1. Topic 5
Antigen Processing
©Dr. Colin R.A. Hewitt

2. What you should know by the end of this lecture
That T and B cells recognise antigen differently
The experimental evidence that antigen catabolism takes place
Antigen processing generates antigenic peptides
That antigen processing can take place in lysosomes
That there is a non-lysosomal mechanism of antigen processing
The mechanism of antigen processing depends upon the compartment in which the pathogen replicates
Antigen processing includes uptake, degradation, complex formation and presentation
The role of invariant chain HLA-DM and CLIP in antigen processing
The role of the proteasome and transporters in antigen processing
How pathogens evade immunity by disrupting antigen processing

3. T cells do not recognise native antigensY B Y B Y B Y B Y B Y B Y B Y B Y B Y Y Y Y Y Y
Cross-linking of surface membrane Ig
Proliferation and antibody production Y T Y T
No proliferation
No cytokine release

4. Antigens must be processed in order to be recognised by T cells
Soluble
native Ag
Cell surface
native Ag
Soluble
peptides
of Ag
Cell surface
peptides
of Ag
Cell surface peptides of Ag presented by cells that express MHC antigens
ANTIGEN
PROCESSING
No T cell
response
No T cell
response
No T cell
response
No T cell
response
T cell
response

5. Early evidence that antigens are catabolisedM M
Macrophages and radiolabelled
Listeria monocytogenes
Rapid binding to cell surface M
Degradation
of bacteria
and release of
Radiolabelled
protein into supernatant and cells M
Internalisation
How is antigen catabolism linked to T cell proliferation?

6. T The interaction of T cells with macrophages
requires antigen catabolism
NO T CELLS
BIND T
Listeria-specific
T cells
Listeria
coated
plastic
NO T CELLS
BIND
NO T CELLS
BIND
T CELLS
BIND
NO T CELLS
BIND
Listeria M M M M
0mins
60mins
T cell do not bind stably to antigen presenting cells unless the antigen is catabolised

7. Only metabolically active cells can process antigen
Listeria-specific
T cells M M M
Fix with
paraformaldehyde
or poison with
sodium azide
Pulse with
Listeria for 60min
& wash cells
Add Listeria
specific T cells
NO T CELLS BIND
Determinants recognised by T cells are generated by catabolic activity that is dependent upon the viability of macrophages
Antigen presenting cells must be viable to PROCESS antigen

8. Antigen presentation does not require metabolically-active cells
Listeria M M M M
Fix with paraformaldehyde
or poison with sodium azide T
Add Listeria
specific T cells M
T CELLS BIND
Antigen presenting cells do not need to be viable to PRESENT antigen

9. Where does antigen processing take place?
Add Listeria
specific T cells
Listeria M M M M
T CELLS BIND
Incubate with CHLOROQUINE M M M M
NO T CELLS BIND
Chloroquine inhibits lysosomal function (a lysosomotrophic drug)
Antigen processing involves the lysosomal system

10. What form of antigen is produced by antigen processing?
Ovalbumin specific T cell line
Native ovalbumin
Digested ovalbumin Ag
APC
T cell
response
Fixed
APC
Fixed
APC
APC
Viable
APC
Viable T T T T
Catabolism reduces antigens to peptides that can be recognised by T cells

11. Summary of exogenous antigen processing
• T cells can not recognise native antigens
• Antigens must be processed for recognition by T cells
• Antigens catabolism occurs inside cells
• Only metabolically active cells can process antigen
• Antigen presentation does not require metabolically-active cells
• Antigen processing involves the lysosomal system
• Catabolism reduces antigens to peptides
• Because extracellular antigens are dealt with by the lysosomal system, lysosomal antigen processing is part of the EXOGENOUS antigen processing pathway

12. Is exogenous antigen processing sufficient?MF
• Macrophages have well- developed lysosomal systems
• Specialised for motility, phagocytosis and the introduction of particles to the lysosomal system
Most cell types do not have lysosomal systems developed as well as macrophages
BUT
Viruses can infect most cell types
A non-lysosomal mechanism to process antigens for presentation to T cells is required

13. Infectious viruses raise CTL that recognise antigens
that are not generated by the exogenous pathway
Infectious influenza
No treatment
CTL assay
Strong T cell response
Kill
CTL
Cloned anti- CTL
Kill
+ Chloroquine
CTL
Lysosome inhibitors do not inhibit the generation of
antigens recognised by most CTL
Most CTL do not recognise lysosomally-derived antigens

14. Inactive viruses raise CTL to antigens that are
generated by the exogenous pathway
Inactivated influenza
No treatment
CTL assay
CTL
Weak T cell response
Kill
Cloned anti- CTL
CTL
+ Chloroquine
No Kill
Lysosomal inhibitors inhibit the generation of antigens from INACTIVE virus
Some CTL can recognise lysosomally-derived antigens

15. Non-lysosomal processing
The antigens of infectious & inactivated viruses are clearly generated by different mechanisms
Infectious viruses use cellular protein synthesis machinery to replicate
Inactivated viruses do not synthesise protein
CTL raised with
infectious virus
CTL
CTL raised with
non-infectious virus
CTL
Untreated
Protein synthesis
inhibitor-treated
Protein synthesis is required for virus infected target cells to express
antigens recognised by CTL

