Nonspecific Host Resistance Study Unit 6

Summary

This study unit details nonspecific host resistance mechanisms, covering physical, mechanical, and chemical barriers, immune cells and their roles, and the role of cytokines. It provides information on the complement system and its activation pathways. The unit also examines various types of blood cells involved in innate immunity.

Full Transcript

Study Unit 6

Nonspecific (Innate) Host Resistance

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6.1

–Cells, tissue, and organs of the immune system

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On completion of this study unit, you
should be able to:

Discuss the role of different physical,
mechanical, and chemical barriers against
infection.
Describe different cells, tissues, and organs of
the immune system and explain their various
roles;
Describe the role of cytokines as molecular
regulators of the immune response.

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Host Resistance Overview

Pathogens—disease-causing microbes.
Must overcome surface barriers and antimicrobial activity.

Immune system
Composed of widely distributed proteins, cells, tissues, and organs.
Neutralize or destroy foreign substances.

Immunity
Ability of host to resist infection or disease.

Immunology
– Study of immune responses and how they protect the host.

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Immunity
Innate immunity
– First line of defense.
– Offers resistance to any microbe or foreign material.
– Includes general mechanisms such as skin, mucus, and antimicrobial
chemicals.
Adaptive immune response
– Activated by cells and chemicals of innate immunity.
– Tailored to a particular foreign agent.
– Has “memory”—effectiveness increases on repeated exposure to foreign
agent.

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Antigens
Name comes from antibody generators
Any substance recognized by the immune system.
Immune system can differentiate between self-antigen and non-
self (foreign) antigen.
– Enables immune system to rid the host of foreign invaders as
well as eliminate cancer cells.
– When discrimination goes awry, it is the basis for allergic
response and autoimmune diseases.

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 Barriers
Skin
Mucous membranes
– Lysozyme
– Lactoferrin
– Lactoperoxidase
– Eye – IgA
Respiratory system
Gastrointestinal tract
– Gastric acid
– Enzymes
– Peristalsis
– Normal microbiota
Genitourinary tract
– Low pH
– Urea
– flushing

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31.3 Innate Resistance Relies on Chemical Mediators

a. Discuss host molecules that have antimicrobial actions.
b. Describe in general terms the activation of the host complement system
and its three outcomes.
c. List three categories of cytokines and discuss their major functions.

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Major Components of Mammalian Immune System – Innate
and Nonspecific

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Major Components of Mammalian Immune System – Adaptive and
Specific

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Chemical Mediators in Innate Resistance

Mammalian hosts have a chemical arsenal with which to combat continuous
onslaught of microorganisms.

Lysozyme—hydrolyzes bond of bacterial cell wall.

Lactoferrin—similar to transferrin in blood.

– Sequester iron, reducing its availability for microbes, limiting their ability to
multiply.

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 Chemical mediators in innate resistance

Antimicrobial peptides
– cationic peptides
– Bacteriocins (normal microbiota)
Complement
Cytokines
– intercellular signal molecules, eg. interleukins, interferons
Acute-phase proteins

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Cationic Peptides
Three classes whose biological activity is related to their ability to damage
bacterial plasma membranes:
– Linear, α-helical peptides (that is, cathelicidins)
Antimicrobial activity against bacteria, enveloped viruses and fungi
Respiratory and urogenital epithelial cells, alveolar macrophages
– Defensins
α defensins—smaller and found in granules of neutrophils, intestinal Paneth cells,
and intestinal and respiratory epithelial cells.
β defensins—found in epithelial cells and stimulate release of chemical mediators.
– Histatins
Larger peptides found in saliva.
Compromise mitochondrial function and generate oxidative and osmotic stress
resulting in fungal death.

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 Bacteriocins
Toxic peptides produced by normal microbiota.
Kill closely related species.
Colicins produced by E. coli.
Bind reporters on the cell envelope of sensitive target bacteria
and cause cell lysis.
Lantibiotics
Produced by Streptococcus, Bacillus, Lactococcus, and
Staphylococcus.

