Systemic Pathology: IMMUNE SYSTEM PDF

Summary

This document is an overview of the immune system, covering both innate and adaptive immunity. It explains various components of the immune system, including cells, receptors, and mechanisms. The document is a good resource for medical students and professionals.

Full Transcript

Systemic Pathology:
IMMUNE SYSTEM
Arlene L. Quitasol, MD, FPSP
 Normal Immune Response
IMMUNITY
Protection from infectious pathogens
Mechanisms of defense against microbes fall into two broad categories
INNATE IMMUNITY
ADAPTIVE IMMUNITY
 Normal Immune Response
INNATE IMMUNITY
Also called NATURAL, OR NATIVE, IMMUNITY
Mechanisms that are ready to react to infections even before they occur
Evolved to specifically recognize and combat microbes
 Normal Immune Response
INNATE IMMUNITY
First line of defense
Mediated by cells and molecules that recognize products of microbes and dead cells and
induce rapid protective host reactions
 Normal Immune Response
INNATE IMMUNITY
Always present, ready to provide defense against microbes and to eliminate damaged
cells
Receptors and components have evolved to serve these purposes
Functions in stages
Recognition of microbes and damaged cells
Activation of various mechanisms
Elimination of the unwanted substances
 Normal Immune Response
ADAPTIVE IMMUNITY
Also called ACQUIRED, or SPECIFIC IMMUNITY
Consists of mechanisms that are stimulated by (“adapt to”) microbes
Capable of recognizing microbial and nonmicrobial substances
Develops later, after exposure to microbes and other foreign substances
More powerful than innate immunity in combating infections
 Normal Immune Response
INNATE IMMUNITY
Components of Innate Immunity
Epithelial barriers that block entry of microbes
Phagocytic cells (mainly neutrophils and macrophages)
Dendritic cells, natural killer (NK) cells
Several plasma proteins, including the proteins of the complement system
 Normal Immune Response
INNATE IMMUNITY
Components of Innate Immunity
Epithelia of the skin and gastrointestinal and respiratory tracts
Mechanical barriers to the entry of microbes from the external environment
Also produce antimicrobial molecules such as defensins, and lymphocytes located in the
epithelia combat microbes at these sites
 Normal Immune Response
INNATE IMMUNITY
Components of Innate Immunity
Monocytes and neutrophils
Phagocytes in the blood that can rapidly be recruited to any site of infection
MACROPHAGES
Monocytes that enter the tissues and mature
 Normal Immune Response
INNATE IMMUNITY
Components of Innate Immunity
Dendritic cells
Specialized cell population present in epithelia, lymphoid organs, and most tissues
Antigen presenting function - capture protein antigens and display peptides for
recognition by T lymphocytes
Endowed with a rich collection of receptors that sense microbes and cell damage and
stimulate the secretion of cytokines, mediators that play critical roles in inflammation
and anti-viral defense.
 Normal Immune Response
INNATE IMMUNITY
Components of Innate Immunity
Natural killer cells
Provide early protection against many viruses and intracellular bacteria
Mast cells
Capable of producing many mediators of inflammation
 Normal Immune Response
INNATE IMMUNITY
Components of Innate Immunity
Soluble proteins
Complement system
Plasma proteins that are activated by microbes using the alternative and lectin
pathways in innate immune responses
In adaptive immunity activated by antibodies using the classical pathway
Mannose-binding lectin and C-reactive protein
Both of which coat microbes and promote phagocytosis
Lung surfactant
Provides protection against inhaled microbes
 Normal Immune Response
INNATE IMMUNITY
Cellular Receptors for Microbes, Products of Damaged Cells, and Foreign Substances
PATHOGEN-ASSOCIATED MOLECULAR PATTERNS
Microbial components that are shared among related microbes and are often essential
for infectivity
Cannot be mutated to allow the microbes to evade the defense mechanisms
DAMAGE-ASSOCIATED MOLECULAR PATTERNS
Molecules released by injured and necrotic cells
PATTERN RECOGNITION RECEPTORS
Cellular receptors that recognize these molecules
 Normal Immune Response
INNATE IMMUNITY
Cellular Receptors for Microbes, Products of Damaged Cells, and Foreign Substances
PATTERN RECOGNITION RECEPTORS
Located in all the cellular compartments where microbes may be present:
Plasma membrane receptors - detect extracellular microbes
Endosomal receptors - detect ingested microbes
Cytosolic receptors - detect microbes in the cytoplasm
 Normal Immune Response
INNATE IMMUNITY
Cellular Receptors for Microbes, Products of Damaged Cells, and Foreign Substances
PATTERN RECOGNITION RECEPTORS
Several classes have been identified
Toll-Like Receptors
NOD-Like Receptors and the Inflammasome
C-type lectin receptors (CLRs)
RIG-like receptors (RLRs)
G-protein–coupled receptors
Mannose receptors
 Normal Immune Response
INNATE IMMUNITY
Cellular Receptors for Microbes, Products of Damaged Cells, and Foreign Substances
PATTERN RECOGNITION RECEPTORS
TOLL-LIKE RECEPTORS
Best known of the pattern recognition receptors
Present in the plasma membrane and endosomal vesicles
 Normal Immune Response
INNATE IMMUNITY
Cellular Receptors for Microbes, Products of Damaged Cells, and Foreign Substances
PATTERN RECOGNITION RECEPTORS
TOLL-LIKE RECEPTORS
Signal by a common pathway that culminates in the activation of two sets of
transcription factors:
NF-κB
Stimulates the synthesis and secretion of cytokines and the expression of
adhesion molecules, both of which are critical for the recruitment and
activation of leukocytes
INTERFERON REGULATORY FACTORS (IRFs)
Stimulate the production of the antiviral cytokines, type I interferons
 Normal Immune Response
INNATE IMMUNITY
Cellular Receptors for Microbes, Products of Damaged Cells, and Foreign Substances
PATTERN RECOGNITION RECEPTORS
NOD-Like Receptors and the Inflammasome
NOD-LIKE RECEPTORS (NLRs)
Cytosolic receptors
Recognize a wide variety of substances, including products of necrotic cells
(e.g., uric acid and released ATP), ion disturbances (e.g., loss of K+), and some
microbial products.
 Normal Immune Response
INNATE IMMUNITY
Cellular Receptors for Microbes, Products of Damaged Cells, and Foreign Substances
PATTERN RECOGNITION RECEPTORS
NOD-Like Receptors and the Inflammasome
INFLAMMASOME
Cytosolic multiprotein complex in which NOD-like receptors signal
Activates an enzyme (caspase-1) that cleaves a precursor form of the cytokine
interleukin-1 (IL-1) to generate the biologically active form
 Normal Immune Response
INNATE IMMUNITY
Cellular Receptors for Microbes, Products of Damaged Cells, and Foreign Substances
PATTERN RECOGNITION RECEPTORS
NOD-Like Receptors and the Inflammasome
NOD-LIKE RECEPTORS (NLRs)
AUTOINFLAMMATORY SYNDROMES
Gain-of-function mutations in one of the NLRs result in periodic fever
syndromes
Respond very well to treatment with IL-1 antagonists
 Normal Immune Response
INNATE IMMUNITY
Cellular Receptors for Microbes, Products of Damaged Cells, and Foreign Substances
PATTERN RECOGNITION RECEPTORS
Other Receptors for Microbial Products
C-TYPE LECTIN RECEPTORS (CLRs)
Expressed on the plasma membrane of macrophages and dendritic cells
Detect fungal glycans and elicit inflammatory reactions to fungi
RIG-LIKE RECEPTORS (RLRs)
Located in the cytosol of most cell types
Detect nucleic acids of viruses that replicate in the cytoplasm of infected cells
Stimulate the production of antiviral cytokines
 Normal Immune Response
INNATE IMMUNITY
Cellular Receptors for Microbes, Products of Damaged Cells, and Foreign Substances
PATTERN RECOGNITION RECEPTORS
Other Receptors for Microbial Products
G PROTEIN–COUPLED RECEPTORS
Found in neutrophils, macrophages, and most other types of leukocytes
Recognize short bacterial peptides containing N-formylmethionyl residues.
Enables neutrophils to detect bacterial proteins and stimulate chemotactic
responses of the cells
MANNOSE RECEPTORS
Recognize microbial substances
Induce phagocytosis of the microbes
 Normal Immune Response
ADAPTIVE IMMUNITY
Consists of lymphocytes and their products, including antibodies
Two types of adaptive immunity:
HUMORAL IMMUNITY
Protects against extracellular microbes and their toxins
Mediated by B (bone marrow–derived) lymphocytes and their secreted products,
ANTIBODIES (also called IMMUNOGLOBULINS, Ig)
 Normal Immune Response
ADAPTIVE IMMUNITY
Two types of adaptive immunity:
CELL-MEDIATED (OR CELLULAR) IMMUNITY
Responsible for defense against intracellular microbes
Mediated by T (thymus-derived) lymphocytes
Both classes of lymphocytes express highly specific receptors for a wide variety of substances,
which are called ANTIGENS
 Normal Immune Response
Cells of the Immune System
T and B LYMPHOCYTES
Heterogeneous and specialized in molecular properties and functions
Not fixed in particular tissues but constantly circulate among lymphoid and other tissues via
the blood and the lymphatic circulation. This feature promotes IMMUNE SURVEILLANCE by
allowing lymphocytes to home to any site of infection
 Normal Immune Response
Cells of the Immune System
NAIVE (IMMUNOLOGICALLY INEXPERIENCED)
Mature lymphocytes that have not encountered the antigen for which they are specific
EFFECTOR CELLS
Lymphocytes after they are activated by recognition of antigens and other signals
Perform the function of eliminating microbes
MEMORY CELLS
Live in a state of heightened awareness and are able to react rapidly and strongly to combat
the microbe in case it returns
 Normal Immune Response
Cells of the Immune System
Lymphocyte Diversity
CLONAL SELECTION
Lymphocytes express specific receptors for antigens and mature into functionally
competent cells before exposure to antigen
Lymphocytes of the same specificity are said to constitute a CLONE; all the members of
one clone express identical antigen receptors
 Normal Immune Response
Cells of the Immune System
Lymphocyte Diversity
Antigen receptor diversity is generated by somatic recombination of the genes that encode
the receptor proteins.
