Difference between revisions of "T cell differentiation"
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[[Image:TH1-2.jpg|thumb|right|200px|TH1 and 2 selection is influenced by infection - B. Catchpole, RVC 2008]] | [[Image:TH1-2.jpg|thumb|right|200px|TH1 and 2 selection is influenced by infection - B. Catchpole, RVC 2008]] | ||
==Introduction== | ==Introduction== | ||
− | + | Within the blood and lymphoid organs the majority of [[T_cells#Helper_CD4.2B|CD4+ T cells]] are antigen-naive T cells. Only a small proportion are memory T cells. | |
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− | + | Naive T cells have yet to encounter antigen and can only be activated by antigen that is presented by dendritic cells. After initial antigenic activation, naïve T-cells develop into an intermediate stage cell called the TH<sub>0</sub> cell which can then be activated by any antigen-presenting cell, e.g. Dendritic cells, [[Macrophages|macrophages]] or [[B cells]]. | |
− | Within the blood and lymphoid organs the majority of T cells are antigen-naive T cells | + | |
− | + | The TH<sub>0</sub> cells have the capacity to differentiate into TH<sub>1</sub> and TH<sub>2</sub> cells. The type of cell that develops depends on the antigen presenting cell type. [[Macrophages|Macrophages]] cause the TH<sub>0</sub> cell to develop into a TH<sub>1</sub> cell induced by IL-12 production following macrophage-antigen interaction. B cells cause the TH<sub>0</sub> cell to develop into a TH<sub>2</sub> cell induced by IL-10 production following B cell-antigen interaction. On antigenic stimulation the TH<sub>1</sub> or TH<sub>2</sub> cells become activated, undergo clonal expansion and secrete a range of different cytokines. | |
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For any one cell the cytokine-secreting activation state is short-lived, lasting between 4 - 40 hours. After this time these cells either die or mature into the long-lived memory cells. The proliferation of [[T cells]] continues until the presentation of antigen ceases. | For any one cell the cytokine-secreting activation state is short-lived, lasting between 4 - 40 hours. After this time these cells either die or mature into the long-lived memory cells. The proliferation of [[T cells]] continues until the presentation of antigen ceases. | ||
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**Helminths (SEA, ES 62) | **Helminths (SEA, ES 62) | ||
*Endogenous | *Endogenous | ||
− | **Inflammatory mediators (IL-1/TNF | + | **Inflammatory mediators (IL-1/TNF-a, hsp, FcR) |
**Immune cells (CD40L, CD47, FasL) | **Immune cells (CD40L, CD47, FasL) | ||
[[Image:Maturation of Dendritic Cells.jpg|thumb|right|300px|Maturation of Dendritic Cells - Copyright Prof Dirk Werling DrMedVet PhD MRCVS]] | [[Image:Maturation of Dendritic Cells.jpg|thumb|right|300px|Maturation of Dendritic Cells - Copyright Prof Dirk Werling DrMedVet PhD MRCVS]] | ||
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The Langerhans cells leave the epithelium and travel via the afferent lymph flow. They are now known as '''Veiled Cells'''. Veiled cells enter the paracortical region of the [[Lymph Nodes - Anatomy & Physiology|lymph node]] where they present antigen to the T cells. They are now known as '''Interdigitating Dendritic Cells'''. | The Langerhans cells leave the epithelium and travel via the afferent lymph flow. They are now known as '''Veiled Cells'''. Veiled cells enter the paracortical region of the [[Lymph Nodes - Anatomy & Physiology|lymph node]] where they present antigen to the T cells. They are now known as '''Interdigitating Dendritic Cells'''. | ||
− | == | + | ==TH<sub>1</sub> Cells== |
− | [[Image:TH1-macrophage.jpg|thumb|right|200px| | + | [[Image:TH1-macrophage.jpg|thumb|right|200px|TH-1 cells boost macrophage response - B. Catchpole, RVC 2008]] |
− | + | TH1 cells help macrophages digest bacteria - the organisms are contained in cellular vesicles. | |
− | + | TH<sub>1</sub> cells secrete a range of cytokines, including: | |
