T Cell Structure and Signalling Flashcards
T cell development occurs in the BLANK
T cell development occurs in the thymus
T cell differentiation occurs in the BLANK
T cell differentiation occurs in the periphery
What do T cells do?
T cells respond to bacterial, viral or tumour antigens
and mount an immune response to clear the bacteria, virus or tumour from the body.
T cell function in response to pathogens is shaped by antigen, pro-inflammatory cytokines, inhibitory receptors and environmental stimuli (e.g. oxygen, AA, glucose, iron availability).
T cells do not respond to soluble bacteria or viral antigens but are triggered by peptides presented to them by major histocompatibility (MHC)
molecules on the surface of other cells.
T cell differentiation:
Naive -> TCR Activated -> Effector -> Memory
Naive: Metabolically inactive Not proliferating - G0 Negligible protein synthesis No nutrient and AA transport
TCR Activated: Metabolically active G1/S phase of cell cycle Increased protein synthesis Active nutrient and AA transport
Effector: Metabolically active Rapidly proliferating Active nutrient and AA transport High rates of protein synthesis Producing effector molecules
Memory: a small proportion of long lived T cells will persist after encountering a pathogen. These cells can respond very quickly to the same antigen again.
MHCs
Most cells in the body express MHC Class I molecules MHC class II molecules are present on specialised antigen presenting cells (APCs) e.g. Dendritic cells, activated macrophages, activated B cells.
These are loaded with either self or foreign peptides
MHC/self peptide complexes trigger T cell survival
MHC/pathogenic peptides presented on the surface of specialised APCs induce T cell immune responses
TCR structure:
CD4/8 chains (alpha/beta, gamma/delta) CD3 Chains (gamma/delta/epsilon/zeta) ITAM domains (Immune Tyrosine based Activation Motif) Variable region Constant region Cytoplasmic tails Transmembrane Tails
KNOW HOW TO DRAW
T Cell Receptor (TCR):
T cells will not respond to peptide alone, they need peptide presented to them.
The key receptor that controls the responses of T lymphocytes is the T Cell Receptor.
The TCR is a multisubunit complex expressed on the
surface membrane of all T cells
T cells can be subdivided into two major subpopulations
based on the type of T cell receptor they express.
T cells can be subdivided into two major subpopulations
based on the type of T cell receptor they express:
alpha/beta T cell receptor (because it uses an alpha/beta dimer to recognise antigen)
- Expressed by majority of recirculating T cells
in the blood and lymphatic system
- recognise small peptides in complexes with MHC class I or class II molecules
- primarily responsible for antigen-specific
cellular immunity
- The ligand for the alpha/beta TCR is peptide/MHC complexes
gamma/delta T cell receptor (because it uses an gamma/delta dimer to recognise antigen)
- Expressed by majority of T cells lining the gut and in the skin
- not MHC restricted
- involved in specific primary immune responses, particularly in young animals, tumour surveillance, and have been implicated in wound healing.
- γδ TCR ligands can be small bacterial phosphoantigens etc.
T cells in the blood and lymphatics that express alpha/beta TCRs can be subdivided into two major subgroups based on the type of coreceptor for MHC that they express:
CD8 T Cell: - Produce effector molecules including granzymes, tumor necrosis factor and perforin - kill pathogen infected cells and tumor cells. - The CD8 molecule is a coreceptor for MHC class I molecules so these cells are triggered by peptide/MHC class I expressing cells.
CD4 T Cell:
- Secrete cytokines including
interferon gamma
- induce the activation of other immune cells including macrophages.
- The CD4 molecule is a coreceptor
for MHC class II molecules so these cells are triggered by peptide/MHC class II expressing cells
Normal ratio of CD4:CD8 T cells in blood is 2:1
How do T cells recognise a wide range of different antigens?
Each T cell can express a unique antigen receptor
This is because the alpha/beta or gamma/delta subunits, which are the receptor subunits that recognise peptide/MHC complexes, are highly variable proteins.
The other antigen receptor subunits (CD3 gamma/delta/epsilon/zeta) are invariant.
They do not recognise antigen but are needed for signal transduction to transmit signal transduction
Why are alpha/beta/gamma/delta subunits highly variable?
Because the genes that encode these proteins undergo gene rearrangements.
Random rearrangements of the exons is controlled by recombinase genes (Rag1/2).
Occurs during T cell development.
Called VDJ Recombination.
TCRs have no intrinsic catalytic activity
TRUE OR FALSE
TRUE
The TCR has no intrinsic catalytic activity but is coupled via signaling motifs known as ITAMs to cytosolic tyrosine kinases Lck/fyn and ZAP70.
Triggering the TCR activates these
tyrosine kinases.
T cell responses to immune stimulation:
- Change migration pattern and move to site of infection
- Proliferate and clonally expand
- Induce expression of genes for cytokines, cytokine receptors etc
- Upregulate growth and protein synthesis to permit rapid cell
division and cytokine production. - Differentiate into killer cells or different types of helper T cells to
make sure the immune response is appropriate
T cell heterogeneity after activation:
CD4+:
- Regulatory T Cells
- Th1
- Th2
- Th17
- Memory T Cells
CD8+:
- Memory T Cells
- CTLs
How can antigen activated T cells differentiate to make different types of effector cells?
Controlled by signaling pathways induced by cytokines produced by activated T cells or cells of the innate immune system.
The type of cytokine produced depends on the pathogen.
Therefore Type of T effector cell produced is dependent on cytokine signalling which is determined by the pathogen.