Enzyme in developing lymphocytes that mediates recombination of these gene segments is
the product of RAG-1 and RAG-2 (recombination activating genes); inherited defects in RAG
proteins result in a failure to generate mature lymphocytes.
 Normal Immune Response
Cells of the Immune System
Lymphocyte Diversity
Germline antigen receptor genes are present in all cells in the body, but only T and B cells
contain recombined (also called rearranged) antigen receptor genes (the T-cell receptor [TCR]
in T cells and immunoglobulin [Ig] in B cells).
Presence of recombined TCR or Ig genes, demonstrated by molecular analysis, is a marker of
T- or B-lineage cells.
 Normal Immune Response
Cells of the Immune System
Lymphocyte Diversity
Each T or B cell and its clonal progeny have a unique DNA rearrangement, it is possible to
distinguish polyclonal (nonneoplastic) lymphocyte proliferations from monoclonal (neoplastic)
lymphoid tumors
Analysis of antigen receptor gene rearrangements is a valuable assay for detecting tumors
derived from lymphocytes
 Normal Immune Response
Cells of the Immune System
T LYMPHOCYTES
Three major populations of T cells, which serve distinct functions
HELPER T LYMPHOCYTES
Stimulate B lymphocytes to make antibodies and activate other leukocytes (e.g.,
phagocytes) to destroy microbes
CYTOTOXIC T LYMPHOCYTES (CTLs)
Kill infected cells
REGULATORY T LYMPHOCYTES
Limit immune responses and prevent reactions against self antigens
 Normal Immune Response
Cells of the Immune System
T LYMPHOCYTES
Develop in the thymus from precursors that arise from hematopoietic stem cells
Mature T cells
Found in the blood constitute 60% to 70% of lymphocytes, and in T-cell zones of
peripheral lymphoid organs
Each T cell recognizes a specific cell-bound antigen by means of an antigen-specific TCR
 Normal Immune Response
Cells of the Immune System
T LYMPHOCYTES
Approximately 95% of T cells, the TCR consists of a disulfide-linked heterodimer made up of
an α and a β polypeptide chain, each having a variable (antigen-binding) region and a
constant region
αβ TCR recognizes peptide antigens that are presented by major histocompatibility complex
(MHC) molecules on the surfaces of antigen-presenting cells
By limiting the specificity of T cells for peptides displayed by cell surface MHC molecules,
called MHC RESTRICTION, the immune system ensures that T cells see only cell-associated
antigens (e.g., those derived from microbes in cells or from proteins ingested by cells).
 Normal Immune Response
Cells of the Immune System
T LYMPHOCYTES
Each TCR is noncovalently linked to six polypeptide chains, which form the CD3 complex and
the ζ chain dimer
CD3 and ζ proteins
Invariant (i.e., identical) in all T cells
Involved in the transduction of signals into the T cell that are triggered by binding of
antigen to the TCR. Together with the TCR, these proteins form the TCR complex.
 Normal Immune Response
Cells of the Immune System
T LYMPHOCYTES
A small population of mature T cells expresses another type of TCR composed of γ and δ
polypeptide chains
γδ TCR recognizes peptides, lipids, and small molecules, without a requirement for display by
MHC proteins.
γδ T cells tend to aggregate at epithelial surfaces, such as the skin and mucosa of the
gastrointestinal and urogenital tracts, suggesting that these cells are sentinels that protect
against microbes that try to enter through epithelia
 Normal Immune Response
Cells of the Immune System
T LYMPHOCYTES
T cells express several other proteins that assist the TCR complex in functional responses
CD4
CD8
CD28
integrins
 Normal Immune Response
Cells of the Immune System
T LYMPHOCYTES
Approximately 60% of mature T cells are CD4+ and about 30% are CD8+.
Most CD4+ T cells function as cytokine-secreting helper cells that assist macrophages and B
lymphocytes to combat infections.
Most CD8+ cells function as cytotoxic (killer) T lymphocytes (CTLs) to destroy host cells
harboring microbes.
During antigen recognition, CD4 molecules bind to class II MHC molecules that are displaying
antigen and CD8 molecules bind to class I MHC molecules
 Normal Immune Response
Cells of the Immune System
B LYMPHOCYTES
Only cells in the body capable of producing antibody molecules, mediators of humoral
immunity
Develop from precursors in the bone marrow
Mature B Cells constitute 10% to 20% of the circulating peripheral lymphocyte population and
are also present in peripheral lymphoid tissues
Recognize antigen via the B-cell antigen receptor complex
 Normal Immune Response
Cells of the Immune System
B LYMPHOCYTES
Membrane-bound antibodies of the IgM and IgD isotypes, present on the surface of all
mature, naive B cells, are the antigen-binding component of the B-cell receptor complex
After stimulation by antigen and other signals, B cells develop into PLASMA CELLS, protein
factories for antibodies
PLASMABLASTS
Antibody-secreting cells detected in human peripheral blood
 Normal Immune Response
Cells of the Immune System
B LYMPHOCYTES
B-cell antigen receptor complex contains a heterodimer of two invariant proteins called Igα
and Igβ.
Similar to the CD3 and ζ proteins of the TCR complex, Igα (CD79a) and Igβ (CD79b) are
essential for signal transduction through the antigen receptor
 Normal Immune Response
Cells of the Immune System
B LYMPHOCYTES
Also express several other molecules that are essential for their responses
TYPE 2 COMPLEMENT RECEPTOR (CR2, OR CD21)
Recognizes complement products generated during innate immune responses to
microbes
Also used by the Epstein-Barr virus (EBV) as a receptor to enter and infect B cells
CD40, which receives signals from helper T cells.
 Normal Immune Response
Cells of the immune system
DENDRITIC CELLS
Interdigitating dendritic cells
Most important antigen-presenting cells for initiating T-cell responses against protein
antigens
Cells have numerous fine cytoplasmic processes that resemble dendrites, from which they
derive their name
 Normal Immune Response
Cells of the Immune System
DENDRITIC CELLS
Several features of dendritic cells account for their key role in antigen presentation
Located at the right place to capture antigens—under epithelia and in the interstitia of
all tissues, where antigens may be produced.
LANGERHANS CELLS
Immature dendritic cells within the epidermis
Express many receptors for capturing and responding to microbes
Recruited to the T-cell zones of lymphoid organs, where they are ideally located to
present antigens to T cells.
Express high levels of MHC and other molecules needed for presenting antigens to and
activating T cells.
 Normal Immune Response
Cells of the Immune System
DENDRITIC CELLS
FOLLICULAR DENDRITIC CELL
Second type of cell with dendritic morphology
Present in the germinal centers of lymphoid follicles in the spleen and lymph nodes
Bear Fc receptors for IgG and receptors for C3b and can trap antigen bound to antibodies
or complement proteins
Play a role in humoral immune responses by presenting antigens to B cells and selecting
the B cells that have the highest affinity for the antigen, thus improving the quality of the
antibody produced.
 Normal Immune Response
Cells of the Immune System
MACROPHAGES
Part of the mononuclear phagocyte system
Function as antigen-presenting cells in T-cell activation
Key effector cells in certain forms of cell-mediated immunity, the reaction that serves to
eliminate intracellular microbes. In this type of response, T cells activate macrophages and
enhance their ability to kill ingested microbes
Participate in the effector phase of humoral immunity
 Normal Immune Response
Cells of the Immune System
NATURAL KILLER CELLS
Function is to destroy irreversibly stressed and abnormal cells, such as virus-infected cells and
tumor cells
Make up approximately 5% to 10% of peripheral blood lymphocytes
Do not express TCRs or Ig
 Normal Immune Response
Cells of the Immune System
NATURAL KILLER CELLS
Morphologically
Somewhat larger than small lymphocytes
Contain abundant azurophilic granules
Endowed with the ability to kill a variety of virus-infected cells and tumor cells, without prior
exposure to or activation by these microbes or tumors
 Normal Immune Response
Cells of the Immune System
NATURAL KILLER CELLS
Two cell surface molecules, CD16 and CD56, are commonly used to identify NK cells
CD16
Fc receptor for IgG
Confers on NK cells the ability to lyse IgG-coated target cells. This phenomenon is
known as ANTIBODY-DEPENDENT CELL-MEDIATED CYTOTOXICITY (ADCC)
 Normal Immune Response
Cells of the Immune System
NATURAL KILLER CELLS
NKG2D FAMILY
Activating receptor
Receptors recognize surface molecules that are induced by various kinds of stress, such
as infection and DNA damage
NK cell inhibitory receptors recognize self class I MHC molecules, which are expressed on all
healthy cells
 Normal Immune Response
Cells of the Immune System
NATURAL KILLER CELLS
NK cells also secrete cytokines such as interferon-γ (IFN-γ), which activates macrophages to
destroy ingested microbes, and thus NK cells provide early defense against intracellular
microbial infections.
 Normal Immune Response
Cells of the Immune System
INNATE LYMPHOID CELLS (ILCS)
Populations of lymphocytes that lack TCRs but produce cytokines similar to those that are
made by T cells
NK cells are considered the first defined ILC
Functions
Early defense against infections
Recognition and elimination of stressed cells (so-called stress surveillance)
Shaping the later adaptive immune response, by providing cytokines that influence the
differentiation of T lymphocytes
 Normal Immune Response
Tissues of the Immune System
Consist
GENERATIVE (also called PRIMARY, or CENTRAL) LYMPHOID ORGANS
T and B lymphocytes mature and become competent to respond to antigens
PERIPHERAL (or SECONDARY) LYMPHOID ORGANS
Adaptive immune responses to microbes are initiated
 Normal Immune Response
Tissues of the Immune System
GENERATIVE LYMPHOID ORGANS
Thymus - where T cells develop
Bone marrow - site of production of all blood cells and where B lymphocytes mature
PERIPHERAL LYMPHOID ORGANS
Lymph nodes
Spleen
Mucosal and cutaneous lymphoid tissues
 Normal Immune Response
Tissues of the Immune System
PERIPHERAL LYMPHOID ORGANS
LYMPH NODES
Nodular aggregates of lymphoid tissues located along lymphatic channels throughout
the body
Antigens of microbes that enter through epithelia or colonize tissues become
concentrated in draining lymph nodes
 Normal Immune Response
Tissues of the Immune System
PERIPHERAL LYMPHOID ORGANS
SPLEEN
Abdominal organ that serves the role in immune responses to bloodborne antigen
Blood entering the spleen flows through a network of sinusoids.
