1. T-CELL DIFFERENTIATION IN THE PERIPHERY
CD8 TCR
APC
CD8 TCR
APC
CD8 TCR
APC
CD4 TCR
APC
CD4 TCR
APC
CD4 TCR
APC Ag Ag Ag
Memory T-cell
Activated T-cell
Mature naive T-cell
Naive or „resting” T cells… restless migration and recirculation, LN, lymph, blood…for several month, which is their lifespan

2. NO SIGNAL 1. for CD4+ Th activation
PERIPHERAL TOLERANCE
IMMUNE RESPONSES ARE NOT INITIATED IN THE PERIPHERY
Normal tissue cells do not express MHC class II
NO SIGNAL 1. for CD4+ Th activation
Normal tissue cells do not express co-stimulatory molecules and do not produce T cell differentiating cytokines
NO SIGNAL 2. for CD4+ Th activation
Migration of naive T lymphocytes to normal tissues is limited
Antigen presenting cells are not activated in normal tissues
NO SIGNAL 3. for CD4+ Th activation
PERIPHERAL TISSUES TOLERIZE THEMSELVES

3. T-CELL DIFFERENTIATION
Environmental factors and interactions with APCs
initiate distinct differentiation programs in
naive T-cells

4. Arming of effector T cells
Clonal selection and differentiation
APC T
IL-2
How can this cell give help to or kill cells that express low levels of B7 family costimulators?
Activation of NAÏVE T cells by signal 1 and 2 is not sufficient to trigger effector function, but…..
the T cell will be activated to proliferate and differentiate under the control of autocrine IL-2 to an effector T cell.
These T cells are ARMED

5. Effector function or Anergy?
Clonally selected,
proliferating and
differentiated
T cell sees antigen on
a B7 negative epithelial cell
This contrasts the situation with naïve T cells, which are anergised without costimulation
The effector programme
of the T cell is activated
without costimulation
Armed
Effector
T cell
CD28
Co-receptor
TcR
IL-2
Armed
Effector
T cell
Naïve
T cell
Kill
Epithelial
cell
Epithelial
cell
Epithelial
cell

6. IL-12 FAVORS POLARIZATION TO TH1-TYPE
EFFECTOR T-CELLS
Virus, bacteria, protozoa, fungi
DCMΦ
CD8+ cytotoxic T cell
IL-12
NK cell
IL-12
IFNγ
Th0
Th1
IL-12
Th2
IL-2
IFNγ
TNF-β
GM-CSF
IL-3
IL-4
IL-5
IL-10
IL-13

7. IL-10 FAVORS POLARIZATION TO Th2DC
Self tissue, tumor cell
IL-10
Macrophage
Th2
IL-4
IL-5
IL-10
IL-13
Th0
IL-10
Th1
IL-2
IFNγ
TNF-β
TNF-α
GM-CSF
IL-3
TOLERANCE

8. POLARIZATION OF HELPER T LYMPHOCYTES IS DIRECTED BY DENDRITIC CELL-DERIVED AND AUTOCRINE CYTOKINES AND TRANSCRIPTION FACTORS

9. EFFECTOR FUNCTIONS OF TH1 CELLS
Activation Killing Proliferation Feed back Entry to tissue Recruitment

10. Granulomas develop when intracellular pathogens resist elimination
Long term persistance of infectious agent in a separated envitonment
In some circumstances mycobacteria (red) resist the killing effects of macrophage activation (top panel). A characteristic localized inflammatory response called a granuloma develops (second panel). The granuloma consists of a central core of infected macrophages, which can include multinucleated giant cells formed by macrophage fusions, surrounded by large single macrophages often called epithelioid cells. Mycobacteria can persist in the cells of the granuloma. The central core is surrounded by T cells, many of which are CD4 T cells. The photomicrograph (bottom panel) shows a granuloma from the lung.