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 The Complement System
Composed of >30 heat-labile proteins.
“Complements” the antimicrobial activity of the immune system.
Major activities:
– Stimulate an inflammatory response by helping to recruit white blood cells
(leukocytes).
– Lysing microbial cell membranes.
– Promoting phagocytosis (engulfment and killing) of microbial invaders.
Opsonization

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 Opsonization
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Enhanced phagocytosis through binding
of antibodies and/or complement on the
surface of a pathogen or antigen
Phagocytes
– neutrophils,
– macrophages,
– dendritic cells
– have Ab and C3 receptors

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Complement Activation
Produced in inactive forms

Activated following
enzymatic cleavage

Must be activated in a
cascade fashion

Three pathways of
activation
– alternative
– lectin
– classical
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Alternative Complement Pathway

Involved in nonspecific defenses against
intravascular invasion by bacteria/fungi

Dependent on interaction of complement with
repetitive structures on pathogens

Begins with activation of C3

Results in formation of membrane attack
complex
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 Complement: Opsonization

Def.: process in which microbes are coated
by serum components in preparation for
recognition/ingestion by phagocytic cells
bind to microbial cells, coating them for
phagocyte recognition – forms bridge between
bacteria and phagocytes

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Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

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Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Phagocytosis

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Cytokines
Cyto=cell; kinesis=movement

soluble proteins or glycoproteins that are released by one cell population that act as
intercellular (between cells) mediators or SIGNALLING MOLECULES

Soluble protein that initiates a signal transduction pathway
that regulates transcription of immune response genes.
Categories:
– Regulators of innate immunity.
– Regulators of adaptive immunity.
– Stimulators of hematopoiesis.

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 Cytokine Groups
Functional groups:
– Chemokines—stimulate cell
migration.
– Interleukins—produced by one
leukocyte, act on another.
– Interferons—regulatory cytokines
produced in response to infection.
– Colony-stimulating factors (CS
Fs)—stimulate growth and
differentiation of immature
leukocytes in bone marrow.
– Tumor necrosis factors (TNF)—
stimulate an inflammatory response.
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 Acute-Phase Proteins
Macrophage responds to sites of
injury.
Macrophage activation → cytokine
release → liver stimulation → acute-
phase protein production.
– Assist in the prevention of blood loss and
ready the host for microbial invasion.
Includes C-reactive protein (CRP), M
BL, and surfactant proteins A (SP-A)
and D (SP-D) which bind bacterial
surfaces and act as opsonins.
– Collectins—proteins composed of
collagen-like motif connected to globular
binding sites.
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Different Types of Human Blood Cells
Leukosiete (WBS)
Almal oorsprong in hematopoiëtiese voorganger stamselle
Elk het gespesialiseerde rol in gasheer verdediging
Granulosiete
Neutrofiele
Basofiele
Eosienofiele
Mast selle
Monosiete, Makrofage, Dendrietselle
Aangebore Limfosiete

Leukocytes (WBC) All originate from
hematopoietic precursor stem cells.
Each has specialized role in defending the host.
Granulocytes
Neutrophils
Basophils
Eosinophils
Mast cells
Monocytes, Macrophages, Dendritic cells
Innate Lymphocytes

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 Mast Cells
Bone marrow–derived cells that
differentiate in connective tissue.
Not phagocytic.
Degranulation—release granules into
extracellular environment.
Local inflammatory reactions
Vasoactive mediators—compounds that
influence the tone and diameter of blood
vessels.
– Histamine, prostaglandins, serotonin,
heparin, dopamine, platelet-activating
factor, and leukotrienes.
Play important role in allergic
responses.
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 Granulocytes

Irregularly shaped nuclei with two to five
lobes.
Cytoplasm has granules with reactive
substances that kill microbes and enhance
inflammation.
Three types:
– Basophils
– Eosinophils
– Neutrophils

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 Monocytes and Macrophages

Monocytes
– Produced in bone marrow and enter the
blood.
– After circulating for about 8 hours, they
migrate into tissues, and mature into
macrophages.
Macrophages
– Larger than monocytes that reside in
specific tissues.
– Highly phagocytic.
– Serve as sentinel cells, sounding the
chemical alarm when a microbe
invades.
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Monocytes and Macrophages

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 Macrophages
Larger than monocytes, reside in specific
tissues, highly phagocytic
have a variety of surface receptors
including (Pattern Recognition
Receptors), toll-type receptors
– recognize pathogen associated molecular
patterns (PAMPs) – lipopolysaccharides,
peptidoglycan, foreign DNA, viruses

– Receptors for Ab and complement proteins

– contact, phagocytose, and process
antigens  display foreign antigens on their
surfaces (antigen presentation)
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 Dendritic Cells

Distinguished by long cellular
projections.
Present in the skin and mucous
membranes of the nose, lungs, and
intestines.
Programmed to detect and
phagocytose pathogens.
Display foreign antigens on their
surfaces to share vital information
with lymphocytes to stimulate an
adaptive immune response.
Functions:
– Destroy pathogens
– Trigger specific immune response
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 Innate Lymphocyte Stimuli and Responses