− | * '''IL-2''', which induces proliferation of both [[Helper_CD4%2B#Helper_CD4.2B|CD4 | + | * '''IL-2''', which induces proliferation of both [[Helper_CD4%2B#Helper_CD4.2B|CD4+]] and [[Cytotoxic_CD8%2B#Cytotoxic_CD8.2B|CD8+ T-cells]]. This stimulation of T cell proliferation is the main function of the TH<sub>1</sub> cell. |
− | * '''Interferon gamma''' ('''IFNγ''') which activates tissue macrophages and is the principal effector mechanism in the defence against intracellular bacteria and parasites such as Mycobacteria, Brucella, Rickettsia Leishmania, Coccidia, and Babesia. | + | * '''Interferon gamma''' ('''IFNγ''') which activates tissue macrophages and is the principal effector mechanism in the defence against intracellular bacteria and parasites such as Mycobacteria, Brucella, Rickettsia Leishmania, Coccidia, and Babesia. Interferon gamma activates macrophages and stimulates them to produce enzymes triggering intracellular killing mechanisms - specifically: |
#Superoxide dismutase and myeloperoxidase that produce H<sub>2</sub>O<sub>2</sub> and trigger the "superoxide burst". | #Superoxide dismutase and myeloperoxidase that produce H<sub>2</sub>O<sub>2</sub> and trigger the "superoxide burst". | ||
#Nitric oxide synthase which produces nitric oxide. | #Nitric oxide synthase which produces nitric oxide. | ||
− | This is another example of the immune system working through the innate immune response | + | This is another example of the immune system working through the innate immune response - this can act to suppress antibody synthesis. |
− | == | + | ==TH<sub>2</sub> Cells== |
− | [[Image:TH2-Bcell.jpg|thumb|right|200px| | + | [[Image:TH2-Bcell.jpg|thumb|right|200px|TH2 cells incite increased antibody production - B. Catchpole, RVC 2008]] |
− | + | TH2 cells help [[B cells]] produce antibody where the organism in present in tissue fluid. The TH2 population influences B cell activation, proliferation and immunoglobulin production. TH2 T cells also secrete a range of cytokines: | |
#'''IL-4''' which stimulates B cell growth and induces the heavy chain switch from [[Immunoglobulin M|IgM]] to [[Immunoglobulin G|IgG]] , [[Immunoglobulin A|IgA]] and [[Immunoglobulin E|IgE]], as well as proliferation of basophils and mast cells. IL-4 can inhibit some T cell responses. | #'''IL-4''' which stimulates B cell growth and induces the heavy chain switch from [[Immunoglobulin M|IgM]] to [[Immunoglobulin G|IgG]] , [[Immunoglobulin A|IgA]] and [[Immunoglobulin E|IgE]], as well as proliferation of basophils and mast cells. IL-4 can inhibit some T cell responses. | ||
#'''IL-5''' which activates B cells and stimulates a high rate of proliferation. IL-5 also promotes immunoglobulin synthesis and the proliferation and differentiation of eosinophils. | #'''IL-5''' which activates B cells and stimulates a high rate of proliferation. IL-5 also promotes immunoglobulin synthesis and the proliferation and differentiation of eosinophils. | ||
#'''IL-6''' also activates B cells, stimulates a high rate of proliferation and promotes immunoglobulin synthesis. | #'''IL-6''' also activates B cells, stimulates a high rate of proliferation and promotes immunoglobulin synthesis. | ||
− | ==Common Functions of | + | ==Common Functions of Th<sub>1</sub> and TH<sub>2</sub> Cells== |
− | Both | + | Both TH1 and TH2 cells produce IL-3 and granulocyte-macrophage colony stimulating factor ([[Leukopoiesis|GM-CSF]]). These act to activate and induce proliferation of [[Neutrophils|neutrophils]] and [[Macrophages|macrophages]]. [[Neutrophils|Neutrophils]] are the major phagocytic cells in the blood and the principal cells in acute inflammatory lesions whose function is chiefly the body's defence against extracellular bacteria. One of the major biological functions therefore of the activation of either TH subset is '''cytokine-controlled reactive [[Haematopoiesis - Overview|haematopoiesis]]'''. |
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==Cytotoxic T-Cells== | ==Cytotoxic T-Cells== | ||