Bloodborne antigens are trapped by dendritic cells and macrophages in the spleen.
 Normal Immune Response
Tissues of the Immune System
PERIPHERAL LYMPHOID ORGANS
CUTANEOUS AND MUCOSAL LYMPHOID SYSTEMS
Located under the epithelia of the skin and the gastrointestinal and respiratory tracts
Respond to antigens that enter through breaches in the epithelium
Pharyngeal tonsils and Peyer’s patches of the intestine are two anatomically defined
mucosal lymphoid tissues
 Normal Immune Response
Tissues of the Immune System
PERIPHERAL LYMPHOID ORGANS
Within the peripheral lymphoid organs, T lymphocytes and B lymphocytes are segregated into
different regions
LYMPH NODES
B cells are concentrated in discrete structures, called FOLLICLES, located around the
periphery, or CORTEX, of each node
If the B cells in a follicle have recently responded to an antigen, this follicle may contain a
central region called a GERMINAL CENTER
T lymphocytes are concentrated in the paracortex, adjacent to the follicles
 Normal Immune Response
Tissues of the Immune System
PERIPHERAL LYMPHOID ORGANS
LYMPH NODES
Follicles contain the follicular dendritic cells that are involved in the activation of B cells,
and the paracortex contains the dendritic cells that present antigens to T lymphocytes
SPLEEN
T lymphocytes are concentrated in periarteriolar lymphoid sheaths surrounding small
arterioles
B cells reside in the follicles
 MAJOR HISTOCOMPATIBILITY COMPLEX (MHC) MOLECULES: The
Peptide Display System of Adaptive Immunity
Function: display peptide fragments of protein antigens for recognition by
antigen specific T cells.
In humans the MHC molecules are called HUMAN LEUKOCYTE ANTIGENS
(HLA) because they were initially detected on leukocytes by the binding of
antibodies
Genes clustered on a small segment of chromosome 6
 MAJOR HISTOCOMPATIBILITY COMPLEX (MHC) MOLECULES: The
Peptide Display System of Adaptive Immunity
Classified into two major classes
CLASS I MHC MOLECULES
Expressed on all nucleated cells and platelets
Heterodimers consisting of a polymorphic α, or heavy, chain (44-kD) linked non covalently to a
smaller (12-kD) nonpolymorphic protein called Β2-MACROGLOBULIN
α chains are encoded by three genes, designated HLA-A, HLA-B, and HLA-C, that lie close to
one another in the MHC locus
 MAJOR HISTOCOMPATIBILITY COMPLEX (MHC) MOLECULES: The
Peptide Display System of Adaptive Immunity
CLASS I MHC MOLECULES
Display peptides that are derived from proteins, such as viral and tumor antigens, that are
located in the cytoplasm and usually produced in the cell
Class I–associated peptides are recognized by CD8+ T lymphocytes.
CD8+ T cells are said to be class I MHC-restricted.
Because one of the important functions of CD8+ CTLs is to eliminate viruses, which may infect
any nucleated cell, and tumors, which may arise from any nucleated cell, it makes good sense
that all nucleated cells express class I HLA molecules and can be surveyed by CD8+ T cells.
 MAJOR HISTOCOMPATIBILITY COMPLEX (MHC) MOLECULES: The
Peptide Display System of Adaptive Immunity
CLASS II MHC MOLECULES
Encoded in a region called HLA-D, which has three subregions: HLA-DP, HLA-DQ, and HLA-DR.
Heterodimer consisting of a noncovalently associated α chain and β chain, both of which are
polymorphic
 MAJOR HISTOCOMPATIBILITY COMPLEX (MHC) MOLECULES: The
Peptide Display System of Adaptive Immunity
CLASS II MHC MOLECULES
Present antigens that are internalized into vesicles, and are typically derived from
extracellular microbes and soluble proteins
Class II β2 domain has a binding site for CD4, and therefore, the class II-peptide complex is
recognized by CD4+ T cells, which function as helper cells.
Because CD4+ T cells can recognize antigens only in the context of self class II molecules, they
are referred to as class II MHC restricted
Mainly expressed on cells that present ingested antigens (macrophages, B lymphocytes, and
dendritic cells).
Hypersensitivity: Immunologically
Mediated Tissue Injury
 HYPERSENSITIVITY
Injurious immune reactions
Term arose from the idea that individuals who have been previously exposed
to an antigen manifest detectable reactions to that antigen and are therefore
said to be SENSITIZED
Excessive or harmful reaction to antigen
 HYPERSENSITIVITY
Important General Features of Hypersensitivity Disorders
Hypersensitivity reactions can be elicited by exogenous environmental antigens
(microbial and nonmicrobial) or endogenous self antigens.
Some of the most common reactions to environmental antigens cause the group of diseases
known as ALLERGY.
Immune responses against self, or autologous, antigens, result in AUTOIMMUNE DISEASES.
Hypersensitivity usually results from an imbalance between the effector mechanisms of
immune responses and the control mechanisms that serve to normally limit such
responses.
 HYPERSENSITIVITY
Important General Features of Hypersensitivity Disorders
Development of hypersensitivity diseases (both allergic and autoimmune) is often
associated with the inheritance of particular susceptibility genes.
Mechanisms of tissue injury in hypersensitivity reactions are the same as the effector
mechanisms of defense against infectious pathogens.
 HYPERSENSITIVITY
Classification of Hypersensitivity Diseases
Classified on the basis of the immunologic mechanism that mediates the disease
IMMEDIATE HYPERSENSITIVITY (TYPE I HYPERSENSITIVITY)
ANTIBODY-MEDIATED DISORDERS (TYPE II HYPERSENSITIVITY)
IMMUNE COMPLEX–MEDIATED DISORDERS (TYPE III HYPERSENSITIVITY)
CELL-MEDIATED IMMUNE DISORDERS (TYPE IV HYPERSENSITIVITY)
 HYPERSENSITIVITY
Classification of Hypersensitivity Diseases
IMMEDIATE HYPERSENSITIVITY (TYPE I HYPERSENSITIVITY
Injury caused by TH2 cells, IgE antibodies, and mast cells and other leukocytes.
Mast cells release mediators that act on vessels and smooth muscle and proinflammatory
cytokines that recruit inflammatory cells.
 HYPERSENSITIVITY
IMMEDIATE (TYPE I) HYPERSENSITIVITY
Rapid immunologic reaction occurring in a previously sensitized individual that is
triggered by the binding of an antigen to IgE antibody on the surface of mast cells.
Reactions are often called ALLERGY, and the antigens that elicit them are ALLERGENS
Systemic disorder or as a local reaction
 HYPERSENSITIVITY
IMMEDIATE (TYPE I) HYPERSENSITIVITY
Local reactions are diverse and vary depending on the portal of entry of the allergen
Form of localized cutaneous rash or blisters (skin allergy, hives)
Nasal and conjunctival discharge (allergic rhinitis and conjunctivitis)
Hay fever
Bronchial asthma
Allergic gastroenteritis (food allergy)
 HYPERSENSITIVITY
IMMEDIATE (TYPE I) HYPERSENSITIVITY
Two well-defined phases
IMMEDIATE REACTION
Characterized by vasodilation, vascular leakage, and depending on the location, smooth
muscle spasm or glandular secretions
Usually become evident within minutes after exposure to an allergen and tend to
subside in a few hours
 HYPERSENSITIVITY
IMMEDIATE (TYPE I) HYPERSENSITIVITY
Two well-defined phases
LATE-PHASE REACTION
2 to 24 hours later without additional exposure to antigen and may last for several days
Characterized by infiltration of tissues with eosinophils, neutrophils, basophils,
monocytes, and CD4+ T cells, as well as tissue destruction, typically in the form of
mucosal epithelial cell damage
 HYPERSENSITIVITY
IMMEDIATE (TYPE I) HYPERSENSITIVITY
They are induced by environmental antigens (allergens) that stimulate strong TH2
responses and IgE production in genetically susceptible individuals
IgE coats mast cells by binding to Fcε receptors; reexposure to the allergen leads to
cross-linking of the IgE and FcεRI, activation of mast cells, and release of mediators.
 HYPERSENSITIVITY
IMMEDIATE (TYPE I) HYPERSENSITIVITY
Principal mediators are histamine, proteases, and other granule contents, prostaglandins
and leukotrienes, and cytokines.
Mediators are responsible for the immediate vascular and smooth muscle reactions and
the late-phase reaction (inflammation).
Clinical manifestations may be local or systemic, and range from mildly annoying rhinitis
to fatal anaphylaxis.
 HYPERSENSITIVITY
Classification of Hypersensitivity Diseases
ANTIBODY-MEDIATED DISORDERS (TYPE II HYPERSENSITIVITY)
Secreted IgG and IgM antibodies injure cells by promoting their phagocytosis or lysis and
injure tissues by inducing inflammation
Antibodies may also interfere with cellular functions and cause disease without tissue injury.
 HYPERSENSITIVITY
Classification of Hypersensitivity Diseases
ANTIBODY-MEDIATED DISORDERS (TYPE II HYPERSENSITIVITY)
Antibodies that react with antigens present on cell surfaces or in the extracellular matrix
cause disease by destroying these cells, triggering inflammation, or interfering with normal
functions
Antibodies may be specific for normal cell or tissue antigens (autoantibodies) or for
exogenous antigens, such as chemical or microbial proteins, that bind to a cell surface or
tissue matrix.
