD19,
CD21 and CD81 (transmit and relay
signals to cell interior
innate immune receptors
pattern recognition receptors (PRRs)
PRRs recognize Pathogen Associated Molecular Patterns (PAMPs)

Receptors for PAMPs may uniformly recognize large numbers of
pathogens that share the same PAMPs

Receptors for PAMPs are not clonally distributed but are expressed
equally on the same cell types

Receptors for PAMPs may be integral membrane proteins or
intracellular proteins

PAMPs represent motifs of recurring patterns on bacteria, yeast, and
parasites
 human PRRs
Full name Cellular location(s) Ligands Cellular functions

TLR Toll-like receptor Plasmamembrane, Microbial carbohydrates, Production of antimicrobials,
endosomes, Lysosomes lipoproteins, fungal mannans, antivirals, and cytokines;
bacterial flagellin, viral RNA, inflammation
self-components of damaged
tissues, etc.

CLR C-type lectin receptor Plasma membrane Carbohydrate components of Phagocytosis, production of
fungi, mycobacteria, viruses, antimicrobials and cytokines;
parasites, and some allergens inflammation

RLR Retinoic acid inducible Cytosol Viral RNA Production of interferons and
gene-I (RIG-I)-like receptor cytokines
NLR Nucleotide oligomerization Cytosol Fragments of intracellular or Production of antimicrobials
domain (NOD)-like receptor extracellular bacteria cell wall and cytokines; inflammation
peptidoglycans
ALR Absent-in-melanoma Cytosol and nucleus Viral and bacterial DNAs Production of interferons and
(AIM)-like receptor cytokines
now for the signalling molecules
Basic information…
Cytokine signals are usually generated by the binding of a ligand
to a complementary cell-bound receptor

Cytokine-receptor binding is noncovalent, although it may be of
generally high affinity

Cytokine-signaling end results often induce a change in the
transcriptional program of the target cell

A cytokine signal is any event that instructs a cell to change its
metabolic or proliferative state
How they work
Cytokines are proteins that mediate the effector functions of the immune
system

They can act in several different ways…

Endocrine action ‒ released into the bloodstream to effect distant
cells

Paracrine action ‒ released to effect nearby cells

Autocrine action ‒ released, but then bind to receptors on the cell
that produced them
 pleiotropic
cytokine action… 01 activity induces different biological effect
dependent on target cell

redundant
02 activity mediates similar effects on target
cell

synergy
03 effect combines two cytokine activities to
be greater than additive effect

antagonistic
04 effect inhibits one cytokine’s effect by
another’s action

cascade
05 effect of one cytokine on one target cell to
produce additional cytokine(s)
practical
examples
 the six cytokine families
Family name Representative members of family Comments

Interleukin-1 family IL-1α, IL-1β, IL-1Ra, IL-18, IL-33 IL-1 was the first noninterferon cytokine to be identified.
Members of this family include important inflammatory
mediators.
Class 1 (hematopoietin) IL-2, IL-3, IL-4, IL-5, IL-6, IL-7, IL-12, IL-13, Members of this large family of small cytokine molecules
cytokine family IL-15, IL-21, IL-23, GM-CSF, G-CSF, exhibit striking sequence and functional diversity.
growth hormone, prolactin,
erythropoietin/hematopoietin
Class 2 (interferon) IFN-α, IFN-β, IFN-γ, IL-10, IL-19, IL-20, IL- While the IFNs have important roles in antiviral
cytokine family 22, IL-24 responses, all are important modulators of immune
responses.
Tumor necrosis factor TNF-α, TNF-β, CD40L, Fas (CD95), BAFF, Members of this family may be either soluble or
family APRIL, LT-β membrane-bound; they are involved in immune system
development, effector functions, and homeostasis.
Interleukin-17 family IL-17 (IL-17A), IL-17B, IL-17C, IL-17D, IL- This is the most recently discovered family; members
17F function to promote neutrophil accumulation and
activation and are proinflammatory.
Chemokines IL-8, CCL19, CCL21, RANTES, CCL2 All serve chemoattractant function.
(MCP-1), CCL3 (MIP-1α)
 IL-1 family
Cytokines of the IL-1 family promote inflammation