11. Responses to Mycobacterium leprae are sharply differentiated in tuberculoid and lepromatous leprosy.
The photographs show sections of lesion biopsies stained with hematoxylin and eosin. Infection with M. leprae bacilli, which can be seen in the right-hand photograph as numerous small dark red dots inside macrophages, can lead to two very different forms of the disease. In tuberculoid leprosy (left), growth of the microorganism is well controlled by TH1-like cells that activate infected macrophages. The tuberculoid lesion contains granulomas and is inflamed, but the inflammation is localized and causes only local peripheral nerve damage. In lepromatous leprosy (right), infection is widely disseminated and the bacilli grow uncontrolled in macrophages. In the late stages there is severe damage to connective tissues and to the peripheral nervous system. There are several intermediate stages between these two polar forms.

12. EFFECTOR CD4+ HELPER T LYMPHOCYTES SECRETE DIFFERENT CYTOKINES
IL-4, IL-5, IL-10
Th2
Th0
IFNγ, IL-2, TNF-β/LT
Th1
IFNγ
IL-4
Inflammatory cytokines
CELLULAR IMMUNE RESPONSE
Anti-inflammatory cytokines
HUMORAL IMMUNE RESPONSE

13. SUBSETS OF HELPER T LYMPHOCYTES COLLABORATE WITH DIFFERENT PROFESSIONAL ANTIGEN PRESENTING CELLS
B7 expression  antigen presentation
Germinal center formation
Affinity maturation
Isotype switch
Memory B cell generation
Th2 B
IL - 4
CD40L
CD40
B7 expression  antigen presentation
MHC-II expression  antigen presentation
Mature dendritic cell
Activated macrophage
CD40L
CD40
DCMΦ
Th1
IFNγ

14. EPIGENETIC CHANGES, MEMORY
CD4
TCR
Th1
Intracellular pathogens
Inflammation
Tc activation
IgG1 & IgG3 antibodies
ADCC, opsonisation
Complement activation
EFFECTOR HELPER T-CELLS
TCR
CD4
Th2
Extracellular pathogens
Multicellular parasites
Secretory IgA
IgE, allergy
Naive CD4+ T cell
Th0 blast
TCR
CD4
CD4
Th17
Extracellular pathogen
Inflammation
Autoimmune diseases
Allergy
TCR
CD4 DC
TCR
TCR
CD4
Treg
Th1 inhibition
Maintenance of immunological tolerance
INTERACTION
ACTIVATION
INSTRUCTION
CLONAL EXPANSION
DIFFERENTIATION
EPIGENETIC CHANGES, MEMORY

15. CHARACTERISTICS OF EFFECTOR HELPER T LYMPHOCYTES
Th1
T-bet
CCR1
CCR5
CXCR3
CD45RBlo
IL-12Rα
LAG3
Th17
RORγt
IL-23R
CCR6
TCR+
CD4+
CD28+
CD25+
CD127
IL-7Rα↓
CTLA4
B7 ligand
GITR
CD25
IL-2Rα
Treg
FoxP3
Th2
GATA3
CCR4
CCR3
CXCR4
CD45RBhigh
IL-1R
CD30

16. Th9 IL-9 HOWEVER, THIS IS NOT THE END OF THE STORY… AS OF YET…
CHARACTERISTICS OF EFFECTOR HELPER T LYMPHOCYTES – Th9 CELLS
TCR+
CD4+
CD28+
CD25+
Th9
PU.1 & IRF4
IL-4Rα
IL-2Rγ
Parasitic helminth infections
Chronic allergic inflammation
Asthma
Autoimmune diseases
Th9
Th0
TGF-β
IL-4
Other cytokines that enhance Th9 polarization:
Type I IFNs , IL-1β, IL-6
IL-9
IL-10
CCL17
CCL22

17. Annunziato and Romagnani (2009) Arthritis Research & Therapy 11:257

18. Neurath MF and Finotto S (2011) Cytokine Growth Factor Rev 22:83-89.

19. Th2 functions

20. Th2 cells stimulate the proliferation and differentiation of naive B cells

21. ISOTYPE SWITCH IN ACTIVATED B CELLS IS REGULATED BY HELPER T CELL - DERIVED CYTOKINES
ISOTYPE SWITCH IS INFLUENCED BY
site of antigen entry
tissue microenvironment
nature of professional antigen presenting cells
polarization of helper T lymphocytes