− | Cytotoxic T cells kill virus infected cells where the organisms are contained in the cell cytoplasm. Viruses are obligate intracellular pathogens that use the host cell machinery for pathogen protein synthesis; viral peptides associate with MHC class I and are expressed on the cell surface. [[T_cells#Cytotoxic_CD8.2B|CD8 | + | Cytotoxic T cells kill virus infected cells where the organisms are contained in the cell cytoplasm. Viruses are obligate intracellular pathogens that use the host cell machinery for pathogen protein synthesis; viral peptides associate with MHC class I and are expressed on the cell surface. [[T_cells#Cytotoxic_CD8.2B|CD8+ cytotoxic T lymphocytes (CTL)]] recognise the antigen-MHC complex. Cytotoxic T-cells secrete a pattern of cytokines similar to that of TH<sub>1</sub> cells: |
− | *IFNγ but not IL-2. The IFN&gamma | + | *IFNγ but not IL-2. The IFN&gamma shifts the balance of the immune response in favour of TH<sub>1</sub> cells and there is therefore an increased level of T-cell proliferation. The initiation of the immune response via CTL leads to the selective proliferation of CTL which enhances the main mechanism of killing virally-infected cells. |
===Killing Mechanism=== | ===Killing Mechanism=== | ||
− | The CTl killing mechanism is initiated by direct CTL-target cell contact. | + | |
− | * The cells involved bind by antigen/[[MHC]] class I-TcR interaction. This | + | * The CTl killing mechanism is initiated by direct CTL-target cell contact. |
− | * Direct cell contact stimulates the release of the granule contents into the area of contact between the two cells. The granules contain two groups of cytotoxic molecules. | + | * The cells involved bind by antigen/[[MHC]] class I-TcR interaction. |
− | + | ** This results in the CTL's intracellular granules becoming localised to the area of contact. | |
− | + | *** These granules contain most of the molecules responsible for cytotoxicity. | |
+ | * Direct cell contact stimulates the release of the granule contents into the area of contact between the two cells. | ||
+ | * The granules contain two groups of cytotoxic molecules. | ||
+ | ** Perforin. | ||
+ | *** Structurally related to the [[Complement|complement]] component, C9. | ||
+ | *** Forms pores in the cell membrane. | ||
+ | ** Granzymes. | ||
+ | *** Proteolytic enzymes. | ||
+ | *** Target cell nucleases. | ||
+ | *** Cause programmed cell death. | ||
==T-Cell Activation== | ==T-Cell Activation== | ||
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− | === | + | * [[Lymphocytes#T cells|T cells]] function only after recent activation by antigen. |
− | + | * CD4 binds [[Major Histocompatability Complexes#MHC II|MHC class II]]. | |
− | + | ** [[Lymphocytes#Helper CD4+|CD4+ T-cells]] therefore recognise antigen only in association with [[Major Histocompatability Complexes#MHC II|MHC class II]] | |
− | + | * CD8 binds [[Major Histocompatability Complexes#MHC I|MHC class I]]. | |
− | + | ** [[Lymphocytes#Cytotoxic CD8+|CD8+ T-cells]] recognise antigen only in association with [[Major Histocompatability Complexes#MHC I|MHC class I]]. | |
− | + | * Activation of [[Lymphocytes#T cells|T cells]] requires two distinct signals. | |
− | + | ** '''Signal 1''' | |
− | + | *** The interaction of the TcR with the antigenic peptide/[[Major Histocompatability Complexes|MHC]] complex on the antigen presenting cell. | |
+ | ** '''Signal 2''' | ||
+ | *** The interaction of CD28 on the [[Lymphocytes#T cells|T cells]] with its ligand, CD80, on the antigen-presenting cell. | ||
+ | **** APC expression of CD80 only occurs after: | ||
+ | ***** The engagement of pattern recognition or Fc receptors. | ||
+ | ***** Activation with cytokines. | ||
+ | ****** Interferons, IL-1β or TNFα. | ||
+ | **** Therefore '''signal 2 only occurs after the recognition of <font color=red>danger</font>'''. | ||
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+ | ===Scenarios=== | ||
+ | |||
+ | * '''No signal 1''' | ||
+ | ** [[T cells|T cells]] is not activated as there is no antigen. | ||
+ | * '''Both signal 1 and signal 2''' | ||
+ | ** [[T cells|T cells]] is activated into clonal expansion. | ||
+ | *** Produces cytokines or becomes cytotoxic. | ||
+ | ** This is the response to a dangerous antigen. | ||
+ | * '''Signal 1 but no signal 2''' | ||
+ | ** T-cell is triggered into apoptosis and dies. | ||
+ | ** This is the basis of "clonal deletion". | ||