16. Non-lysosomal antigen processing
Inactive virus raises a weak CTL response
The processing of antigens from inactive viruses is sensitive to lysosomotrophic drugs
ANTIGENS FROM INACTIVE VIRUSES ARE PROCESSED VIA THE EXOGENOUS PATHWAY
Infectious virus raises a strong CTL response
The processing of antigens from infectious viruses is NOT sensitive to lysosomotrophic drugs
Most CTL recognise antigens generated via a non-lysosomal pathway
Protein synthesis is required for non-lysosomal antigen processing
ANTIGENS FROM INFECTIOUS VIRUSES ARE PROCESSED VIA THE ENDOGENOUS PATHWAY
Do the two pathways generate the same type of T cell receptor ligand?

17. Endogenous antigen processing also generates peptides
Influenza virus
Nucleoprotein
Peptides of nucleoprotein
CTL
CTL
CTL
Native antigen fails to sensitise for lysis
No protein/antigen
synthesis
Infectious virus
sensitises for lysis
Protein/antigen
synthesis
Synthetic peptide antigens sensitise targets for lysis
No protein/antigen
synthesis but peptides are
pre-formed

18. The site of pathogen replication or mechanism of antigen uptake determines the antigen processing pathway used
EXTRACELLULAR OR
ENDOSOMAL REPLICATION Y Y
Vesicular Compartment
Contiguous with extracellular fluid
Exogenous processing
(Streptococcal, Mycobacterial antigens)
INTRACELLULAR REPLICATION
Cytosolic compartment
Endogenous processing
(Viral antigens)
Distinct mechanisms of antigen generation are used to raise
T cells suited to the elimination of endogenous or exogenous pathogens

19. Antigens generated by endogenous and exogenous antigen processing activate different effector functions Y
EXOGENOUS
PATHOGENS Y
ENDOGENOUS PATHOGENS
Eliminated by:
Antibodies and phagocyte
activation by T helper cells that use antigens generated by
EXOGENOUS PROCESSING
Eliminated by:
Killing of infected cells by CTL that use antigens generated by ENDOGENOUS PROCESSING

20. Stages of endogenous and exogenous
antigen processing
UPTAKE
Access of native antigens and pathogens to intracellular pathways of degradation
DEGRADATION
Limited proteolysis of antigens to peptides
ANTIGEN-MHC COMPLEX FORMATION
Loading of peptides onto MHC molecules
ANTIGEN PRESENTATION
Transport and expression of peptide-MHC complexes on the surface of cells for recognition by T cells

21. Uptake of exogenous antigens
Membrane Ig
receptor mediated
uptake Y Y
Phagocytosis
Complement receptor
mediated phagocytosis Y
Pinocytosis Y
Fc receptor mediated phagocytosis
Uptake mechanisms direct antigen into intracellular vesicles
for exogenous antigen processing

22. Receptor-mediated uptake enhances the
efficiency of the T cell response
Non-receptor
-mediated uptake
Receptor-mediated
antigen uptake
100 50 75 25
% of max.
T cell
response
10-1
10-2
10-3
Antigen gml-1

23. Exogenous pathway Cell surface Protein antigens Uptake In endosome
Increase
in acidity
Protein antigens
In endosome
Endosomes
To lysosomes
Cathepsin B, D and L proteases are activated by the decrease in pH
Proteases produce ~24 amino acid long peptides from antigens
Drugs that raise the pH of endosomes inhibit antigen processing

24. Activation of Cathepsin B at low pH
Loss of the pro-region exposes the catalytic site of the protease
At higher pH cathepsin B exists in a pro-enzyme form
Acidification of the endosome alters the conformation of the proenzyme to allow cleavage of the pro-region
Hence: drugs that alter acidification of the endosomes disturb exogenous antigen processing

25. Exogenous pathway Cell surface Protein antigens Uptake In endosome
Increase
in acidity
Protein antigens
In endosome
Endosomes
To lysosomes
Cathepsin B, D and L proteases are activated by the decrease in pH
Proteases produce ~24 amino acid long peptides from antigens
Drugs that raise the pH of endosomes inhibit antigen processing

26. Flexibility of the peptide binding
site in MHC molecules
MHC molecules possess binding sites that are flexible at an early, intracellular stage of maturation
Floppy
Compact
Although this example shows MHC class I molecules, the flexibility in the peptide binding site of MHC class II molecules also occurs at an early stage of maturation in the endoplasmic reticulum

27. MHC class II maturation and invariant chain
In the endoplasmic reticulum
Invariant chain stabilises MHC class II by non- covalently binding to the immature MHC class II molecule and forming a nonomeric complex
Need to prevent newly synthesised, unfolded self proteins from binding to immature MHC

28. Invariant chain structure
Three extended peptides each bind into the grooves of three MHC class II molecules to form the nonomeric complex

29. Invariant chain CLIP peptide
and b chains of MHC class II molecules
CLIP
A peptide of the invariant chain blocks the MHC molecule binding site.
This peptide is called the CLass II associated Invariant chain Peptide (CLIP)

