BMS150 Immunology II PDF - Week 1, Spring 2023

Summary

These lecture notes cover the topic of Innate Immunity and Inflammation for the BMS 150 course. The document explains the mechanisms of innate immunity, phagocytosis, and the role of different receptors.

Full Transcript

Immunology II

Innate Immunity & Inflammation

BMS 150
Week 1
Innate Immunity—Outline
Describe the location and basic mechanism of the major barriers
of innate immunity
Describe the process of phagocytosis and mechanisms of microbe
destruction in macrophages and neutrophils
Briefly describe what is meant by the term “pattern-recognition
receptor” and “opsonin”
For Toll-like receptors:
Describe typical ligands and cellular compartments
Briefly discuss the signaling cascade that is activated with ligand
binding
For acute inflammation
Briefly describe the steps of the acute inflammatory process and their
histologic appearance
Relate specific mediators of acute inflammation to the steps of the
process
Describe the role that acute inflammation plays in protection of the
host
Innate Immunity
Mechanisms of innate immunity discriminate very
effectively between host cells and pathogens

Innate immune defenses exist in all individuals and
act within minutes - hours after an encounter with
infectious agent

Only when innate defenses are
overwhelmed/bypassed/evaded is an adaptive
immune response required
Barriers

**
Chemical Barriers
Lysozyme
Present in secretions (mucus, tears, milk, saliva)
Uses hydrolysis to break apart the peptidoglycan wall à lysis of
bacterial cell wall
Antimicrobial peptide - defensins
Small, heterogeneous, cationic peptides
kill Gram-negative and Gram-positive bacteria, some enveloped
viruses, fungi
Multiple antimicrobial effects:
§ Destabilize membranes and Pore formation in bacterial cell
walls
§ Proteolytic degradation of bacterial proteins
§ Inhibit viral binding and entry
§ Inhibit virus particle assembly
Defensins – prototypical AMPs
Defensins can act as a chemical barrier when they are
secreted by epithelial cells in a variety of mucosal surfaces
Defensins and other AMPs (i.e. cathelicidins) are also stored
in neutrophil granules and can be released within tissues in
response to inflammation
§ Can kill microbes extracellularly à released when neutrophils die
during inflammation
§ Can kill microbes intracellularly after a cell (i.e. neutrophil)
phagocytoses a pathogen
Just like many molecules and cells of the immune system,
defensins perform a number of roles – not just a chemical
barrier
Phagocytosis and Phagocytes
One of the first lines of defense if microbes do invade
tissue
Engulf and destroy microorganisms, especially bacteria
Key role in innate immunity as they can recognize,
ingest and destroy many pathogens without aid of an
adaptive immune response
§ Phagocytosis can also occur after an antibody has bound to
an antigen – the antibody can act as a “signal” that triggers
efficient phagocytosis
Macrophages and neutrophils are the major
phagocytes in the body
Phagocytic Cells
Monocytes & Macrophages:
Pro-monocytes (BM)àmonocyte (blood)à
macrophage/macrophage-like cells (tissues)
Long-lived cells resident within the tissues

Neutrophils:
Derived from hematopoietic precursors in the BM
Non-dividing, short-lived cell type in blood
(dominant WBC)
Phagocytosis – the basics