 HYPERSENSITIVITY
Classification of Hypersensitivity Diseases
IMMUNE COMPLEX–MEDIATED DISORDERS (TYPE III HYPERSENSITIVITY)
IgG and IgM antibodies bind antigens usually in the circulation, and the antigen-antibody
complexes deposit in tissues and induce inflammation
Leukocytes that are recruited (neutrophils and monocytes) produce tissue damage by release
of lysosomal enzymes and generation of toxic free radicals
 HYPERSENSITIVITY
Classification of Hypersensitivity Diseases
IMMUNE COMPLEX–MEDIATED DISORDERS (TYPE III HYPERSENSITIVITY)
Antigen-antibody complexes produce tissue damage mainly by eliciting inflammation at the
sites of deposition
Pathologic reaction is usually initiated when antigen combines with antibody in the
circulation, creating immune complexes that typically deposit in vessel walls.
Complexes may be formed at sites where antigen has been “planted” previously (called in situ
immune complexes).
Immune complex–mediated diseases tend be systemic, but often preferentially involve the
kidney (glomerulonephritis), joints (arthritis), and small blood vessels (vasculitis), all of which
are common sites of immune complex deposition
 HYPERSENSITIVITY
Classification of Hypersensitivity Diseases
IMMUNE COMPLEX–MEDIATED DISORDERS (TYPE III HYPERSENSITIVITY)
Morphology
Principal morphologic manifestation of immune complex injury is acute vasculitis,
associated with necrosis of the vessel wall and intense neutrophilic infiltration
Necrotic tissue and deposits of immune complexes, complement, and plasma protein
appear as a smudgy eosinophilic area of tissue destruction, an appearance termed
fibrinoid necrosis
When deposited in the kidney, the complexes can be seen on immunofluorescence
microscopy as granular lumpy deposits of immunoglobulin and complement and on
electron microscopy as electron-dense deposits along the glomerular basement
membrane
 HYPERSENSITIVITY
Classification of hypersensitivity diseases
CELL-MEDIATED IMMUNE DISORDERS (TYPE IV HYPERSENSITIVITY)
Sensitized T lymphocytes (TH1 and TH17 cells and CTLs) are the cause of the tissue injury.
TH2 cells induce lesions that are part of immediate hypersensitivity reactions and are not
considered a form of type IV hypersensitivity.
 HYPERSENSITIVITY
Classification of hypersensitivity diseases
CELL-MEDIATED IMMUNE DISORDERS (TYPE IV HYPERSENSITIVITY)
Caused by inflammation resulting from cytokines produced by CD4+ T cells and cell killing by
CD8+ T cells
CD4+ T cell–mediated hypersensitivity induced by environmental and self antigens is the
cause of many chronic inflammatory diseases, including autoimmune diseases
CD8+ cells may also be involved in some of these autoimmune diseases and may be the
dominant effector cells in certain reactions, especially those that follow viral infection
Autoimmune Diseases
 AUTOIMMUNITY
Immune reactions against self antigens
Important cause of certain diseases in humans
Estimated to affect at least 1% to 2% of the US population
 AUTOIMMUNITY
Mere presence of autoantibodies does not indicate an autoimmune disease
exists
Autoantibodies can be found in the serum of apparently normal individuals,
particularly in older age groups
Innocuous autoantibodies are sometimes produced after damage to tissues
and may serve a physiologic role in the removal of tissue breakdown products
 AUTOIMMUNITY
PATHOLOGIC AUTOIMMUNITY
At least three requirements should be met
(1) Presence of an immune reaction specific for some self antigen or self tissue
(2) Evidence that such a reaction is not secondary to tissue damage but is of primary
pathogenic significance
(3) Absence of another well-defined cause of the disease
 AUTOIMMUNITY
PATHOLOGIC AUTOIMMUNITY
IMMUNE-MEDIATED INFLAMMATORY DISEASES
Disorders in which chronic inflammation is a prominent component
May be autoimmune, or the immune response may be directed against normally harmless
microbes such as gut commensal bacteria.
 AUTOIMMUNE DISEASES
Clinical manifestations are extremely varied
Immune responses are directed against a single organ or tissue, resulting in ORGAN-
SPECIFIC DISEASE
Autoimmune reactions are against widespread antigens, resulting in SYSTEMIC OR
GENERALIZED DISEASE
ORGAN-SPECIFIC DISEASE – DM Type I, multiple sclerosis
SYSTEMIC OR GENERALIZED DISEASE - SLE
 AUTOIMMUNE DISEASES
IMMUNOLOGIC TOLERANCE
Phenomenon of unresponsiveness to an antigen induced by exposure of lymphocytes to
that antigen
SELF-TOLERANCE
Refers to lack of responsiveness to an individual’s own antigens
Underlies our ability to live in harmony with our cells and tissues
 AUTOIMMUNE DISEASES
Mechanisms of self-tolerance can be broadly classified into two groups:
CENTRAL TOLERANCE
PERIPHERAL TOLERANCE
 AUTOIMMUNE DISEASES
CENTRAL TOLERANCE
Immature self-reactive T and B lymphocyte clones that recognize self antigens during
their maturation in the central (or generative) lymphoid organs (the thymus for T cells
and the bone marrow for B cells) are killed or rendered harmless
NEGATIVE SELECTION OR DELETION
When immature lymphocytes encounter antigens in the thymus, many of the cells die by
apoptosis
Responsible for eliminating self-reactive lymphocytes from the T-cell pool
 AUTOIMMUNE DISEASES
CENTRAL TOLERANCE
AIRE (AUTOIMMUNE REGULATOR)
Protein that stimulates expression of some “peripheral tissue-restricted” self antigens in the
thymus
Critical for deletion of immature T cells specific for these antigens.
Mutations are the cause of an autoimmune polyendocrinopathy
 AUTOIMMUNE DISEASES
CENTRAL TOLERANCE
RECEPTOR EDITING
When developing B cells strongly recognize self antigens in the bone marrow, many of the
cells reactivate the machinery of antigen receptor gene rearrangement and begin to express
new antigen receptors, not specific for self antigens
Estimated that a quarter to half of all B cells in the body may have undergone receptor editing
during their maturation.
If receptor editing does not occur, the self reactive cells undergo apoptosis, thus purging
potentially dangerous lymphocytes from the mature pool.
 AUTOIMMUNE DISEASES
PERIPHERAL TOLERANCE
Several mechanisms silence potentially autoreactive T and B cells in peripheral tissues;
these are best defined for T cells.
ANERGY
Lymphocytes that recognize self antigens may be rendered functionally unresponsive
SUPPRESSION BY REGULATORY T CELLS
A population of T cells called REGULATORY T CELLS functions to prevent immune
reactions against self antigens
Best defined regulatory T cells
CD4+ cells that express high levels of CD25, the α chain of the IL-2 receptor, and a
transcription factor of the forkhead family, called FOXP3
 AUTOIMMUNE DISEASES
PERIPHERAL TOLERANCE
DELETION BY APOPTOSIS
T cells that recognize self antigens may receive signals that promote their death by
apoptosis.
Two mechanisms of deletion of mature T cells have been proposed, based mainly on
studies in mice
If T cells recognize self antigens, they may express a pro-apoptotic member of the
Bcl family, called Bim. Unopposed Bim triggers apoptosis by the mitochondrial
pathway
A second mechanism of activation-induced death of CD4+ T cells and B cells
involves the Fas-Fas ligand system
 AUTOIMMUNE DISEASES
PERIPHERAL TOLERANCE
IMMUNE PRIVILEGED SITES
Some antigens are hidden (sequestered) from the immune system, because the tissues in
which these antigens are located do not communicate with the blood and lymph
Self antigens fail to elicit immune responses and are essentially ignored by the immune
system
Testis, eye, and brain
 AUTOIMMUNE DISORDERS
Mechanisms of Autoimmunity: General Principles
Autoimmunity arises from a combination of the inheritance of susceptibility genes,
which may contribute to the breakdown of self-tolerance, and environmental triggers,
such as infections and tissue damage, which promote the activation of self-reactive
lymphocytes.
Defective tolerance or regulation
Abnormal display of self antigens
Inflammation or an initial innate immune response.
 AUTOIMMUNE DISEASES
Role of Susceptibility Genes
Most autoimmune diseases are complex multigenic disorders.
Incidence of many autoimmune diseases is greater in twins of affected individuals than
in the general population, and greater in monozygotic than in dizygotic twins
 AUTOIMMUNE DISEASES
Role of Susceptibility Genes
Association of HLA Alleles with Disease
HLA genes
ankylosing spondylitis - HLA-B27
Association of Non-MHC Genes with Autoimmune Diseases
Multiple non-MHC genes are associated with various autoimmune diseases
Polymorphisms in a gene called PTPN22, which encodes a protein tyrosine phosphatase,
are associated with rheumatoid arthritis, type 1 diabetes, and several other autoimmune
diseases.
Polymorphisms in the gene for NOD2 are associated with Crohn disease, a form of
inflammatory bowel disease, especially in certain ethnic populations.
Polymorphisms in the genes encoding the IL-2 receptor (CD25) and IL-7 receptor α
chains are associated with multiple sclerosis and other autoimmune diseases.
 AUTOIMMUNE DISEASES
Role of Infections
Autoimmune reactions may be triggered by infections.
MOLECULAR MIMICRY
Some microbes may express antigens that have the same amino acid sequences as self
antigens.
RHEUMATIC HEART DISEASE
Antibodies against streptococcal proteins cross-react with myocardial proteins and
cause myocarditis
 AUTOIMMUNE DISEASES
General Features of Autoimmune Diseases
Autoimmune diseases tend to be chronic, sometimes with relapses and remissions, and
the damage is often progressive.
