need for peripheral tolerance
mandatory because central is not complete (escapes)
low avidity T-cells
can be activated in unknown circumstances & mediate auto-immune reaction ( self-reaction escaped cells somehow activated)
main auto-immune diseases:
psoriasis
rheumatoid arthritis
graves’ disease
systemic lupus erythematosus
multiple sclerosis
Multiple sclerosis
in the CNS normally myelinated neurons but the formation of plaque (delineated area)
demyelinated neurons can’t fulfill their function —> handicap
MS due to self-reactive CD8+ T-cells killing oligodendrocytes that produce myelin
Layers of tolerance
Central tolerance
Peripheral energy
Regulatory T-cells
Activation-induced cell death
Peripheral anergy
signal 1 but low signal 2
no priming of T-cells to effector T-cells
cellular inactivation by weak signaling without co-stimulus
in secondary lymphoid tissue
suppression by cytokines, intercellular signals
in secondary lymphoid tissue and sites of inflammation
multiple tissues in steady state
Apoptosis
Antigen segregation
thought that a physical barrier exists to prevent self-antigen access to the lymphoid system
but also migration of DC with antigen in steady-state (presentation of self-antigens to B-&T-cells)
can be the reason for an autoimmune reaction
OT-I CD8 T cells transgenic for a TCR specific for an OVA peptide presented by H-2kb
OVA expressed in melanocytes & injection of class I restricted TCR specific for OVA
Gut draining lymph node control: see transferred labeled CD8 T-cells
in skin DLN: proliferation due to dilution of the dye
—>without any infection migration of DC to present self-antigens
—>no activation of DC, no upregulation of costimulatory signals & B7
—> strong signal 1 without signal 2 (peripheral tolerance)
—>start to be activated by proliferation but never stage of effector T-cell
stain cells with fluorescent dye CFSE (covalent binding of cytoplasmic proteins, stable, upon cell division intensity of dye divided between both cells)
in
immunologically privileged peripheral tissues
brain
eye
testis
uterus
more immuno-suppressive microenvironment
tissue grafts often last indefinitely & antigens placed there don’t elicit destructive immune responses
peripheral anergy/apoptosis
stimulation of naive T-cell —> proliferating T-cell —> differentiation —> active effector T-cells
kill virus-infected target cells
without signal 2: stop at the PROLIFERATION stage
never effector phase
natural regulatory T-cells
T-cell specific for self-antigen recognized in thymus becomes a natural regulatory T-cell (nTreg)
induced in the thymus with high avidity for self (Hassal corpuscle)
in periphery constantly activated by self-antigen
Conventional vs. regulatory T-cells
bith express CTLA-4, TCR, CD4, CD25 at the cell surface
TF Foxp3 specific for nTreg
activation modes of Treg
at distance secreted factors: cytokines IL-10 & TGFß inhibit other self-reactive T-cells
cell/cell contact manner: CTLA4/B7 reverse signaling —> indoleamine2,3deoxygenase (ILDO expression) tryptophane catabolism (reduced proliferation as essential AA)
not antigen-specific!
inhibit any kind of immune reaction —>naturally dampens immune reactions
conventional B-cells vs. regulatory
B1 (unconventional) & Breg express TLR, BCR/IgM, CD40, CD5 at surface
the only difference is that Breg produces IL-10 (but not easy to detect secreted factor —> no marker)
B2 (conventional) expresses TLR, BCR/IgM & CD40 (no CD5)
B-cell peripheral tolerance
the end of central tolerance in the periphery SLO (bone marrow central for B-cells)
transitional B-cells that enter the follicle receive maturation & survival signals —> differentiate into follicular B-cells or marginal zone B-cells
transitional B-cells: IgM high, IgD negative
BCR signaling (mutation in BCR) = ligand-dependent + BAFF signaling
BAFF: important factor (TNF SF) produced by FDC stimulating the development of final maturation of B-cells (signal 1 to transitional B-cells BCR dependent)
too strong signal = exclusion from the follicle & death or MZ B-cell but not conventional B2
BAFF deficient mice have no mature B-cells —> strong phenotype by mutation of 1 gene
Generation of auto-reactive B-cells during GC
somatic hypermutation generates novel B-cell specificities within germinal centers
some of these B-cells may now be able to bind self-antigens
encounter of autoreactive B-cell with self-antigen within germinal center causes apoptosis —> lack T-cell help
auto-reactive T-cells eliminated in the thymus
effectors of auto-immunity
antibodies: antagonist, agonist or pro-inflammatory
auto-reactive T-cells
Autoantibodies against signaling receptors
Graves’ disease with an agonist Ab against Thyroid-stimulating hormone receptor —> pathway overactivated
Myasthenia gravis: antagonist Ab against Ach receptor
Myasthenia gravis
muscle weakness
antagonist Ab against a signaling receptor
neuromuscular function: muscle needs nerves for stimulation of contraction —> release of Ach & stimulation of AChR on the surface of muscle —> Na+ influx & contraction
when auto-Abs against AchR their binding induces internalization & degradation —> muscle unresponsive to ACh —> no Na+ influx & no muscle contraction
blood test: take the serum of the patient & inject it in animal —> disease symptoms also triggered —> immunoprecipitation of Abs for AChR —> binds mouse & human AChR
for production of Ab also auto-reactive CD4 T-cells present
Phenphigus vulgaris
antagonist Abs against adhesion molecules
first mucose than skin —> blistering of the skin
different B-cell epitopes on desmogleins are targeted by auto-Abs (early epitope in the mucosal stage of disease vs. late epitope in skin stage of disease)
