Dendritic cells
bridge between innate and adaptive immunity
professional antigen-presenting cell (most efficient APC)
only APC able to activate naive T-cells
constitutive MHC class II expression
antigen uptake in peripheral sites & antigen presentation
production of dendritic cells
derive from common myeloid progenitor
leave bone marrow and immature circulating in the blood
in peripheral tissue also resident immature DC
activated —>maturation due to extravasation or migration to draining lymph node
DC immunodeficiencies
exists in genetically deficient mice & observed in humans (IRF8 deficiency autosomal recessive)
loss of circulating monocytes & all types of DC
highly susceptible to infections of all kinds —>no adaptive immune response
immature tissue-resident DC
form network of sentinel cells
waits to sense infection
types of dendritic cells
conventional DC = myeloid cells
cDC1: express CD8aa, main subset involved in cross-presentation, TLR3+, produce IL-12 (Th1—>polarization & IFNγ production)
cDC2: express CD4, mostly extracellular antigen presentation bacteria to CD4+ cells, TLR3-, produce IL-23/-6 (Th17)
plasmacytoid DC (non-conventional): TLR9, virus recognition, produce type I IFNs
MHCII & lineage positive cells in the blood
B-cells
monocytes
Langerhans cells
first recognized DC from the skin
express langerin (CD207)
part of cDC2
In vitro generation of DCs
define conditions to generate wanted cell type from blood precursors
monocytes via GM-CSF & IL-4 tp Mo-DC (monocyte-derived DC)
hematopoietic pluripotent stem cell (CD34+) via GM-CSF & TNFa to Langerhans cells
intensively used for infusion in cancer patients after pulse with tumor antigens
Bridging innate and adaptive immunity
DC activation in peripheral tissues
CCR7 induction (receptor recognizing cytokines from the lymph node)
Migration to draining lymph node (in T-cell zone)
Upregulation of MHC and costimulatory molecules (B7)
Stop processing of antigens (want antigen from tissue)
Antigen transfer in secondary lymphoid organs
mature DC enters lymph nodes from infected tissues and transfers antigens to resident DCs
B7-positive DC stimulates naive T-cells
secondary lymphoid organs
lymph node
mucosa-associated lymphoid tissue (MALT)
spleen
classical pathway of the complement system
C1q interacts with pathogen surface or with Abs bound to the surface
after initial binding interaction with
C1r (activates protein cascade, protease)
C1s (activates protein cascade)
C4 (surface-binding protein & opsonin)
C2 (activates protein cascade)
lectin pathway of the complement system
mannose-binding lectin and ficolins recognize and bind carbohydrates on pathogen surface
recruitment of
MASP-2 (protease)
C4
C2
alternative pathway of the complement system
properdin activates cleavage of C3 by factor D&B after binding of carbohydrates on cell surface on pathogen
effect of the complement system
all pathways generate C3 convertase cleaving C3b bound to the microbial surface & releasing C3a
—>C3a & C5a recruit phagocytic cells to the site of infection and promote inflammation
—> Phagocytes with receptors for C3b engulf and destroy the pathogen (opsonins)
—>completion of complement cascade leads to formation of a membrane-attack complex MAC disrupting cell membrane and causes cell lysis (formation of pores)
Complement receptors
for opsonisation: CR1-4 (CR3&4 are integrins)
for inflammation C5a & C3a (chemokine-like function)
follicle DC
FDC
resident DC from SLO in the germinal center
no hematopoietic origin
Regulation of the complement system
soluble factors:
C1 inhibitor displaces C1r/s & MASP-2 inhibiting activation of C1q & MBL
C4-binding protein displaces C2a (cofactor for C4b cleavage of factor I)
membrane-bound factors:
decay accelerating factor displaces Bb and C2a from C3b and C4b respectively
Membrane-cofactor protein
protectin inhibits MAC formation
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