1. B Cells and B Cell Development
© Dr. Colin R.A. Hewitt

2. The discovery of B cell immunity
Bruce Glick, Ohio State University
Studies on the function of the bursa of Fabricius, a lymphoid organ in the cloacal region of the chicken
Bursectomy – no apparent effect
None of the bursectomised chickens made anti-Salmonella antibodies
Bursectomised chickens were later used in experiments to raise antibodies to Salmonella antigens
Bursa was later found to be the organ in which antibody producing cells developed – antibody producing cells were thereafter called B cells
Mammals do not have a bursa of Fabricius

3. Origin of B cells and organ of B cell
maturation
Transfer marked foetal
liver cells
Mature marked
B cells
in periphery
Normal bone marrow
No Mature
B cells
Defective bone marrow
B cell development starts in the foetal liver
After birth, development continues in the bone marrow

4. B cell development in the bone marrow
Regulates construction of an antigen receptor
Ensures each cell has only one specificity B
Checks and disposes of self-reactive B cells B
Exports useful cells to the periphery B
Provides a site for antibody production B
Bone Marrow provides a
MATURATION & DIFFERENTIATION MICROENVIRONMENT
for B cell development

5. Bone Marrow M S E M

7. Scheme of B Cell Development in the Bone Marrow
Immature & mature B
Central Sinus
E n d o os t e u m
Progenitors
Pre-B X
Stromal cells X X
Macrophage

8. Bone marrow stromal cells nurture developing B cells
1. Specific cell-cell contacts between stromal cells and developing B cells
Cell-cell contact
Secreted
Factors - CYTOKINES
2. Secretion of cytokines by stromal cells B
Stromal cell
Types of cytokines and cell-cell contacts needed at each stage of differentiation are different

9. Maturing B cells
Bone marrow stromal cell

10. B B
Stromal cell

11. Stages of B cell development
Stem Cell
Early pro-B cell
Late pro-B cell
Large pre-B cell
Peripheral
Small pre-B cell
Immature B cell
Mature B cell
Each stage of development is defined by rearrangements of IgH chain genes, IgL chain genes, expression of surface Ig, expression of adhesion molecules and cytokine receptors

12. Cytokines and cell-cell contacts at each stage of differentiation are different
Stem
Early pro-B
Kit
Receptor Tyrosine
kinase
Stem cell factor
Cell-bound growth
factor
VLA-4
(Integrin)
Cell adhesion
molecules
VCAM-1
(Ig superfamily)
Stromal cell

13. Cytokines and cell-cell contacts at each stage of differentiation are different
Interleukin-7
receptor
Interleukin-7
Growth factor
Early pro-B
Late pro-B
Pre-B
Stromal cell

14. Stages of differentiation in the bone marrow are
defined by Ig gene rearrangement
Pre-B cell
receptor
expressed
B CELL STAGE
IgH GENE
CONFIGURATION
Stem cell
Early pro-B
Late pro-B
Large pre-B
Germline
DH to JH
VH to DHJH
VHDHJH
Ig light chain gene has not yet rearranged

15. Transiently expressed when VHDHJH CHm is productively rearranged
B cell receptor
CHm
Heavy chain
VHDHJH
Light chain
VLJLCL
VpreB l5
Iga & Igb signal
transduction
molecules
Transiently expressed when VHDHJH CHm is productively rearranged
VpreB/l5 - the surrogate light chain, is required for surface expression
Ligand for the pre-B cell receptor may be galectin 1, heparan sulphate, other pre-BCR or something as yet unknown

16. Ligation of the pre-B cell receptor
1. Suppresses further H chain rearrangement
2. Triggers entry into cell cycle
Large
Pre-B
Unconfirmed ligand of pre-B cell receptor
1. Ensures only one specificty of Ab expressed per cell
Stromal cell
2. Expands only the pre-B cells with in frame VHDHJH joins
ALLELIC EXCLUSION
Expression of a gene on one chromosome prevents expression of the allele on the second chromosome