PRR = Pattern Recognition Receptor
Pattern Recognition
Evolutionarily conserved mechanism for
recognizing common, conserved ‘signs’ of microbial
infection, physiological stress, or other damage
Recognition is immediate, does not require prior
recognition, and activates several arms of the
innate (and adaptive) immune response
Responses are elicited via the engagement of
Pattern Recognition Receptors (PRRs) found on
phagocytes, in response to:
§ Pathogen Associated Molecular Patterns (PAMPs)
§ Danger Associated Molecular Patterns (DAMPs)
Pattern Recognition Receptors
Examples of PRRs:
§ Toll-like receptors
§ Nod-like
receptors
§ Lectins
Elicit responses
such as:
§ Phagocytosis
§ Cytokine
secretion
 Phagocytosis – the process
See table next slide for receptors that
1. A pattern-recognition-receptor
(PRR) binds to a microbe or bit of trigger phagocytosis
debris, OR an opsonin created by
another cell binds to the microbe
A microbe
A bit of debris
An opsonin
An opsonin is basically a
soluble, secreted PRR
that enhances the
effectiveness of
phagocytosis
An opsonin coats a
microbe, the phagocyte
has receptors for parts of
that opsonin
PRRs that trigger phagocytosis
Receptor Examples Microbial ligands
Lectin receptors Mannose receptor, dectin Bacterial, fungal, parasitic
(lectin receptors receptor cell walls
recognize “carbohydrate
patterns”)
Scavenger receptors SR-A, SR-B LPS, lipoteichoic acid –
mostly bacteria
Collagen-domain Calreticulin – binds to Collectins, ficolin – mostly
receptors particular opsonins - FYI carbohydrate groups on
bacteria
Complement receptors CR3, CR1 – binds to Mostly bacterial cell walls
complement opsonins
Fc receptors – receptor Different Fc receptor for Almost anything
for the constant region of each type of Ab – FYI for
an antibody now
Phagocytosis – the
process
2. The microbe is engulfed
– the PRR receptors signal
the cell membrane to
approach, coat and then
surround the sites where
the receptor is bound
Forms a phagosome
Mediated by
intracellular signalling
events and actin
polymerization – see
diagram
PI3 kinase seems to
be important here
 Phagocytosis – the process
3 & 4. Microbe killing – phagosomes
fuse with lysosomes as well as (in
neutrophils) primary and secondary
granules
Phagosomes have many
molecules that are effective at
cellular killing – a little more
later
Major groups include:
Reactive oxygen species
“pore”-forming proteins
or peptides
Hydrolytic enzymes
pH changes – i.e. acidic
environment of the
lysozyme
5. The microbe remnants are either digested and used, or can be excreted
from the phagocyte
Phagocytosis details à FYI
Microbe killing – so many options
After the microbe has been phagocytosed, the phagosome will
dock with a lysosome and/or neutrophil granules
Lysosomes can pretty much break down anything (acid hydrolases)
The low pH of a lysosome is also unpleasant for many bacteria
See next slide for the NAPDH oxidase complex
This complex becomes associated with the membrane of the
phagolysosome
Uses a large amount of oxygen (respiratory burst)
If a particle is too large to phagocytose, macrophages will surround
it and “place” their NADPH oxidases close to it to try to kill it
Macrophages in particular are also capable of killing cells by
inducing the synthesis of nitric oxide at high concentrations
Neutrophils have a multitude of pore-forming molecules within
their granules – these granules will fuse with the phagosome
Microbe killing via neutrophils
Neutrophil granules:
Defensins are very rich in cysteine
Form voltage-dependent pores in
bacteria that are permeable to water
Cause lysis
Cathepsin - a type of protease
Cathelicidins – another pore-forming
molecule
Causes lysis, multitude of different
structures
Lysozyme – a glycoside hydrolase
Doesn’t require an acidic pH
Found in a variety of glandular secretions
Great at killing gram +(ve) bacteria
Lactoferrin – iron-binding protein that
interferes with iron metabolism in
microbes
Microbe killing via neutrophils
Neutrophils can do a neat trick – when they’re in
an environment with many bacteria (they’re
“surrounded”) they can can lyse and release their
DNA into the ECF
§ Known as a NET – a neutrophil extracellular trap
§ NETs are “sticky” – most bacteria are trapped in the
chromatin
§ Histones are toxic to many bacteria
§ The granule contents will remain close to the NETs and
help with killing bacteria, even after the neutrophil itself
is dead
Stuck in the NET
Phagocytosis – take-aways
You need to know the following:
§ How do phagocytes recognize that something is a
“target” for phagocytosis? What’s an opsonin and how
are they involved in this process?
§ How do phagocytes kill a phagocytosed pathogen?
What is the role of:
Lysosomes
Free radicals (how are they produced? Which ones are
involved?)
Anti-microbial peptides
§ How can a NET add to host protection beyond
phagocytosis?
Pattern Recognition Receptors
Examples of PRRs:
§ Lectins
§ Toll-like receptors
§ Nod-like
receptors
Elicit responses
such as:
§ Phagocytosis
§ Cytokine
secretion
Toll-Like Receptors
Family of 10 cell membrane receptors with variable specificity for a range of
pathogens
Ligands can include LPS, dsRNA, ssRNA, DNA, Flagellin