30. Class II associated invariant chain peptide (CLIP)
Cell surface
Uptake
Endosomes
(inv)3 complexes
directed towards
endosomes by
invariant chain
Cathepsin L degrades Invariant chain
CLIP blocks groove in MHC molecule
MHC Class II
containing vesicles
fuse with antigen

31. Removal of CLIP ?
How can the peptide stably bind to a floppy binding site?
Competition between large number of peptides

32. HLA-DM assists in the removal of CLIP
HLA-DR
HLA-DM: Crystallised without a peptide in the groove
In space filling models the groove is very small

33. HLA-DM HLA-DR Single pocket in “groove” insufficient to accommodate
a peptide
HLA-DR
Multiple pockets
in groove sufficient to
accommodate a peptide

34. HLA-DM catalyses the removal of CLIP
Replaces CLIP with a peptide antigen using a catalytic mechanism (i.e. efficient at sub-stoichiometric levels)
Discovered using mutant cell lines that failed to present antigen
HLA-DO may also play a role in regulating DM
MIIC compartment
Sequence in cytoplasmic tail retains HLA-DM in endosomes
HLA-DM
HLA-DR

35. Surface expression of MHC class II-
peptide complexes
Exported to the cell surface (t1/2 = 50hr)
Sent to lysosomes for degradation
MIIC compartment sorts peptide-MHC complexes for surface expression or
lysosomal degradation

36. Endogenous antigen processing
UPTAKE
Antigens/pathogens already present in cell
DEGRADATION
Antigens synthesised in the cytoplasm undergo limited proteolytic degradation in the cytoplasm
ANTIGEN-MHC COMPLEX FORMATION
Loading of peptide antigens onto MHC class I molecules is different to the loading of MHC class II molecules
PRESENTATION
Transport and expression of antigen-MHC complexes on the surface of cells for recognition by T cells

37. Degradation in the proteasome
Cytoplasmic cellular proteins, including non-self proteins
are degraded continuously by a multicatalytic protease of 28 subunits
The components of the proteasome include MECL-1, LMP2, LMP7
These components are induced by IFN- and replace constitutive components to confer proteolytic properties.
LMP2 & 7 encoded in the MHC
Proteasome cleaves proteins after hydrophobic and basic amino acids and releases peptides into the cytoplasm

38. Crystal Structure Of The 20s Proteasome
From Yeast
View
End on

39. ENDOPLASMIC RETICULUM
Peptide antigens produced in the cytoplasm are physically separated from newly formed MHC class I
ENDOPLASMIC RETICULUM
Newly synthesised
MHC class I molecules
Peptides need
access to the ER in
order to be loaded onto MHC class I molecules
CYTOSOL

40. Transporters associated with antigen processing (TAP1 & 2)
ER membrane
Lumen of ER
Cytosol
ER membrane
Lumen of ER
Cytosol
ATP-binding cassette
(ABC) domain
Hydrophobic
transmembrane
domain
Peptide antigens
from proteasome
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
Transporter has preference for >8 amino acid peptides
with hydrophobic C termini.

41. Discovery of the role of TAP1 & TAP2 in antigen processing
Normal antigen
presenting cell
line with stable
surface MHC
class I expression
Analysis of genes in the MHC of the mutant cell line
showed mutations
in a pair of ABC transporter genes X √
Chemically-induced
mutant antigen
presenting cell line
with unstable (floppy)
MHC class I
expressed intracellularly
Transfection of normal TAP genes into mutant APC restored stable
surface MHC class I
expression
Mutations in TAP genes affect the supply of peptides to the ER
MHC class I stability is dependent upon a supply of peptides

42. Maturation and loading of MHC class I
Endoplasmic reticulum
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
Calnexin binds
to nascent
class I chain
until 2-M binds
B2-M binds and stabilises floppy MHC
Tapasin, calreticulin, TAP 1 & 2 form a complex with the floppy MHC
Cytoplasmic peptides are loaded onto the MHC molecule and the structure becomes compact

43. Fate of MHC class I Exported to the cell surface
Sent to lysosomes for degradation

44. Evasion of immunity by interference with endogenous antigen processing
Endoplasmic reticulum
Sent to lysosomes
for degradation
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
Peptide
TAP-1
TAP-2
HSV protein blocks transport
of viral peptides into ER

45. Evasion of immunity by interference with endogenous antigen processing
Normally exported to the cell surface
Sent to lysosomes for degradation
Adenoviral
protein
retains MHC
class I in the ER

46. Summary T and B cells recognise antigen differently
Antigen must be catabolised before T cells can recognise it
Antigen processing generates antigenic peptides
Exogenous antigen processing takes place in lysosomes
Endogenous processing is non-lysosomal
The mechanism of antigen processing depends upon the compartment in which the pathogen replicates
Endogenous and exogenous antigen processing both involve uptake, degradation, complex formation and presentation
Exogenous antigen processing uses invariant chain and HLA-DM
Endogenous antigen processing uses proteasomes and peptide transporters in antigen processing
Pathogens can evade immunity by disrupting antigen processing