The clinical and pathologic manifestations of an autoimmune disease are determined by
the nature of the underlying immune response.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Autoimmune disease involving multiple organs
Characterized by a vast array of autoantibodies, particularly antinuclear antibodies
(ANAs)
Injury is caused mainly by deposition of immune complexes and binding of antibodies to
various cells and tissues.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
May be acute or insidious in its onset
Chronic, remitting and relapsing, febrile, illness
Injury to the skin, joints, kidney, and serosal membranes is prominent
Clinical presentation is so variable that the American College of Rheumatology has
established a complex set of criteria for this disorder, which is helpful for clinicians and
for the design and assessment of clinical trials
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Prevalence: 1 in 2500 in certain populations
Predominantly affects women, with a frequency of 1 in 700 among women of
childbearing age and a female-to-male ratio of 9 : 1 during the reproductive age group of
17 through 55 years
Prevalence of the disease is 2- to 3-fold higher in blacks and Hispanics than in whites
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Spectrum of Autoantibodies in SLE
Hallmark: production of autoantibodies
Some antibodies recognize diverse nuclear and cytoplasmic components of the cell that are
neither organ- nor species-specific, and others are directed against cell surface antigens of
blood cells
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Spectrum of Autoantibodies in SLE
ANTINUCLEAR ANTIBODIES (ANAs)
Directed against nuclear antigens and can be grouped into four categories:
(1) Antibodies to DNA
(2) Antibodies to histones
(3) Antibodies to nonhistone proteins bound to RNA
(4) Antibodies to nucleolar antigens
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Spectrum of Autoantibodies in SLE
ANTINUCLEAR ANTIBODIES (ANAs)
INDIRECT IMMUNOFLUORESCENCE
Most widely used method for detecting ANAs
Identify antibodies that bind to a variety of nuclear antigens, including DNA, RNA,
and proteins (collectively called generic ANAs)
Pattern of nuclear fluorescence suggests the type of antibody present in the
patient’s serum
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Spectrum of Autoantibodies in SLE
ANTINUCLEAR ANTIBODIES (ANAs)
INDIRECT IMMUNOFLUORESCENCE
Basic patterns are recognized
Homogeneous or diffuse nuclear staining
Rim or peripheral staining patterns.
Speckled pattern
Nucleolar pattern
Centromeric pattern
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Spectrum of Autoantibodies in SLE
ANTINUCLEAR ANTIBODIES (ANAs)
INDIRECT IMMUNOFLUORESCENCE
Basic patterns are recognized
Homogeneous or diffuse nuclear staining
Usually reflects antibodies to chromatin, histones, and, occasionally,
double-stranded DNA.
Rim or peripheral staining patterns
Indicative of antibodies to double-stranded DNA and some times to
nuclear envelope proteins.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Spectrum of Autoantibodies in SLE
ANTINUCLEAR ANTIBODIES (ANAs)
INDIRECT IMMUNOFLUORESCENCE
Basic patterns are recognized
Speckled pattern
Refers to the presence of uniform or variable-sized speckles
One of the most commonly observed patterns of fluorescence and
therefore the least specific
Reflects the presence of antibodies to non-DNA nuclear constituents such
as Sm antigen, ribonucleoprotein, and SS-A and SS-B reactive antigens.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Spectrum of Autoantibodies in SLE
ANTINUCLEAR ANTIBODIES (ANAs)
INDIRECT IMMUNOFLUORESCENCE
Basic patterns are recognized
Nucleolar pattern
Presence of a few discrete spots of fluorescence within the nucleus and
represents antibodies to RNA
Reported most often in patients with systemic sclerosis.
Centromeric pattern
Patients with systemic sclerosis
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Spectrum of Autoantibodies in SLE
ANTINUCLEAR ANTIBODIES (ANAs)
Antibodies to double-stranded DNA and the so-called Smith (Sm) antigen are virtually
diagnostic of SLE
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Spectrum of Autoantibodies in SLE
Other Autoantibodies
ANTIPHOSPHOLIPID ANTIBODIES
Present in 30% to 40% of lupus patients
Directed against epitopes of plasma proteins that are revealed when the proteins
are in complex with phospholipids.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Etiology and Pathogenesis of SLE
Fundamental defect is a failure of the mechanisms that maintain self-tolerance.
Both genetic and environmental factors play a role
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Etiology and Pathogenesis of SLE
Genetic Factors
Family members of patients have an increased risk of developing SLE. As many as 20% of
clinically unaffected first-degree relatives of SLE patients reveal auto antibodies and
other immunoregulatory abnormalities.
Higher rate of concordance (>20%) in monozygotic twins when compared with dizygotic
twins (1% to 3%).
Some lupus patients have inherited deficiencies of early complement components, such
as C2, C4, or C1q. Lack of complement may impair removal of circulating immune
complexes by the mononuclear phagocyte system, thus favoring tissue deposition.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Etiology and Pathogenesis of SLE
Immunologic Factors
Failure of self-tolerance in B cells results from defective elimination of self-reactive B
cells in the bone marrow or defects in peripheral tolerance mechanisms.
CD4+ helper T cells specific for nucleosomal antigens also escape tolerance and
contribute to the production of high-affinity pathogenic autoantibodies.
Type I interferons play a role in lymphocyte activation in SLE.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Etiology and Pathogenesis of SLE
Environmental Factors
Exposure to ultraviolet (UV) light exacerbates the disease in many individuals
Gender bias of SLE is partly attributable to actions of sex hormones and partly related to
genes on the X chromosome, independent of hormone effects.
Drugs such as hydralazine, procainamide, and D-penicillamine can induce an SLE-like
response in humans
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Mechanism of Tissue Injury.
Most of the systemic lesions are caused by immune complexes (type III hypersensitivity).
DNA-anti-DNA complexes can be detected in the glomeruli and small blood vessels.
Autoantibodies specific for red cells, white cells, and platelets opsonize these cells and
promote their phagocytosis and lysis.
In tissues, nuclei of damaged cells react with ANAs, lose their chromatin pattern, and
become homogeneous, to produce so-called LE BODIES or HEMATOXYLIN BODIES.
LE CELL is any phagocytic leukocyte (blood neutrophil or macrophage) that has engulfed
the denatured nucleus of an injured cell.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Mechanism of Tissue Injury
ANTIPHOSPHOLIPID ANTIBODY SYNDROME
Patients with antiphospholipid antibodies may develop venous and arterial thromboses,
which may be associated with recurrent spontaneous miscarriages and focal cerebral or
ocular ischemia.
SECONDARY ANTIPHOSPHOLIPID ANTIBODY SYNDROME
Constellation of clinical features, in association with lupus
Mechanisms of thrombosis are not defined, and antibodies against clotting factors,
platelets and endothelial cells have all been proposed as being responsible for
thrombosis
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Extremely variable
Most characteristic lesions result from immune complex deposition in
Blood vessels
Kidneys
Connective tissue
Skin
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Blood Vessels
Acute necrotizing vasculitis involving capillaries, small arteries and arterioles
Arteritis characterized by fibrinoid deposits in the vessel walls
Chronic stages, vessels undergo fibrous thickening with luminal narrowing
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Kidney
Up to 50% of SLE patients have clinically significant renal involvement
All of the glomerular lesions are the result of deposition of immune complexes
that are regularly present in the mesangium or along the entire basement
membrane and sometimes throughout the glomerulus.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Kidney
According to the currently accepted classification, six patterns of glomerular
disease are seen in SLE
Some overlap within these classes and over time lesions may evolve from one
class to another
Class I is the least common and class IV is the most common pattern.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Kidney
Six patterns of glomerular disease seen in SLE
MINIMAL MESANGIAL LUPUS NEPHRITIS (CLASS I)
MESANGIAL PROLIFERATIVE LUPUS NEPHRITIS (CLASS II)
FOCAL LUPUS NEPHRITIS (CLASS III)
DIFFUSE LUPUS NEPHRITIS (CLASS IV)
MEMBRANOUS LUPUS NEPHRITIS (CLASS V)
ADVANCED SCLEROSING LUPUS NEPHRITIS (CLASS VI)
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Kidney
MINIMAL MESANGIAL LUPUS NEPHRITIS (CLASS I)
Very uncommon
Characterized by immune complex deposition in the mesangium, identified
by immunoflourescence and by electron microscopy, but without structural
changes by light microscopy
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Kidney
MESANGIAL PROLIFERATIVE LUPUS NEPHRITIS (CLASS II)
Characterized by mesangial cell proliferation, often accompanied by
accumulation of mesangial matrix, and granular mesangial deposits of
immunoglobulin and complement without involvement of glomerular
capillaries.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Kidney
FOCAL LUPUS NEPHRITIS (CLASS III)
Defined by involvement of fewer than 50% of all glomeruli.
Lesions may be segmental (affecting only a portion of the glomerulus) or global (involving
the entire glomerulus).
Affected glomeruli may exhibit swelling and proliferation of endothelial and mesangial cells
associated with leukocyte accumulation, capillary necrosis, and hyaline thrombi.
Often extracapillary proliferation associated with focal necrosis and crescent formation
Clinical presentation ranges from mild hematuria and proteinuria to acute renal insufficiency.
Red cell casts in the urine are common when the disease is active. Some patients progress
to diffuse glomerulonephritis.
Active (or proliferative) inflammatory lesions can heal completely or lead to chronic global
or segmental glomerular scarring.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Kidney
DIFFUSE LUPUS NEPHRITIS (CLASS IV)
Most common and severe form of lupus nephritis.
Half or more of the glomeruli are affected.
Lesions may be segmental or global and on the basis of this, it can be subclassified as
class IV segmental (IV-S) or class IV global (IV-G).
Involved glomeruli show proliferation of endothelial, mesangial and epithelial cells, with the
latter producing cellular crescents that fill Bowman’s space
Subendothelial immune complex depos its may create a circumferential thickening of the
capillary wall, forming “wire loop” structures on light microscopy
Immune complexes can be readily detected by electron microscopy and immunofluorescence
Lesions may progress to scarring of glomeruli. Patients with diffuse glomerulonephritis are
usually symptomatic, showing hematuria as well as proteinuria.
Hypertension and mild to severe renal insufficiency are also common.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Kidney
MEMBRANOUS LUPUS NEPHRITIS (CLASS V)
Characterized by diffuse thickening of the capillary walls due to deposition
of subepithelial immune complexes
Immune complexes are usually accompanied by increased production of
basement membrane-like material.
Lesion is usually accompanied by severe proteinuria or nephrotic syndrome,
and may occur concurrently with focal or diffuse lupus nephritis.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Kidney
ADVANCED SCLEROSING LUPUS NEPHRITIS (CLASS VI)
Characterized by sclerosis of more than 90% of the glomeruli, and
represents end-stage renal disease
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Skin
“BUTTERFLY” RASH
Characteristic erythema affects the face along the bridge of the nose and
cheeks in approximately 50% of patients, but a similar rash may also be
seen on the extremities and trunk.
Urticaria, bullae, maculopapular lesions, and ulcerations also occur.