17. Evidence for allelic exclusion
ALLOTYPE- polymorphism in the C region of Ig – one allotype inherited from each parent
Allotypes can be identified by staining B cell surface Ig with antibodies
a/a
b/b
a/b Y B a Y B b Y B a Y B b
AND Y B a b
Suppression of H chain rearrangement by pre-B cell receptor prevents expression of two specificities of antibody per cell
(Refer back to Dreyer & Bennet hypothesis in Molecular Genetics of Immunoglobulins lecture topic)

18. Allelic exclusion prevents unwanted responses
One Ag receptor per cell
IF there were two Ag receptors per cell Y B Y
Self antigen
expressed by
e.g. brain cells B Y
S. aureus
S. aureus Y
Anti
S. aureus
Antibodies Y
Anti
brain
Abs Y
Anti
S. aureus
Antibodies
Suppression of H chain gene rearrangement
ensures only one specificity of Ab expressed per cell.
Prevents induction of unwanted responses by pathogens

19. Allelic exclusion is needed for efficient clonal selection
Antibody
S. typhi
S. typhi
All daughter cells must express the same Ig specificity
otherwise the efficiency of the response would be compromised
Suppression of H chain gene rearrangement helps prevent the emergence of
new daughter specificities during proliferation after clonal selection

20. Allelic exclusion is needed to prevent holes in the repertoireY B
One specificity of Ag receptor per cell Y B
IF there were two specificities of Ag receptor per cell
Anti-brain Ig
Anti-brain Ig
AND
anti-S. aureus Ig
Exclusion of anti-brain B cells i.e. self tolerance
BUT
anti S.aureus B cells will be excluded leaving a “hole in the repertoire” B
Deletion
Anergy OR Y B
S. aureus

21. Ligation of the pre-B cell receptor
1. Suppresses further H chain rearrangement
2. Triggers entry into cell cycle
Large
Pre-B
Unconfirmed ligand of pre-B cell receptor
1. Ensures only one specificity of Ab expressed per cell
Stromal cell
2. Expands only the pre-B cells with in frame VHDHJH joins

22. Large pre-B cells need in frame VHDHJH joins to mature
Development continues
Pre-B cell receptor can be activated
Human IgG3 Heavy Chain nucleotide sequence
ATGAAACANCTGTGGTTCTTCCTTCTCCTGGTGGCAGCTCCCAGATGGGTCCTGTCCCAGGTGCACCTGCAGGAGTCGGGCCCAGGACTGGGGAAGCCTCCAGAGCTCAAAACCCCACTTGGTGACACAACTCACACATGCCCACGGTGCCCAGAGCCCAAATCTTGTGACACACCTCCCCCGTGCCCACGGTGCCCAGAGCCCAAATCTTGTGACACACCTCCCCCATGCCCACGGTGCCCAGAGCCCAAATCTTGTGACACACCTCCCCCGTGCCCNNNGTGCCCAGCACCTGAACTCTTGGGAGGACCGTCAGTCTTCCTCTTCCCCCCAAAACCCAAGGATACCCTTATGATTTCCCGGACCCCTGAGGTCACGTGCGTGGTGGTGGACGTGAGCCACGAAGACCCNNNNGTCCAGTTCAAGTGGTACGTGGACGGCGTGGAGGTGCATAATGCCAAGACAAAGCTGCGGGAGGAGCAGTACAACAGCACGTTCCGTGTGGTCAGCGTCCTCACCGTCCTGCACCAGGACTGGCTGAACGGCAAGGAGTACAAGTGCAAGGTCTCCAACAAAGCCCTCCCAGCCCCCATCGAGAAAACCATCTCCAAAGCCAAAGGACAGCCCGAGGAGATGACCAAGAACCAAGTCAGCCTGACCTGCCTGGTCAAAGGCTTCTACCCCAGCGACATCGCCGTGGAGTGGGAGAGCAATGGGCAGCCGGAGAACAACTACAACACCACGCCTCCCATGCTGGACTCCGACGGCTCCTTCTTCCTCTACAGCAAGCTCACCGTGGACAAGAGCAGGTGGCAGCAGGGGAACATCTTCTCATGCTCCGTGATGCATGAGGCTCTGCACAACCGCTACACGCAGAAGAGCCTCTCCCTGTCTCCGGGTAAATGA
Translation in frame 1
MKXLWFFLLLVAAPRWVLSQVHLQESGPGLGKPPELKTPLGDTTHTCPRCPEPKSCDTPPPCPRCPEPKSCDTPPPCPRCPEPKSCDTPPPCXXCPAPELLGGPSVFLFPPKPKDTLMISRTPEVTCVVVDVSHEDXXVQFKWYVDGVEVHNAKTKLREEQYNSTFRVVSVLTVLHQDWLNGKEYKCKVSNKALPAPIEKTISKAKGQPEEMTKNQVSLTCLVKGFYPSDIAVEWESNGQPENNYNTTPPMLDSDGSFFLYSKLTVDKSRWQQGNIFSCSVMHEALHNRYTQKSLSLSPGK*
Development
arrests
Translation in frame 2
(no protein) *
Translation in frame 3
ETXVVLPSPGGSSQMGPVPGAPAGVGPRTGEASRAQNPTW*