Figure 3.7 Sensing of LPS by TLR4 on macrophages leads to activation cytokine synthesis
Toll-Like Receptors
Cytokines secreted in response to TLR’s include:
§ Inflammatory cytokines (IL-1b, IL-6, CXCL8, IL-12, TNFa)
Cytokine – a (small) protein messenger, secreted by a vast array of
cells, that can:
§ Influence the differentiation of a wide variety of cells,
including leukocytes
§ Mediate – activate or inactivate – the activity of many cells,
including leukocytes
§ Increase or decrease the production of a wide variety of
stem/hematopoietic cells
More cytokine overview in the e-learning module
§ Interferons
Interferon (IFN) alpha, beta, and lambda (IFNa, IFNb, IFNl)
Autocrine and paracrine signaling molecules that are effective
in activating macrophages, NK cells, and inducing an antiviral
state
More on interferons in subsequent lectures
Consequences of TLR signaling
The phenotype of individuals with specific gene
mutations/polymorphisms can tell us about the
overall importance and function of that gene
Example: MyD88 à An essential adaptor in TLR
signaling
§ Patients with MyD88 deficiency:
Suffer frequent and severe bacterial infections
Antiviral responses generally unaffected
§ Patients with constitutively active MyD88:
Develop various blood disorders and blood cancers:
§ Overproduction or dysregulated production of IgM
§ B cell lymphoma, marginal cell lymphoma
Nod-Like Receptors
Family of intracellular
receptors found in the
cytoplasm that detect
products derived from the
intracellular degradation
of phagocytosed
pathogens (e.g.
components of bacterial
cell wall)
Also recognize DAMPs
associated with cellular
stress
activates expression
of inflammatory cytokines
Acute inflammation

How do we get from
here…

To here?
Steps of Acute Inflammation
A. Alteration of vascular caliber - vasodilation
§ Leads to increases in blood flow at the capillary bed
due to arteriolar dilation, dilation of precapillary
sphincters
Nitric oxide and histamine
A variety of prostaglandins (PGI2, PGE2, PGD2)
Platelet activating factor (at low concentrations – higher
concentrations cause vasoconstriction)
Complement
§ C5a and C3a stimulate histamine release
 At low concentrations,
nitric oxide is a potent
vasodilator (why Viagra
is a profitable drug)

At high concentrations,
it’s capable of
destroying both
microbes and host cells
since it’s a free radical
Higher
concentrations
produced by an
inducible nitric oxide
synthase in
macrophages
Vasodilation
Arterioles and pre-capillary sphincters dilate
leading to vastly increased blood flow in inflamed
tissue
Vasodilation and fluid loss (due to increased
permeability) lead to slower blood flow
§ Known as vascular congestion
§ This helps with margination of leukocytes
Whoa… what do we need to know from
that last slide?
Prostaglandins and leukotrienes are produced when PLA2
generates arachidonic acid from membrane phospholipids
Different types of cyclooxygenases produce different types
of prostaglandins from arachidonic acid
§ Important prostaglandins – PGE2, PGD2, and PGI2 cause
vasodilation and increase vascular permeability, important acute
inflammatory mediators
Different types of 5-lipoxygenase produce different types of
leukotrienes from arachidonic acid that seem particularly
important in lung tissue
§ LTB4 – important chemotactic agent
§ Other LTs – increased vascular permeability and smooth muscle
constriction (think asthma)
Lipoxins are generated from arachidonic acid by 12-
lipoxygenase – they decrease inflammation
Steps of acute inflammation
B. Enhancement of vascular permeability
§ Capillaries and venules become more “leaky” with the
release of a number of mediators
Histamine and serotonin (released by activated
platelets, a link between inflammation and clotting)
Prostaglandins (PGD2 and PGE2)
Leukotrienes (LTC4, LTD4, LTE4)
Platelet activating factor
C3a and C5a
Bradykinin
§ a wide variety of proteins and mediators can enter the
interstitial space from the bloodstream
 Vascular permeability
Increased vascular permeability is due to contraction of
endothelial cells
Occurs mainly in venules
Often short-lived
Another mechanism is endothelial damage
Can be caused by trauma, burns, microbial damage
Can also be caused by leukocyte-mediated damage to the
endothelium (often longer-lived)