Histologically the involved areas show vacuolar degeneration of the basal layer of
the epidermis
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Skin
Dermis, there is variable edema and perivascular inflammation.
Vasculitis with fibrinoid necrosis may be prominent.
Immunofluorescence microscopy
Deposition of immunoglobulin and complement along the dermoepidermal
junction which may also be present in uninvolved skin.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Joint
Nonerosive synovitis with little deformity
Central Nervous System
Neuropsychiatric symptoms of SLE have often been ascribed to acute vasculitis
Noninflammatory occlusion of small vessels by intimal proliferation is sometimes
noted, which may be due to endothelial damage by autoantibodies or immune
complexes.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Pericarditis and Other Serosal Cavity Involvement
Inflammation of the serosal lining membranes may be acute, subacute, or
chronic
Acute phases - mesothelial surfaces are sometimes covered with fibrinous
exudate. Later they become thickened, opaque, and coated with a shaggy
fibrous tissue that may lead to partial or total obliteration of the serosal
cavity.
Pleural and pericardial effusions may be present
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Cardiovascular system
Symptomatic or asymptomatic pericardial involvement is present in up to 50% of
patients.
Myocarditis, or mononuclear cell infiltration, is less common and may cause
resting tachycardia and electrocardiographic abnormalities.
Valvular abnormalities, primarily of the mitral and aortic valves, manifest as
diffuse leaflet thickening that may be associated with dysfunction (stenosis and/or
regurgitation).
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Cardiovascular system
Valvular (or so-called LIBMAN-SACKS) endocarditis was more common prior to
the widespread use of steroids.
Nonbacterial verrucous endocarditis takes the form of single or multiple 1-
to 3-mm warty deposits on any heart valve, distinctively on either surface
of the leaflets
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Morphology
Spleen
Splenomegaly, capsular thickening, and follicular hyperplasia are common features.
Central penicilliary arteries may show concentric intimal and smooth muscle cell
hyperplasia, producing so-called onion-skin
Lungs
Pleuritis and pleural effusions, present in almost 50% of patients
Chronic interstitial fibrosis and secondary pulmonary hypertension.
Other Organs and Tissues
LE, or hematoxylin, bodies in the bone marrow or other organs are strongly
indicative of SLE. Lymph nodes may be enlarged with hyperplastic follicles or
even demonstrate necrotizing lymphadenitis.
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Clinical Features
Typically, patient is a young woman with some of the following features:
Butterfly rash over the face
Fever
Pain but no deformity in one or more peripheral joints (feet, ankles, knees, hips, fingers,
wrists, elbows, shoulders)
Pleuritic chest pain
Photosensitivity
 AUTOIMMUNE DISEASES
SYSTEMIC LUPUS ERYTHEMATOSUS (SLE)
Clinical Features
With appropriate therapy, the disease is characterized by flare-ups and remissions spanning a
period of years or even decades.
Disease flares are usually treated with corticosteroids or other immunosuppressive drugs.
Even without therapy, in some patients the disease may run an indolent course with relatively
mild manifestations, such as skin changes and mild hematuria, for years.
Outcome has improved significantly, and an approximately 90% 5-year and 80% 10-year
survival can be expected
Most common causes of death are renal failure and intercurrent infections. Coronary artery
disease is also becoming an important cause of death.
 AUTOIMMUNE DISEASES
CHRONIC DISCOID LUPUS ERYTHEMATOSUS.
Disease in which the skin manifestations may mimic SLE, but systemic manifestations are
rare
Characterized by the presence of skin plaques showing varying degrees of edema,
erythema, scaliness, follicular plugging, and skin atrophy surrounded by an elevated
erythematous border
Face and scalp are usually affected, but widely disseminated lesions occasionally occur.
Usually confined to the skin, but 5% to 10% of patients develop multisystem
manifestations after many years.
 AUTOIMMUNE DISEASES
CHRONIC DISCOID LUPUS ERYTHEMATOSUS
Approximately 35% of patients show a positive test for generic ANAs
Immunofluorescence studies of skin biopsy specimens show deposition of
immunoglobulin and C3 at the dermoepidermal junction similar to that in SLE
 AUTOIMMUNE DISEASES
SUBACUTE CUTANEOUS LUPUS ERYTHEMATOSUS
Also presents with predominant skin involvement and can be distinguished from chronic
discoid lupus erythematosus by several criteria
Skin rash in this disease tends to be widespread, superficial, and nonscarring, although
scarring lesions may occur in some patients.
Most patients have mild systemic symptoms consistent with SLE
Strong association with antibodies to the SS-A antigen and with the HLA-DR3 genotype.
Group intermediate between SLE and lupus erythematosus localized only to skin.
 AUTOIMMUNE DISEASES
DRUG-INDUCED LUPUS ERYTHEMATOSUS
Lupus erythematosus-like syndrome may develop in patients receiving a variety of drugs,
including
Hydralazine
Procainamide
Isoniazid
D-penicillamine
Anti-TNF therapy, which is effective in rheumatoid arthritis and other autoimmune
diseases, can also cause drug-induced lupus
 AUTOIMMUNE DISEASES
DRUG-INDUCED LUPUS ERYTHEMATOSUS
Many of these drugs are associated with the development of ANAs, but most patients do
not have symptoms of lupus erythematosus.
Persons with the HLA-DR4 allele are at a greater risk of developing a lupus
erythematosus-like syndrome after administration of hydralazine, whereas those with
HLA-DR6 (but not DR4) are at high risk with procainamide
Remits after withdrawal of the offending drug
 AUTOIMMUNE DISEASES
SJÖGREN SYNDROME
Chronic disease characterized by
DRY EYES (KERATOCONJUNCTIVITIS SICCA)
DRY MOUTH (XEROSTOMIA)
Results from immunologically mediated destruction of the lacrimal and salivary glands
Occurs as an isolated disorder (PRIMARY FORM), also known as the SICCA SYNDROME,
or more often in association with another autoimmune disease (SECONDARY FORM)
 AUTOIMMUNE DISEASES
SJÖGREN SYNDROME
Etiology and Pathogenesis
Characteristic decrease in tears and saliva (sicca syndrome) is the result of lymphocytic
infiltration and fibrosis of the lacrimal and salivary glands
Infiltrate contains predominantly activated CD4+ helper T cells and some B cells, including
plasma cells.
About 75% of patients have rheumatoid factor (an antibody reactive with self IgG) whether or
not coexisting rheumatoid arthritis is present.
ANAs are detected in 50% to 80% of patients by immunofluorescence assay
 AUTOIMMUNE DISEASES
SJÖGREN SYNDROME
Etiology and Pathogenesis
Antibodies directed against two ribonucleoprotein antigens, SS-A (Ro) and SS-B (La) are
detected in as many as 90% of patients by sensitive techniques
Considered serologic markers of the disease.
Patients with high titers of antibodies to SS-A are more likely to have
Early disease onset
Longer disease duration
Extraglandular manifestations, such as cutaneous vasculitis and nephritis
 AUTOIMMUNE DISEASES
SJÖGREN SYNDROME
Etiology and Pathogenesis
Although the pathogenesis remains obscure, aberrant T-cell and B-cell activation are both
implicated
 AUTOIMMUNE DISEASES
SJÖGREN SYNDROME
Morphology
Lacrimal and salivary glands are the major targets of the disease
Other exocrine glands, including those lining the respiratory and gastrointestinal tracts
and the vagina, may also be involved
Earliest histologic finding in both the major and the minor salivary glands is
periductal and perivascular lymphocytic infiltration
Eventually the lymphocytic infiltrate becomes extensive and in the larger salivary
glands lymphoid follicles with germinal centers may be seen
Ductal lining epithelial cells may show hyperplasia, thus obstructing the ducts.
 AUTOIMMUNE DISEASES
SJÖGREN SYNDROME
Morphology
Later there is atrophy of the acini, fibrosis, and hyalinization; still later in the course
atrophy and replacement of parenchyma with fat are seen.
Patients are at high risk for development of B-cell lymphomas
Lack of tears leads to drying of the corneal epithelium, which becomes inflamed,
eroded, and ulcerated
Oral mucosa may atrophy, with inflammatory fissuring and ulceration;
Dryness and crusting of the nose may lead to ulcerations and even perforation of
the nasal septum.
 AUTOIMMUNE DISEASES
SJÖGREN SYNDROME
Clinical Features
Occurs most commonly in women between the ages of 50 and 60
Symptoms result from inflammatory destruction of the exocrine glands
Keratoconjunctivitis produces blurring of vision, burning, and itching, and thick
secretions accumulate in the conjunctival sac
Xerostomia results in difficulty in swallowing solid foods, a decrease in the ability to
taste, cracks and fissures in the mouth, and dryness of the buccal mucosa
 AUTOIMMUNE DISEASES
SJÖGREN SYNDROME
Clinical Features
Lymph nodes are often hyperplastic
About 5% of patients develop lymphoma, an incidence that is 40-fold greater than normal.
 AUTOIMMUNE DISEASES
SYSTEMIC SCLEROSIS (SCLERODERMA)
Characterized by:
(1) Chronic inflammation thought to be the result of autoimmunity
(2) Widespread damage to small blood vessels
(3) Progressive interstitial and perivascular fibrosis in the skin and multiple organs
Characterized by excessive fibrosis throughout the body.