Bridge between innate and
adaptive immunity
Diverse ILC with different
functions, target cells
– Kill infected cells, activate T
cell, enhance inflammation
– Respond to injured cells,
tissue repair, regulate
inflammation
– Regulate antibody production
– Kill tumour cells
(Left top) Nixxphotography/Getty Images; (Left middle) Olgaru79/Shutterstock; (Left bottom) Jezperklauzen/iStock/Getty Images

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Natural Killer (NK) Cells
Non-phagocytic granular lymphocytes
– Cytotoxic enzymes
– destroy malignant cells and cells infected with viral pathogens
Several surface receptors.

If activated to kill the target cell, they releases a pore-forming protein (perforin)
and enzymes called granzymes trigger the target cell to undergo apoptosis.

Two ways of recognizing target cells
– bind to antibodies which coat infected or malignant cells (antibody-
dependent cell-mediated cytotoxicity (ADCC))
– recognizes cells that have lost their class I major histocompatibility
antigen due to presence of virus or cancer
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 Abnormal cells

Natural killer
cells
Antibody-dependent cell-
mediated cytotoxicity 38
31.5 Organs and Tissues of the Immune System Are Sites of Host Defense /
Organe en weefsels van die immuunsisteem is plekke van gasheer
verdediging
a. Differentiate between primary and secondary lymphoid tissues and organs
in terms of structure and function.
b. Explain the role of the spleen in host defense.
c. Rationalize the cellular architecture of skin- and mucosal-associated
lymphoid tissues.

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 Organs and Tissues of the Immune System

Primary organs and tissues
– Where hematopoietic stem cells differentiate into
immune cells.
– Bone marrow—B cells
– Thymus—T cells
secondary organs and tissues
– Where lymphocytes are activated by antigen interaction.
followed by proliferation and differentiation into fully mature effector
cells
– Spleen, lymph nodes and lymph tissue, mucosa associated tissue

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Primary Lymphoid Organs and Tissues
Thymus
– Precursor cells move, enter from bone marrow and proliferate.
– Negative selection—removal of T cells not able to distinguish between self and non-self antigens.
– Remaining cells become mature T cells and enter the bloodstream where they await activation by innate immune
cells.
Bone marrow
– Site of B cell maturation in mammals.
– Maturation involves removal of self-reactive cells.
– Enter bloodstream and migrate to lymph nodes and spleen to await introduction to the antigen to which they will
make targeted antibody.

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Secondary Lymphoid Organs and Tissues—Spleen

Most highly organized
secondary lymphoid organ.
Filters blood and traps blood-
borne particles for assessment
by phagocytes and B cells.
Macrophages and dendritic
cells phagocytose blood-borne
pathogens.
– Present antigens to T cells,
activating specific immune
response.

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 Secondary Lymphoid Organs and Tissues—Lymph Nodes and tissues

Lymph nodes
Capture phagocytosed antigens and present them to
T cells.
Outer region is rich in B cells that can bind antigen
directly from the blood or lymph.
Follicles—inner region where T cells await interaction
with DC or B cells.
Lymphoid tissues
Located throughout the body.
Highly organized and loosely associated lymphoid
tissues exist.
Sample host microbial environment in a region where
leukocytes location is optimized.
Associated lymphoid tissues
– Skin-associated lymphoid tissue (SALT)
– Mucosal-associated lymphoid tissue (MALT)

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Study unit 6.2
Phagocytosis and inflammation

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 On completion of this study section, you
must be able to:
Describe events during the inflammatory response and the role
thereof in non-specific defence of the body;
give a review / an outline of the different types of immune cells and
chemical mediators that act during the inflammatory response;
describe the process of phagocytosis and explain its role in
inflammation; and
discuss the role of different receptors in MHC proteins in phagocytic
destruction of microbes.

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31.6 Phagocytosis Destroys Invaders

a. Explain the methods by which pathogens are recognized by phagocytes.
b. Compare and contrast the processes of autophagy and phagocytosis.
c. Correlate the biochemical activities within the phagolysosome with
pathogen destruction.