+ | *** A major mechanism of tolerance. | ||
+ | *** Ensures that T-cells do not react with self (non-dangerous) antigens. | ||
===TCR Complex=== | ===TCR Complex=== | ||
− | [[Image:TCR Complex.jpg|thumb|right| | + | [[Image:TCR Complex.jpg|thumb|right|150px|TCR Complex - Copyright Prof Dirk Werling DrMedVet PhD MRCVS]] |
− | The | + | *The TCR is always associated with CD3 |
+ | **The TCR and CD3 molecule is referred to as the '''TCR complex''' | ||
+ | *TCR is expressed on the surface of T cells in noncovalent association with a complex of transmembrane polypeptides | ||
+ | *CD3 contains 3 distinct polypeptide chains: | ||
+ | **γ, ε, and δ | ||
+ | **Members of the Ig superfamily | ||
+ | **The ε chain associates with both γ and δ | ||
+ | **'''chaperone''' role in transporting newly synthesized TCR molecules to the cell surface | ||
+ | **Expressed exclusively on T cells | ||
+ | *CD3 also contains 2 identical chains: | ||
+ | **ζ | ||
+ | **16 kDa | ||
+ | **Found on T cells, macrophages and NK cells | ||
+ | **Mice also can have an ε (eta) form | ||
− | + | ===Response to Activation=== | |
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− | + | * The response of the [[Lymphocytes#T cells|T cells]] to obtaining Signals 1 and 2 is: | |
− | The response of the T cells to obtaining Signals 1 and 2 is | + | ** To express the receptor for the cytokine interleukin-2 (IL-2). |
− | The final trigger for clonal expansion is the engagement of IL-2R with IL-2 from any activated CD4 | + | ** In [[Lymphocytes#Helper CD4+|CD4+ T-cells]] only, the secretion of IL-2. |
+ | * The final trigger for clonal expansion is the engagement of IL-2R with IL-2. | ||
+ | ** The IL-2 can come from any activated CD4+ T-cell. | ||
+ | ** IL-2 produced by a CD4+ cell may also stimulate clonal expansion of that cell. | ||
==T-Helper Cell Function== | ==T-Helper Cell Function== | ||
− | [[Image:TH1-2.jpg|thumb|right| | + | [[Image:TH1-2.jpg|thumb|right|150px|TH1 and 2 selection is influenced by infection - B. Catchpole, RVC 2008]] |
− | The function of T helper cells is to regulate the immune response. The cytokines they secrete exert their influence on other cell populations | + | * The function of T helper cells is to regulate the immune response. |
− | + | ** The cytokines they secrete exert their influence on other cell populations. | |
− | TH cells secrete cytokines for only a short period after they have been activated | + | *** Most of the different effector cells of the immune system are affected by one or more of the cytokines secreted by TH cells. |
− | + | * TH cells secrete cytokines for only a short period after they have been activated. | |
− | + | * The range of cytokines that TH cells secrete after activation chiefly determines their function. | |
− | + | ** Different T-helper cell subpopulations secrete different sets of cytokines. | |
− | + | *** Th<sub>1</sub> and TH<sub>2</sub> cells. | |
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[[Category:Lymphocytes|E]] | [[Category:Lymphocytes|E]] | ||
[[Category:Adaptive Immune System|C]] | [[Category:Adaptive Immune System|C]] |
Revision as of 19:59, 25 September 2010
Introduction
Within the blood and lymphoid organs the majority of CD4+ T cells are antigen-naive T cells. Only a small proportion are memory T cells.
Naive T cells have yet to encounter antigen and can only be activated by antigen that is presented by dendritic cells. After initial antigenic activation, naïve T-cells develop into an intermediate stage cell called the TH0 cell which can then be activated by any antigen-presenting cell, e.g. Dendritic cells, macrophages or B cells.
The TH0 cells have the capacity to differentiate into TH1 and TH2 cells. The type of cell that develops depends on the antigen presenting cell type. Macrophages cause the TH0 cell to develop into a TH1 cell induced by IL-12 production following macrophage-antigen interaction. B cells cause the TH0 cell to develop into a TH2 cell induced by IL-10 production following B cell-antigen interaction. On antigenic stimulation the TH1 or TH2 cells become activated, undergo clonal expansion and secrete a range of different cytokines.