Increased transcytosis can
also result in leakage of
plasma components into
the interstitial space
Transcytosis?
Active, vesicle-mediated
transport across the
capillary endothelial cell
Large molecules can
move across the
endothelium via:
Pinocytosis (caveolin
pathway)
Receptor-mediated
endocytosis
Mechanisms of increased vascular
permeability
Lymphatics
As interstitial fluid accumulates during
inflammation, pressure increases in the interstitial
space and lymphatic drainage increases
§ Normally only a small amount of interstitial fluid is
produced in non-inflamed tissue
§ Excess fluid, microbes, debris, and leukocytes all migrate
into the lymph during inflammation
The lymphatic vessels themselves can become
inflamed – known as lymphangiitis
Leukocyte migration
C. Emigration and activation of leukocytes
§ Neutrophils, monocytes, eosinophils, and basophils
will all migrate from the circulation into inflamed
tissue
§ Steps:
a) Margination
Mediated by binding of selectins and
b) Rolling cellular adhesion molecules to their
c) Adhesion respective ligands on leukocytes
d) Diapedesis
e) Chemotaxis of leukocytes to sites of injury or infection
Chemokine or cytokine?
Cytokine – a (small) protein messenger, secreted by a vast array of cells,
that can:
§ Influence the differentiation of a wide variety of cells, including
leukocytes
§ Mediate – activate or inactivate – the activity of many cells,
including leukocytes
§ Increase or decrease the production of a wide variety of
stem/hematopoietic cells
Chemokine – structurally-related family of small cytokines that:
§ Bind to cell-surface receptors (usually leukocytes)
§ Induce movement of leukocytes along the chemokine concentration
gradient
§ Mediate adhesion of leukocytes for the purposes of:
Differentiation
Inflammation/migration
 Chemokines
2 major chemokine families
§ CXC
CXC chemokines attract
neutrophils, are
angiogenic, and are very
similar in structure
The “X” indicates the
location of a disulphide
bond
§ CC
Act on/attract a wide
variety of other
leukocytes
Chemokines - FYI
Leukocyte migration
C. Emigration and activation of leukocytes
§ Steps:
a) Margination – leukocytes migrate towards vessel wall
b) Rolling – formation & dissociation of adhesion bonds between
leukocytes and endothelial cells
*Activation by
chemokines
presented on
endothelial cells
is required
before the
leukocyte can
form stable
adhesion
 Endothelial cell presents
a chemokine that
stimulates activation of
the leukocytes
This increases affinity of
leukocyte integrin for it’s
ligand, allowing
stable/tight adhesion
bonds to form
Leukocyte migration

C. Emigration and activation of leukocytes
§ Steps continued:
c) Stable/Tight Adhesion – Formation of tight/stable
adhesion bonds between leukocytes and endothelial cells

d) Diapedesis/
Transmigration –
leukocyte migrates
through
endothelium

e) Chemotaxis of
leukocytes to
sites of injury or
infection
Putting it all together
Adhesion molecules and
their ligands – what are
the concepts here?
 A variety of inflammatory
mediators increase the ability of
leukocytes to migrate to a target

Histamine, Thrombin
Rolling
Selectin expression by
endothelial cells

TNF & IL1
ICAM expression by
endothelial cells

Chemokines
Increased integrin affinity
Chemotactic agents
All of these agents are produced in higher
concentrations at sites of cellular
damage/pathogen invasion
Leukotriene B4
Bacterial products containing N-formyl-methionine
Activated complement (particularly C5a)
More on this in the e-module
Chemokines (IL-8, RANTES, eotaxin)
Leukocytes can “follow the breadcrumbs” to the
site of pathology via the chemotactic agent
concentration gradient
For leukocyte emigration:
What molecules cause loose adhesion of leukocytes
to the vascular endothelium?
§ What binds to what?
How about tight adhesion?
§ What cells are integrins found on? How about ICAMS?
What causes expression of the molecules above?
What is the role of a chemokine in:
§ Tight adhesion?
§ Migration of a leukocyte to a site of inflammation?
What is a chemotactic agent? Name a few