22. REGULATION OF ISOTYPE SWITCH OF B CELLS
IL-2
IL-4
IL-5
IgM
Helper T cell
IL-2
IL-4
IL-5
IL-2
IL-4
IL-6
IFNγ
IgG
B cell
IL-5
TGFβ
IgA
IL-4
IgE
B cell proliferation and differentiation – isotype switch

23. Human Ig classes and subclasses Complement activation
Classical FcR binding
IgM
IgG
IgG
IgG
IgG4 +/- +
IgA
IgE
IgD

24. Cytotoxic T-cells

25. PRIMING OF CD8+ CYTOTOXIC T CELLS

26. PRIMING OF CD8+ CYTOTOXIC T CELLS THROUGH COLLABORATION OF HELPER AND CYTOTOXIC T-CELLS
ACTIVATION
CD4+ Th
CD40L
Dendritic cells with high B7 expression activate CD8+ T cells directly
Dendritic cells activate CD4+ T cells, which in turn enhance the co-stimulatory activity of dendritic cells
Activated CD4+ T cells secrete cytokines (IL-2), which directly acts on activated CD8+ T cell B7
IL-2
CD28
CD8+ Tc

27. KILLING OF INFECTED CELLS BY CTL
Recognition by CTLs induces secretion of cytotoxins to the target cell
As shown in the panels on the left, initial adhesion to a target cell has no effect on the location of the lytic granules (LG) (top panel). Engagement of the T-cell receptor causes the T cell to become polarized: the cortical actin cytoskeleton at the site of contact reorganizes, enabling the microtubule-organizing center (MTOC), the Golgi apparatus (GA), and the lytic granules to align toward the target cell (center panel). Proteins stored in lytic granules are then directed onto the target cell (bottom panel). The photomicrograph in panel a shows an unbound, isolated cytotoxic T cell. The microtubules are stained green and the lytic granules red. Note how the lytic granules are dispersed throughout the T cell. Panel b depicts a cytotoxic T cell bound to a (larger) target cell. The lytic granules are now clustered at the site of cell-cell contact in the bound T cell. The electron micrograph in panel c shows the release of granules from a cytotoxic T cell.

28. PHYSIOLOGICAL AND PATHOLOGIC CELL DEATH
Apoptotic signal
Cell demage

29. APOPTOSIS AND NECROSIS
Healthy cell
Necrotic cell
Apoptotic cell
Late apoptotic cell
HIGHLY REGULATED PROCESS
Induction
Excecution
Mitochondrial function  * Activation of caspases
Electron transport  * Serine protease,calpain, proteasome
Oxidative phosphorylateion  * Redox potential
ATP synthesis  * DNA degradation (endonuclease)

30. MECHANISM OF CELLULAR KILLING BY CD8+ CYTOTOXIC T LYMPHOCYTES
Proteoglycans
H2O, Ca++, ions
Polymerized perforin
Granzyme
APOPTOSIS
CYTOKINE RELEASE
CD8+ T CELL
TARGET CELL

31. TNF AND TNF RECEPTOR FAMILY MEMBERS AND THEIR LIGANDS
Soluble TNF
TNF-α
TNF-β/LTα
TNFRI
TNFRII
RECEPTOR TRIMERIZATION
LTβ
LTα
LTβR
Soluble FasL
FasL
FAS
CD40L
CD30L
CD27L
4-1BBL
Ox40L
CD40
CD30
CD27
4-1BB
Ox40
DEATH DOMAIN

32. MECHANISMS OF FAS RECEPTOR – MEDIATED PROGRAMED CELL DEATH

33. CONSEQUENCE OF T CELL-MEDIATED IMMUNE RESPONSES
Cytotoxic T lymphocytes recognize
virus-infected or tumor cells
Activated cytotoxic T-lymphocytes
kill virus-infected or tumor cells