For any one cell the cytokine-secreting activation state is short-lived, lasting between 4 - 40 hours. After this time these cells either die or mature into the long-lived memory cells. The proliferation of T cells continues until the presentation of antigen ceases.
Dendritic Cells
There are two different lineages of dendritic cells:
- From myeloid precursor cells
- From plasmacytoid precursor cells
Dendritic cells stimulate a primary T cell response; they migrate through tissues, track to T cell dependent areas of the lymph nodes and cluster with the T cells. Dendritic cells have unique capabilities to take up antigen by pathways involving phagocytosis, macropinocytosis and clathrin-coated pits. The cell-surface antigen phenotype distinguishes the dendritic cell from Monocytes/macrophages and B cells. Their main function is priming T helper cells. They produce cell signaling cytokine molecules known as chemokines.
Maturation signals
- Exogenous
- Bacteria or their products (LPS, LTA, lipoproteins)
- Viruses or their products (dsRNA, G-RSV)
- Protozoa or their products
- Helminths (SEA, ES 62)
- Endogenous
- Inflammatory mediators (IL-1/TNF-a, hsp, FcR)
- Immune cells (CD40L, CD47, FasL)
Antigen Presentation
Circulating monocytes differentiate to form immature dendritic cells called Langerhans Cells
Langerhans cells sample the tissue fluid by endocytosis:
- Foreign organisms are internalised
- Within the dendritic cells, antigen is digested to peptides
- Some of the peptides formed bind to the cell’s MHC molecules
The Langerhans cells leave the epithelium and travel via the afferent lymph flow. They are now known as Veiled Cells. Veiled cells enter the paracortical region of the lymph node where they present antigen to the T cells. They are now known as Interdigitating Dendritic Cells.
TH1 Cells
TH1 cells help macrophages digest bacteria - the organisms are contained in cellular vesicles.
TH1 cells secrete a range of cytokines, including:
- IL-2, which induces proliferation of both CD4+ and CD8+ T-cells. This stimulation of T cell proliferation is the main function of the TH1 cell.
- Interferon gamma (IFNγ) which activates tissue macrophages and is the principal effector mechanism in the defence against intracellular bacteria and parasites such as Mycobacteria, Brucella, Rickettsia Leishmania, Coccidia, and Babesia. Interferon gamma activates macrophages and stimulates them to produce enzymes triggering intracellular killing mechanisms - specifically:
- Superoxide dismutase and myeloperoxidase that produce H2O2 and trigger the "superoxide burst".
- Nitric oxide synthase which produces nitric oxide.
This is another example of the immune system working through the innate immune response - this can act to suppress antibody synthesis.
TH2 Cells
TH2 cells help B cells produce antibody where the organism in present in tissue fluid. The TH2 population influences B cell activation, proliferation and immunoglobulin production. TH2 T cells also secrete a range of cytokines:
- IL-4 which stimulates B cell growth and induces the heavy chain switch from IgM to IgG , IgA and IgE, as well as proliferation of basophils and mast cells. IL-4 can inhibit some T cell responses.
- IL-5 which activates B cells and stimulates a high rate of proliferation. IL-5 also promotes immunoglobulin synthesis and the proliferation and differentiation of eosinophils.
- IL-6 also activates B cells, stimulates a high rate of proliferation and promotes immunoglobulin synthesis.
Common Functions of Th1 and TH2 Cells
Both TH1 and TH2 cells produce IL-3 and granulocyte-macrophage colony stimulating factor (GM-CSF). These act to activate and induce proliferation of neutrophils and macrophages. Neutrophils are the major phagocytic cells in the blood and the principal cells in acute inflammatory lesions whose function is chiefly the body's defence against extracellular bacteria. One of the major biological functions therefore of the activation of either TH subset is cytokine-controlled reactive haematopoiesis.