IL-1 stimulated by viral, parasitic, or
bacterial antigens

IL-1 Secreted very early in immune responses by
macrophages and dendritic cells

Acts locally on capillary permeability and to
pull leukocytes to infected tissues

Acts systemically to signal the liver to
produce acute phase proteins

Can help to activate adaptive immune responses
 class 1 family
Class I cytokines are diverse in action and cell
target

Structurally class I cytokines are a single protein

Class 1 family

Most of class I cytokines are made up of multiple
subunits
Cytokines recognized by
Common cytokine
receptors bearing that common
receptor subunit
subunit
γc IL-2, IL-4, IL-7, IL-9, IL-15, IL-12
βc IL-3, IL-5, GM-CSF
gp130 IL-6, IL-11, LIF, OSM, CNTF, IL-
27
 IFN family
Type I interferons

IFN-α and IFN-β are 18–20 kDa dimers with antiviral effects

Secreted by activated macrophages and dendritic cells

IFN
Induce synthesis of ribonucleases and inhibit protein synthesis

Type II interferon (IFN-γ)

Dimer produced by activated T/NK cells

Potent modulator of adaptive immunity

Type III interferon family (IFN-λ)

Secreted by plasmacytoid dendritic cells

Upregulate genes controlling viral replication and host cell
proliferation
 TNF family
Tumor Necrosis Factor (TNF) regulates development,
effector function, and homeostasis of cells of the
skeletal, neuronal, and immune system

TNF
TNF cytokines may be soluble or membrane bound

TNF-α is proinflammatory and produced
by activated macrophages and other cell
types

TNF-β (lymphotoxin-α) is produced by
activated lymphocytes, delivering signals
to leukocytes and endothelial cells.
 Lymphotoxin-β
mem. bound TNF 01 induces lymphocyte differentiation

BAFF and APRIL
02 required for B-cell development and
homeostasis

TNF 03
CD40 Ligand (CD40L)
involved in transmitting the T-cell
differentiation signal to B cell

Fas Ligand (FasL)
04 programmed cell death - induces cell death
(apoptosis) upon ligand binding
 IL-17 family
IL-17 family cytokines are proinflammatory
molecules expressed on a variety of cells

Receptors found on neutrophils, keratinocytes,

IL-17
and other nonlymphoid cells

Tend to work at the interface of innate and
adaptive immunity

Generally exist as homodimers

Monomers range from 17.3–22.8 kDa

All are transmembrane proteins
 chemokines
Direct leukocyte migration

They are small (7.5–12.5 kDa) proteins

Ch Possess highly conserved disulfide bonds that
dictate both structure and category (six categories)

Share two, four, or six conserved cysteine residues
chemokine receptors
Are G-protein-coupled receptors (seven-pass transmembrane
proteins)
Transduce signals via interactions with a polymeric GTP/GDP-
binding G protein
Many receptors can bind to more than one chemokine
Several chemokines are able to bind to more than one
receptor
Signaling through chemokine receptors helps cells move to
different body areas
 remember…
A cellular signal is any event that
instructs a cell to change its
metabolic or proliferative state

Signals are usually generated by the
binding of a ligand to a
complementary cell-bound receptor

A cell can become more or less
susceptible to actions of a ligand by
increasing or decreasing expression
of the receptor for that ligand
 remember…
Cell signaling often induces a change
in the transcriptional program of the
target cell

Sometimes multiple signals through
multiple receptors are required to
effect particular outcomes

Integration of all signals received by
a cell occurs at the molecular level
inside the recipient cell
putting it all together
 step 02
tyrosine phosphorylation of ITAMs. CD3 (T
cells) and Igα/β (B cells). Phosphorylated
tyrosines dock adaptor proteins.

step 01
antigen binds ligand. Receptor
dimerization / multimerization.
Clustering in lipid rafts.
step 03
Adapter proteins help to gather
members of signaling pathways
Signal-inducing phosphatidyl
bisphosphate (PIP2) breakdown by
phospholipase C gamma (PLCγ) causes
an increase in cytoplasmic calcium ion
concentration

Calcium ions bind Calmodulin (CaM)
and activate it.