Skin is most commonly affected, but the gastrointestinal tract, kidneys, heart, muscles,
and lungs also are frequently involved
 AUTOIMMUNE DISEASES
SYSTEMIC SCLEROSIS (SCLERODERMA)
Two major categories:
DIFFUSE SCLERODERMA
Characterized by widespread skin involvement at onset
Rapid progression and early visceral involvement
LIMITED SCLERODERMA
Skin involvement is often confined to fingers, forearms, and face
 AUTOIMMUNE DISEASES
SYSTEMIC SCLEROSIS (SCLERODERMA)
Some patents with the limited disease also develop a combination of calcinosis, Raynaud
phenomenon, esophageal dysmotility, sclerodactyly, and telangiectasia, called the CREST
SYNDROME
 AUTOIMMUNE DISEASES
SYSTEMIC SCLEROSIS (SCLERODERMA)
Etiology and Pathogenesis
Cause is not known, but the disease likely results from three interrelated processes
Autoimmune responses
Vascular damage
Collagen deposition
 AUTOIMMUNE DISEASES
SYSTEMIC SCLEROSIS (SCLERODERMA)
Etiology and Pathogenesis
Autoimmune responses
Proposed that CD4+ T cells responding to an as yet unidentified antigen accumulate in
the skin and release cytokines that activate inflammatory cells and fibroblasts
 AUTOIMMUNE DISEASES
SYSTEMIC SCLEROSIS (SCLERODERMA)
Etiology and Pathogenesis
Vascular Damage
Microvascular disease present early in the course and may be the initial lesion
Intimal proliferation is evident in the digital arteries of patients
 AUTOIMMUNE DISEASES
SYSTEMIC SCLEROSIS (SCLERODERMA)
Etiology and Pathogenesis
Fibrosis
Progressive fibrosis characteristic of the disease may be the culmination of multiple
abnormalities
Accumulation of alternatively activated macrophages
Actions of fibrogenic cytokines produced by infiltrating leukocytes
Hyperresponsiveness of fibroblasts to these cytokines
Scarring following upon ischemic damage caused by the vascular lesions
 AUTOIMMUNE DISEASES
SYSTEMIC SCLEROSIS (SCLERODERMA)
Morphology
Skin
Diffuse, sclerotic atrophy of the skin, which usually begins in the fingers and
distal regions of the upper extremities and extends proximally to involve the
upper arms, shoulders, neck, and face.
Histologically, there are edema and perivascular infiltrates containing CD4+ t cells,
together with swelling and degeneration of collagen fibers, which become
eosinophilic
Capillaries and small arteries (150 to 500 µm in diameter) may show thickening
of the basal lamina, endothelial cell damage, and partial occlusion.
With progression of the disease, there is increasing fibrosis of the dermis, which
becomes tightly bound to the subcutaneous structures.
 AUTOIMMUNE DISEASES
SYSTEMIC SCLEROSIS (SCLERODERMA)
Morphology
Skin
Marked increase of compact collagen in the dermis,
Focal and sometimes diffuse subcutaneous calcifications may develop, especially
in patients with the CREST syndrome.
In advanced stages the fingers take on a tapered, clawlike appearance with
limitation of motion in the joints,
Face becomes a drawn mask
 AUTOIMMUNE DISEASES
SYSTEMIC SCLEROSIS (SCLERODERMA)
Morphology
Alimentary Tract
Affected in approximately 90% of patients
Progressive atrophy and collagenous fibrous replacement of the muscularis may
develop at any level of the gut but are most severe in the esophagus
Lower two thirds of the esophagus often develops a rubber-hose–like
inflexibility.
Mucosa is thinned and may be ulcerated, and there is excessive collagenization
of the lamina propria and submucosa
 AUTOIMMUNE DISEASES
SYSTEMIC SCLEROSIS (SCLERODERMA)
Morphology
Musculoskeletal System
Inflammation of the synovium, associated with hypertrophy and hyperplasia of
the synovial soft tissues, is common in the early stages; fibrosis later ensues.
 AUTOIMMUNE DISEASES
SYSTEMIC SCLEROSIS (SCLERODERMA)
Morphology
Kidneys
Most prominent are the vascular lesions
Interlobular arteries show intimal thickening as a result of deposition of
mucinous or finely collagenous material, which stains histochemically for
glycoprotein and acid mucopolysaccharides.
Concentric proliferation of intimal cells.
Hypertension occur in 30% of patients with scleroderma, and in 20% it takes an
ominously rapid, downhill course (malignant hypertension).
 AUTOIMMUNE DISEASES
SYSTEMIC SCLEROSIS (SCLERODERMA)
Morphology
Lungs
Involved in more than 50% of individuals
Pulmonary hypertension and interstitial fibrosis.
Heart.
Pericarditis with effusion
Myocardial fibrosis, and thickening of intramyocardial arterioles occur in one third
of the patients
 AUTOIMMUNE DISEASES
SYSTEMIC SCLEROSIS (SCLERODERMA)
Clinical Features.
Female-to-male ratio of 3 : 1, with a peak incidence in the 50- to 60-year age group
Distinctive features are the striking cutaneous changes, notably skin thickening.
Raynaud phenomenon, manifested as episodic vasoconstriction of the arteries and arterioles
of the extremities, is seen in virtually all patients and precedes other symptoms in 70% of
cases
Dysphagia attributable to esophageal fibrosis and its resultant hypomotility are present in
more than 50% of patients
Most ominous manifestation is malignant hypertension
 AUTOIMMUNE DISEASES
SYSTEMIC SCLEROSIS (SCLERODERMA)
Clinical Features.
Two ANAs strongly associated with systemic sclerosis have been described.
Directed against DNA topoisomerase I (anti-Scl 70), is highly specific.
Depending on the ethnic group and the assay, it is present in 10% to 20% of patients
with diffuse systemic
Patients who have this antibody are more likely to have pulmonary fibrosis and
peripheral vascular disease.
Anticentromere antibody, is found in 20% to 30% of patients, who tend to have the
CREST syndrome.
 AUTOIMMUNE DISEASES
MIXED CONNECTIVE TISSUE DISEASE
Used to describe a disease with clinical features that are a mixture of the features of SLE,
systemic sclerosis, and polymyositis
Characterized serologically by high titers of antibodies to ribonucleoprotein particle-
containing U1 ribonucleoprotein
Presents with synovitis of the fingers, Raynaud phenomenon and mild myositis, but renal
involvement is modest and there is a good response to corticosteroids
Serious complications of mixed connective tissue disease include pulmonary
hypertension, interstitial lung disease, and renal disease.
 AUTOIMMUNE DISEASES
IgG4-RELATED DISEASE (IgG4-RD)
Newly recognized constellation of disorders characterized by tissue infiltrates dominated
by IgG4 antibody-producing plasma cells and lymphocytes, particularly T cells, storiform
fibrosis, obliterative phlebitis, and usually increased serum IgG4
Pathogenesis is not understood
IgG4 production in lesions is a hallmark of the disease it is not known if this antibody
type contributes to the pathology
Key role of B cells is supported by initial clinical trials in which depletion of B cells by
anti–B cell reagents such as rituximab provided clinical benefit
Unclear if the disease is truly autoimmune in nature, and no target autoantigens have
been identified
Rejection of Tissue Transplants
 Rejection of Tissue Transplants
REJECTION
Process in which T lymphocytes and antibodies produced against graft antigens react
against and destroy tissue grafts.
 Rejection of Tissue Transplants
Recognition of Graft Alloantigens by T and B Lymphocytes
Major antigenic differences between a donor and recipient that result in rejection of
transplants are differences in HLA alleles.
ALLOGRAFTS - grafts exchanged between individuals of the same species
XENOGRAFTS- grafts from one species to another
 Rejection of Tissue Transplants
Recognition of Graft Alloantigens by T and B Lymphocytes
Following transplantation, the recipient’s T cells recognize donor antigens from the graft
(the allogeneic antigens, or alloantigens) by two pathways, called direct and indirect
 Rejection of Tissue Transplants
Recognition of Graft Alloantigens by T and B Lymphocytes
DIRECT PATHWAY OF ALLORECOGNITION
T cells of the transplant recipient recognize allogeneic (donor) MHC molecules on the surface
of APCs in the graft
INDIRECT PATHWAY OF ALLORECOGNITION
Recipient T lymphocytes recognize MHC antigens of the graft donor after they are presented
by the recipient’s own APCs
Involves the uptake and processing of MHC molecules from the grafted organ by host APCs
Generates CD4+ T cells that enter the graft and recognize graft antigens being displayed by
host APCs that have also entered the graft, and the result is a delayed hypersensitivity type of
inflammatory reaction
 Rejection of Tissue Transplants
T CELL–MEDIATED REACTIONS
T cells can contribute to both acute and chronic rejection.
ACUTE CELLULAR REJECTION
Most commonly seen within the initial months after transplantation
Direct killing of graft cells by CD8+ CTLs is a major component of the reaction
Inflammation results in increased vascular permeability and local accumulation of
mononuclear cells (lymphocytes and macrophages), and graft injury is caused by the
activated macrophages
 Rejection of Tissue Transplants
T CELL–MEDIATED REACTIONS
T cells can contribute to both acute and chronic rejection.
CHRONIC REJECTION
Lymphocytes reacting against alloantigens in the vessel wall secrete cytokines that
induce local inflammation and may stimulate the proliferation of vascular endothelial
and smooth muscle cells
 Rejection of Tissue Transplants
ANTIBODY-MEDIATED REACTIONS
Antibodies produced against alloantigens in the graft are also important mediators of
rejection
Antibody-mediated reactions can take three forms
HYPERACUTE REJECTION
ACUTE ANTIBODY-MEDIATED REJECTION
CHRONIC ANTIBODY-MEDIATED REJECTION
 Rejection of Tissue Transplants
ANTIBODY-MEDIATED REACTIONS
HYPERACUTE REJECTION
Occurs when preformed antidonor antibodies are present in the circulation of the recipient.
present in a recipient who has previously rejected a transplant
Multiparous women who develop antibodies against paternal HLA antigens shed from the
fetus may have preformed antibodies that will react with grafts taken from their husbands or
children, or even from unrelated individuals who share HLA alleles with the husbands
Blood transfusions can also lead to presensitization, because platelets and white blood cells
are rich in HLA antigens and donors and recipients are usually not HLA-identical
 Rejection of Tissue Transplants
ANTIBODY-MEDIATED REACTIONS
ACUTE ANTIBODY-MEDIATED REJECTION
Caused by antidonor antibodies produced after transplantation
Recipients not previously sensitized to transplantation antigens, exposure to the class I and
class II HLA antigens of the donor graft, as well as other antigens that differ between donor
and recipient, may evoke antibodies
Antibodies formed by the recipient may cause injury by several mechanisms, including
complement-dependent cytotoxicity, inflammation, and antibody-dependent cell-mediated
cytotoxicity
Initial target of these antibodies in rejection seems to be the graft vasculature
 Rejection of Tissue Transplants
ANTIBODY-MEDIATED REACTIONS
CHRONIC ANTIBODY-MEDIATED REJECTION
Usually develops insidiously, without preceding acute rejection
Primarily affects vascular components
Antibodies are detected in the circulation but are not readily identified within the graft
Mechanisms of the vascular lesions are not well understood
 Rejection of Kidney Grafts
Morphology
HYPERACUTE REJECTION
Occurs within minutes or hours after transplantation
Hyperacutely rejecting kidney rapidly becomes cyanotic, mottled, and flaccid, and may
excrete a mere few drops of bloody urine
Immunoglobulin and complement are deposited in the vessel wall, causing endothelial injury
and fibrin-platelet thrombi
Neutrophils rapidly accumulate within arterioles, glomeruli, and peritubular capillaries.