Cytotoxic T-Cells
Cytotoxic T cells kill virus infected cells where the organisms are contained in the cell cytoplasm. Viruses are obligate intracellular pathogens that use the host cell machinery for pathogen protein synthesis; viral peptides associate with MHC class I and are expressed on the cell surface. CD8+ cytotoxic T lymphocytes (CTL) recognise the antigen-MHC complex. Cytotoxic T-cells secrete a pattern of cytokines similar to that of TH1 cells:
- IFNγ but not IL-2. The IFN&gamma shifts the balance of the immune response in favour of TH1 cells and there is therefore an increased level of T-cell proliferation. The initiation of the immune response via CTL leads to the selective proliferation of CTL which enhances the main mechanism of killing virally-infected cells.
Killing Mechanism
- The CTl killing mechanism is initiated by direct CTL-target cell contact.
- The cells involved bind by antigen/MHC class I-TcR interaction.
- This results in the CTL's intracellular granules becoming localised to the area of contact.
- These granules contain most of the molecules responsible for cytotoxicity.
- This results in the CTL's intracellular granules becoming localised to the area of contact.
- Direct cell contact stimulates the release of the granule contents into the area of contact between the two cells.
- The granules contain two groups of cytotoxic molecules.
- Perforin.
- Structurally related to the complement component, C9.
- Forms pores in the cell membrane.
- Granzymes.
- Proteolytic enzymes.
- Target cell nucleases.
- Cause programmed cell death.
- Perforin.
T-Cell Activation
- T cells function only after recent activation by antigen.
- CD4 binds MHC class II.
- CD4+ T-cells therefore recognise antigen only in association with MHC class II
- CD8 binds MHC class I.
- CD8+ T-cells recognise antigen only in association with MHC class I.
- Activation of T cells requires two distinct signals.
- Signal 1
- The interaction of the TcR with the antigenic peptide/MHC complex on the antigen presenting cell.
- Signal 2
- The interaction of CD28 on the T cells with its ligand, CD80, on the antigen-presenting cell.
- APC expression of CD80 only occurs after:
- The engagement of pattern recognition or Fc receptors.
- Activation with cytokines.
- Interferons, IL-1β or TNFα.
- Therefore signal 2 only occurs after the recognition of danger.
- APC expression of CD80 only occurs after:
- The interaction of CD28 on the T cells with its ligand, CD80, on the antigen-presenting cell.
- Signal 1
Scenarios
- No signal 1
- T cells is not activated as there is no antigen.
- Both signal 1 and signal 2
- T cells is activated into clonal expansion.
- Produces cytokines or becomes cytotoxic.
- This is the response to a dangerous antigen.
- T cells is activated into clonal expansion.
- Signal 1 but no signal 2
- T-cell is triggered into apoptosis and dies.
- This is the basis of "clonal deletion".
- A major mechanism of tolerance.
- Ensures that T-cells do not react with self (non-dangerous) antigens.
TCR Complex
- The TCR is always associated with CD3
- The TCR and CD3 molecule is referred to as the TCR complex
- TCR is expressed on the surface of T cells in noncovalent association with a complex of transmembrane polypeptides
- CD3 contains 3 distinct polypeptide chains:
- γ, ε, and δ
- Members of the Ig superfamily
- The ε chain associates with both γ and δ
- chaperone role in transporting newly synthesized TCR molecules to the cell surface
- Expressed exclusively on T cells
- CD3 also contains 2 identical chains:
- ζ
- 16 kDa
- Found on T cells, macrophages and NK cells
- Mice also can have an ε (eta) form
Response to Activation
- The response of the T cells to obtaining Signals 1 and 2 is:
- To express the receptor for the cytokine interleukin-2 (IL-2).
- In CD4+ T-cells only, the secretion of IL-2.
- The final trigger for clonal expansion is the engagement of IL-2R with IL-2.
- The IL-2 can come from any activated CD4+ T-cell.
- IL-2 produced by a CD4+ cell may also stimulate clonal expansion of that cell.
T-Helper Cell Function
- The function of T helper cells is to regulate the immune response.
- The cytokines they secrete exert their influence on other cell populations.
- Most of the different effector cells of the immune system are affected by one or more of the cytokines secreted by TH cells.
- The cytokines they secrete exert their influence on other cell populations.
- TH cells secrete cytokines for only a short period after they have been activated.
- The range of cytokines that TH cells secrete after activation chiefly determines their function.
- Different T-helper cell subpopulations secrete different sets of cytokines.
- Th1 and TH2 cells.
- Different T-helper cell subpopulations secrete different sets of cytokines.