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 Phagocytosis
process by which
phagocytic cells
(macrophages, dendritic
cells, and neutrophils)
recognize, ingest, and kill
extracellular microbes

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 Phagocytosis…

Two mechanisms for recognition of microbe by phagocyte

– opsonin-independent (nonopsonic) recognition

– opsonin-dependent (opsonic) recognition

phagocytosis can be greatly increased by opsonization

https://www.youtube.com/watch?v=iZYLeIJwe4w

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Phagocytosis: Overview

https://www.youtube.com/watch?v
=7VQU28itVVw
 Pathogen-Associated Molecular Patterns
(PAMPs)

Based on detection, by phagocytes, of conserved microbial
molecular structures that occur in patterns
PAMPs are unique to microbes, not present in host
– e.g., lipopolysaccharide (LPS) of gram-negative bacteria
– e.g., peptidoglycan of gram-positive bacteria

PAMPs recognized by pattern recognition receptors (PRRs) on
phagocytic cells
PRRs can work alone or together to trigger phagocytes, e.g. toll-
type receptors (TLR)
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 Opsonin-Independent Pathogen Recognition

Common pathogen components are non-specifically recognized to activate
phagocytes
Microbe-associated molecular patterns (MAMPs):
– Specific regions within common microbial macromolecules, such as lipopolysaccharide,
peptidoglycan, fungal cell wall components, viral nucleic acids, and other microbial
structures.
– Alert host about the presence of microbe.
Pattern recognition receptors (PRR):
– C-type lectin receptors
– Toll-like receptors
– NOD-like receptors
– RIG-I-like receptors

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Recognition of MAMPs by PRRs

Source: “Introduction to the Immune System.” What-When-How.

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 Intracellular Digestion

Once bound, microbes can be internalized and
phagosome delivered to a lysosome to become a
phagolysosome
Lysosome produces hydrolytic enzymes – lysozyme, Rnases,
DNases, proteases
acid pH
respiratory burst reactions occur once phagosome forms
toxic oxygen products are produced which can kill
invading microbes

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Intracellular Digestion—Respiratory Burst

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Autophagy

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 Exocytosis
Process used by neutrophils to expel
microbial fragments after they have
been digested.
Phagolysosome unites with cell
membrane.
– Results in extracellular release of microbial
fragments.
Antigen-presenting cells—
macrophages and DC.
– Move fragments from phagolysosome or
autolysosome to the endoplasmic reticulum.
– Peptide fragment components unite with
glycoproteins, becoming part of cell membrane.
– Microbe-specific peptide placed in MHC.
– Facing exterior of the cell
– Antigen is shown (presented) to T cells
– Activates the adaptive immune response
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Antigen Processing and Presentation: MHC
Inflammation
Nonspecific response to tissue injury
– can be caused by pathogen or physical trauma
– acute inflammation is the immediate response of
body to injury or cell death
cardinal signs
– redness (rubor)
– warmth (calor)
– pain (dolor)
– swelling (tumor)
– altered function (functio laesa)

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Inflammation

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Acute Inflammatory Response…
Involves chemical mediators (chemokines)
– selectins
cell adhesion molecules on activated capillary endothelial cells (attract
neutrophils)
– integrins
adhesion receptors on neutrophils
integrins bind to selectins
– chemotaxins
chemotactic factors released by injured cells

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Acute Inflammatory Response
Various
processes
occur
– margination
– diapedesis
– extravasasion

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Acute Inflammatory Response
Various processes occur
– Margination – neutrophils
bind to the epithelium of a
blood vessel

– diapedesis – neutrophils
change shape and squeeze
through endothelial wall

– extravasation – neutrophils
migrate to site of injury

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More about Acute Inflammation…

Tissue injury causes release of kalikrein and various other
mediators that increase capillary dilation and increased blood
flow bring more antimicrobial factors and leukocytes that kill
pathogens
fibrin clot may restrict pathogen movement
phagocytes accumulate in inflamed area and destroy
pathogens
bone marrow is stimulated by numerous released chemicals
to release neutrophils and increase rate of granulocyte
production

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Prostaglandins –
Swelling, pain

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Pathogen is neutralized:

Increase in blood flow, antimicrobial factors,
leukocytes
Blood leakage into tissue spaces
– Increases temperature
– Stimulates inflammatory response
– Inhibit microbial growth
Fibrin clot limit spread
Phagocytes ingest pathogens, increased
granulocyte production.
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 Chronic Inflammation

Slow process
Involves formation of new connective tissue
Usually causes permanent tissue damage
Dense infiltration of lymphocytes and macrophages at site of
inflammation
Granuloma—mass of cells that forms when phagocytic cells can’t
destroy pathogen and instead attempt to wall off the site.

Dr. Cornelio Arevalo, Venezuela/CDC
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