Calmodulin dephosphorylates NFAT
in the cytosol, activating it.

NFAT migrates to the nucleus and
activates immune-specific genes.
step 04
Ras is a G protein

Activated when GTP exchanged for
GDP Guanine-nucleotide Exchange
Factors (GEFs) activate Ras by
inducing this exchange

GTPase activating proteins (GAPs)
inhibit Ras by stimulating its ability
to break down GTP into GDP

Ras (once active) participates in
downstream signaling events
step 05
The Ras/MAP kinase cascade activates
transcription through AP-1 by these
nuclear events
Phosphorylated ERK (pERK) phosphorylates
and activates Elk-1 transcription factor
leading to production of the Fos protein

Fos is phosphorylated by ERK and binds with
phosphorylated Jun protein

This pJun/pFos combination is known as
transcription factor AP-1

AP-1 can facilitate transcription of the IL-2
gene
step 06
Phosphokinase C (PKC) activates Nuclear
factor kappa B (NF-κB)

NFκB inactive in the cytoplasm when bound
to inhibitor (IκB)
PKC phosphorylates IκB releasing it from
NFκB

Diacylglycerol activates PKC, activating IKK
complexes

IκB phosphorylation and ubiquitination
targets it for destruction

NF-κB translocates to the nucleus to
enhance transcription
Immune responses and cell signaling

Antigen signaling includes

○ Bringing dendritic cells into the required locations

○ Macrophages and neutrophils upregulate phagolysosome activity and
cytokine production

○ Dendritic cells exhibit antigen peptides on MHC class I and MHC class
II

○ Cytoplasmic proteasomes process antigen to peptides

○ Dendritic cells induced to secrete cytokine
lift off… 01 leukocytes
Increased migration into infected
tissues. chemokine and cytokine prod.

M∅ and neutrophils
02 pathogen destruction. activation of
adaptive immunity. cytokine
production.

dendritic cells
03 enhanced antigen presentation.
chemokine and cytokine production.
motility
B and T cells
04 activation. cell division and
differentiation. cytokine production.
NFAT and NFkB detail
AP-1 detail
Component B-cells T-cells

Receptor B-cell receptor – similar to antibody T-cell receptor – heterodimer, either ab
helpful summary structure. CH structure modified to bind
to cell membrane
(more common, binds MHC) or gd
(mucosal localiztion, binds MHC and
Short cytoplasmic tail other ligands).

Accessory proteins Iga and Igb with ITAM (Immuno-receptor CD3 complex (3 dimers – de, ge and
(signal transduction function) tyrosine activation motifs) [either zz or zh]. Intra-cytoplasmic tails of
CD· complex contain ITAMs

Ligand Antigens (sometimes bound to MHC class I and II
complement components eg C3d)
Co-receptors CD19, CD21 (C3d binding) and CD81 CD4 (MHC class II) and CD8 (MHC class
I) - bind non-polymorphic regions of the
MHC molecule
CD28: naïve T-cells need CD28 co-
stimulation – CD4 and CD8 alone are not
enough.

Key tyrosine kinases Syk and Lyn (membrane associated) Lck (membrane associated) and ZAP-70

Key adaptor proteins Phospholipase C; BLNK; LAT, SLP76 and GADS, PLC

Key effector molecules NFAT, NF-kB, AP1 NFAT, NF-kB, AP1
session 3 – prepare…
01.
Name and describe three components of
the innate immune system.

02.
What is the principal role of phagocytes
(neutrophils and macrophages) in natural
immunity, and what are their main
properties?

03.
If pus contains mostly neutrophils, does it
mean that macrophages do not injure host
tissues?