Glomeruli undergo thrombotic occlusion of the capillaries, and fibrinoid necrosis occurs in
arterial walls
Kidney cortex then undergoes outright necrosis (infarction), and such nonfunctioning kidneys
have to be removed.
 Rejection of Kidney Grafts
Morphology
ACUTE REJECTION
Within days of transplantation in the untreated recipient or may appear suddenly months or even years later,
after immunosuppression is tapered or terminated. In any one patient, cellular or humoral immune mechanisms
may predominate.
ACUTE CELLULAR (T CELL-MEDIATED) REJECTION.
Two patterns
TUBULOINTERSTITIAL PATTERN (sometimes called type I)
extensive interstitial inflammation with infiltration of tubules associated with focal tubular
injury
immunohistochemical staining reveals both CD4+ and CD8+ T lymphocytes, which express
markers of activated T cells, such as the α chain of the IL-2 receptor.
VASCULAR PATTERN shows inflammation of vessels (endotheliitis, type II)
Sometimes with necrosis of vascular walls (type III)
Affected vessels have swollen endothelial cells, and at places the lymphocytes can be seen
between the endothelium and the vessel wall.
Recognition of cellular rejection is important because, in the absence of an accompanying
humoral rejection, patients respond well to immunosuppressive therapy
 Rejection of Kidney Grafts
Morphology
ACUTE REJECTION
ACUTE ANTIBODY-MEDIATED REJECTION
Manifested mainly by damage to glomeruli and small blood vessels.
Lesions consist of inflammation of glomeruli and peritubular capillaries, associated with
deposition of the complement breakdown product C4d, which is produced during
activation of the complement system by the antibody-dependent classical pathway
Small vessels may also show focal thrombosis
 Rejection of Kidney Grafts
Morphology
CHRONIC REJECTION
Emerged as an increasingly frequent cause of graft failure.
Present clinically with progressive renal failure manifested by a rise in serum creatinine over a
period of 4 to 6 months
Dominated by vascular changes, which include
(1) Intimal thickening with inflammation
(2) Glomerulopathy, with duplication of the basement membrane, likely secondary to chronic
endothelial injury, and
(3) Peritubular capillaritis with multilayering of peritubular capillary basement membranes
Interstitial fibrosis and tubular atrophy with loss of renal parenchyma may occur secondary to
the vascular lesions.
Chronically rejecting kidneys usually have interstitial mononuclear cell infiltrates, including NK
cells and plasma cells.
Immunodeficiency Syndromes
 IMMUNODEFICIENCY SYNDROMES
Divided into
PRIMARY (OR CONGENITAL) IMMUNODEFICIENCY DISORDERS
Genetically determined
Detected in infancy, between 6 months and 2 years of life
SECONDARY (OR ACQUIRED) IMMUNODEFICIENCIES
Result from altered immune function caused cancers, infections, malnutrition, or side effects
of immunosuppression, irradiation, or chemotherapy for cancer and other diseases
 IMMUNODEFICIENCY SYNDROMES
PRIMARY IMMUNODEFICIENCIES
Defects in Innate Immunity
Defects in Leukocyte Function
Inherited defects in leukocyte adhesion lead to recurrent bacterial infections caused by
defective leukocyte recruitment
Leukocyte adhesion deficiency type I: defective synthesis of B2 chain shared by
LFA-1 and Mac integrins
Leukocyte adhesion deficiency type II: defective sialyl-Lewis X ligand for E and P-
selectins
 IMMUNODEFICIENCY SYNDROMES
PRIMARY IMMUNODEFICIENCIES
Defects in Innate Immunity
Defects in Leukocyte Function
Inherited defects in phagolysosome function
Cause susceptibility to infections caused by neutropenia , defective degranulation and delayed
microbial killing
CHÉDIAK-HIGASHI SYNDROME
Autosomal recessive condition characterized by defective fusion of phagosomes and
lysosomes, resulting in defective phagocytes function and susceptibility to infections
Main leukocyte abnormalities are neutropenia (decreased numbers of neutrophils),
defective degranulation, and delayed microbial killing.
Leukocytes contain giant granules, which can be readily seen in peripheral blood smears
and are thought to result from aberrant phagolysosome fusion.
Abnormalities in melanocytes (leading to albinism), cells of the nervous system and
platelets
Gene associated with this disorder encodes a large cytosolic protein called LYST, which is
believed to regulate lysosomal trafficking
 IMMUNODEFICIENCY SYNDROMES
PRIMARY IMMUNODEFICIENCIES
Defects in Innate Immunity
Defects in Leukocyte Function
Inherited defects in microbicidal activity
CHRONIC GRANULOMATOUS DISEASE
Characterized by defects in bacterial killing and render patients susceptible to
recurrent bacterial infections
Results from inherited defects in the genes encoding components of phagocyte
oxidase, culminating in deficient superoxide production.
 IMMUNODEFICIENCY SYNDROMES
PRIMARY IMMUNODEFICIENCIES
Defects in Innate Immunity
Defects in Leukocyte Function
Defects in TLR signaling
Mutations in TLR3 (a viral DNA receptor)
Leads to recurrent herpes simplex encephalitis
Defects in MyD88 (downstream adaptor protein for several TLRs)
Associated with destructive bacterial pneumonias
 IMMUNODEFICIENCY SYNDROMES
PRIMARY IMMUNODEFICIENCIES
Defects in Innate Immunity
Defects in Complement System
Deficiency of C2
Most common complement protein deficiency
Deficiency of C2 or C4, early components of the classical pathway, is associated with
increased bacterial or viral infection
 IMMUNODEFICIENCY SYNDROMES
PRIMARY IMMUNODEFICIENCIES
Defects in Innate Immunity
Defects in Complement System
Deficiency of components of the alternative pathway (properdin and factor D) is rare. It
is associated with recurrent pyogenic infections
C3 component deficiency
Results in susceptibility to serious and recurrent pyogenic infections
Increased incidence of immune complex-mediated glomerulonephritis
 IMMUNODEFICIENCY SYNDROMES
PRIMARY IMMUNODEFICIENCIES
Defects in Innate Immunity
Defects in Complement System
Deficiency of the terminal components of complement C5, 6, 7, 8, and 9 (required for
the assembly of the membrane attack complex involved in the lysis of organisms)
Increased susceptibility to recurrent Neisserial (gonococcal and meningococcal)
infection
 IMMUNODEFICIENCY SYNDROMES
PRIMARY IMMUNODEFICIENCIES
Defects in Innate Immunity
Defects in Complement System
Deficiency of C1 inhibitor (C1 INH)
Gives rise to HEREDITARY ANGIOEDEMA
C1 inhibitor’s targets are proteases, specifically C1r and C1s of the complement
cascade, factor XII of the coagulation pathway, and the kallikrein system.
Unregulated activation of kallikrein may lead to increased production of vasoactive
peptides such as bradykinin, with recurrent episodes of cutaneous and mucosal
edema
 IMMUNODEFICIENCY SYNDROMES
PRIMARY IMMUNODEFICIENCIES
Defects in Adaptive Immunity
Subclassified on the basis of the primary component involved (B cells or T cells or both)
Result from abnormalities in lymphocyte maturation or activation
 IMMUNODEFICIENCY SYNDROMES
SEVERE COMBINED IMMUNODEFICIENCY (SCID)
Represents a constellation of genetically distinct syndromes
All having in common defects in both humoral and cell-mediated immune responses
Affected infants present with
Prominent thrush (oral candidiasis)
Extensive diaper rash
Failure to thrive
Some patients develop a morbilliform rash shortly after birth because maternal T cells
are transferred across the placenta and attack the fetus, causing GVHD.
 IMMUNODEFICIENCY SYNDROMES
SEVERE COMBINED IMMUNODEFICIENCY (SCID)
Extremely susceptible to recurrent, severe infections by a wide range of pathogens,
including Candida albicans, Pneumocystis jiroveci, Pseudomonas, Cytomegalovirus,
varicella, and a whole host of bacteria.
Without HSC transplantation, death occurs within the first year of life
 IMMUNODEFICIENCY SYNDROMES
SEVERE COMBINED IMMUNODEFICIENCY (SCID)
X-LINKED SCID
Most common form
50% to 60% of cases
More common in boys than in girls
X-linked form is a mutation in the common γ-chain (γc) subunit of cytokine receptors (IL-2, IL-
4, IL-7, IL-9, IL-11, IL-15, and IL-21)
IL-7
Required for the survival and proliferation of lymphoid progenitors, particularly T-cell
precursors
Defective IL-7 receptor signaling, there is a profound defect in the earliest stages of
lymphocyte development, especially T-cell development
 IMMUNODEFICIENCY SYNDROMES
SEVERE COMBINED IMMUNODEFICIENCY (SCID)
AUTOSOMAL RECESSIVE SCID
Most common cause: deficiency of the enzyme adenosine deaminase (ADA).
Deficiency of ADA leads to accumulation of deoxyadenosine and its derivatives (e.g, Deoxy-
ATP), which are toxic to rapidly dividing immature lymphocytes, especially those of the T-cell
lineage
Greater reduction in the number of T lymphocytes than of B lymphocytes
 IMMUNODEFICIENCY SYNDROMES
X-LINKED AGAMMAGLOBULINEMIA (BRUTON AGAMMAGLOBULINEMIA)
Characterized by the failure of B-cell precursors (pro-B cells and pre-B cells) to develop
into mature B cells.
One of the more common forms of primary immunodeficiency
Usually does not become apparent until about 6 months of age