Abs made against Dsg-1 & Dsg-3 unzip the adhesive interactions in desmosomes —> intra- & intermolecular epitope spreading
desmoglein is an adhesion molecule in cell junctions holding together keratinocytes
interfere with the physiological adhesive interactions of desmoglein (necessary for skin integrity)
Graves’ disease
agonistic auto-Ab against a signaling receptor
thyroid-stimulating hormone TSH which acts on the thyroid inducing the release of thyroid hormones
the pituitary gland secretes thyroid-stimulating hormone TSH which acts on the thyroid inducing the release of thyroid hormones
TH acts on the hypothalamus & pituitary to shut down the production of TSH, suppressing further TH synthesis
—> Feedback suppression
Autoimmune B-cell makes Abs against TSH-R that also stimulates thyroid hormone production
loose regulation of thyroid hormones —> constitutive release (hyperthyroidism)
TH shut down TSH production but had no effect on auto-Ab production —> excessive TH production
Mother-to-newborn transmission
patient with Graves’ disease makes anti-TSHR Abs transferred across the placenta to the fetus —> newborn with Graves’ disease
Plasmapheresis removes maternal anti-TSHR Abs & cures the disease
spread via non-classical MHC molecule, FCRN transporting IgG
transferable AIDs: myasthenia gravis, Graves’ disease,, thrombocytopenia purpura, pemphigus vulgaris, neonatal lupus rash and/or congenital heart block—>IgG mediated auto-immune disease
little lasting symptoms disappear along with maternal Ab
Systemic Lupus Erythematosus
Inflammatory antibodies
multiple-organs affected: skin, blood vessels, kidney
antibodies against DNT & T-independent responses: BCR + TCR signaling
B-cells with specificity for DNA bind soluble fragments of DNA sending a signal through the BCR
cross-linked BCR is internalized with bound DNA molecule
GC-rich fragments from internalized DNA bind to TLR-9 in an endosomal compartment (co-stimulatory signal)—>hypomethylated CpG sequences rich in prokaryotes & apoptotic cells
B-cells with a strong affinity for DNA are eliminated but with lower affinity escape & persist
—> Cell apoptosis is needed so that DNA is visible to the immune system
DNA associated with proteins —> both internalized by BCR —> proteins can activate TH —>T-dependent high affinity & antibody switch
DNA-specific presents peptides from DNA-associated proteins to T-cells
autoimmune CD8 T-cells attack the myelin sheath from nerves axons in humans —> paralysis
animal model: experimental autoimmune encephalitis
injection of myelin basic protein & complete Freund’s adjuvant develop EAE —> paralyzed (also a drug for permeabilization BBB)
peripheral vaccination with MHC II-restricted peptide from myelin-associated protein disease is mediated by Th17 & Th1 cells specific for myelin basic protein
transmittable via transfer of T-cells from affected animals (activated CD4+ myelin-specific T-cells)
—>similar disease but different effector cells —> animal models not always optimal (in human CD8+)
Type I diabetes
CD8 T-cells infiltrate in the pancreas, in the beginning don’t kill ß-cells (insulitis = presymptomatic stage)
islets of Langerhans: several cell types secreting hormones —> each cell expresses different tissue-specific proteins
T1D: effector T-cell recognizes peptides from a ß-cell specific protein —> destruction of insulin-producing ß-cells —> hyperglycemia
glucagon & somatostatin still produced by the α & δ cells but no insulin made
Rheumatoid arthritis
innate cells as effectors: macrophages & CD4+ T-cells
effects the joints
unknown trigger sets up initial focus of inflammation in synovial membrane attracting leukocytes
auto-reactive CD4 T-cells activates macrophages —> production of pro-inflammatory cytokines & sustained inflammation
cytokines induce production of matrix metalloproteases & RANK ligand by fibroblasts
MMPs tissues & activation of bone-destroying osteoclasts by RANK ligand —> joint destruction
in past treated with nonspecific immunosuppressive drugs, today more specific TNFα
citrullinated proteins
autoantigens
PAD (peptidyl arginine deaminase) converts positively charged arginine residues to neutral citrulline residues
—> loss of surface chages makes the protein more susceptible to proteolytic degradation —> recognized at non-self —> peptides with citrulline residues are presented by HLA class II to CD4 T-cells
Abs against citrullinated proteins —> epitopes recognized after post-translational modification
also rheumatoid factor = antibody against the Fc part of Ig, Abs against other Abs
PAD expressed in tissues stressed by wounds or infection
Etiology
genetuc factors (susceptible genes) in combination with infection & environmental exposure
lead to immune dysregulation which can result in auto-immunity
Main genetic factor
HLA
different MHC molecules: bad ones bind better self-peptides
can be class I or class II
DQ6 HLA allele less susceptible for T1D
HLA & T1D
position 57 of the DQß chain affects susceptiblity to type 1 diabetes mellitus
Asp57 & salt bridge with arginine —> impair self-peptide presentation
Alanine 57: non-polar AA, no salt bridge—> self-peptide presentation possible
AA differences in the MHC groove after self-peptide presentation
molecular mimicry
environmental factor
RIP-OVA (Rat insulin promotor) & OVA expressing virus infection
mice produce OVA in pnacreas—> develop T1D when infected with virus recombinant for OVA
pathogen triggers immune response & if pathogenic antigen similar to a self-antigen
pathogen specific T-cells & Abs produced that may be cross-reactive with self-antigen —> MS & EBV best known examples
molecular mimicry for T-cells & B-cells between EBNA1 & myelin
Last changed10 months ago