23. Ligation of the pre-B cell receptor triggers entry into the cell cycle
Large
pre-B
Large
Pre-B
Many large pre-B cells with identical pre-B receptors
Proliferation
Large pre-B Y
Immature
B cell
Light chain expressed
IgM displayed on surface
IgM
Proliferation stops
Pre-receptor not displayed
Small pre-B
Intracellular VDJCH chain
VL-JL rearranges

24. Heavy and light chain rearrangement is potentially wasteful
Large
pre-B
Small V D J C
Germline V C D J D J
DH-JH joining V C D J V
VH-DHJH joining
With two “random” joins to generate a heavy chain
there is a 1:9 chance of a rearrangement of being in frame V J C
Germline V C J V
VL-JL joining
With one “random” join to generate a light chain
there is a 1:3 chance of a rearrangement being of frame
There is, therefore, only a 1:27 chance of an in frame rearrangement
Out of frame rearrangements arrest further B cell maturation

25. B cells have several chances to successfully
rearrange Ig genes
Early Pro B
Late Pro B
Pre B
Immature B
DH-JH
On first
chromosome
VH-DJH
On first
chromosome
k on first
chromosome
YES
YES
YES Y
IgMk B
YES
YES
YES NO NO NO
k on second
chromosome
DH-JH
On second
chromosome
VH-DJH
On second
chromosome NO
YES
l on first
chromosome Y
IgMl B
YES NO B NO NO
l on second
chromosome NO

26. Y B B Acquisition of antigen specificity creates a need
to check for recognition of self antigens Y B B
Small pre-B cell
No antigen receptor at cell surface
Unable to sense Ag environment
!!May be self-reactive!!
Immature B cell
Cell surface Ig expressed
Able to sense Ag environment
Can now be checked for self-reactivity
Physical removal from the repertoire DELETION
Paralysis of function ANERGY
Alteration of specificity RECEPTOR EDITING

27. B cell self tolerance: clonal deletion
Small
pre-B
Small pre-B cell
assembles Ig B
Immature Y
Immature
B cell recognises
MULTIVALENT
self Ag
Clonal deletion by
apoptosis

28. B cell self tolerance: anergy
IgD normal IgM low Y Y
IgM B
Small
pre-B
Small pre-B cell
assembles Ig B
Immature B Y Y
IgD
IgD Y
IgD B
Immature
B cell recognises
soluble self Ag
No cross-linking
Anergic B cell

29. Y Y B B Receptor editing B
A rearrangement encoding a self specific receptor can be replaced V V V C D J V Y B
!!Receptor
recognises
self antigen!!
Arrest development
And reactivate
RAG-1 and RAG-2 B
Apoptosis
or anergy V V V V C D J Y B
Edited receptor now recognises
a different antigen and can be
rechecked for specificity

30. B cell self tolerance: export of self tolerant B cells
IgD and IgM normal
IgM
IgD Y B
Small
pre-B
Small pre-B cell
assembles Ig Y B
Immature Y Y B Y Y Y Y Y
Mature B cell
exported to the
periphery
Immature
B cell doesn’t recognise any
self Ag

31. IgM and IgD simultaneously?
How can B cells express
IgM and IgD simultaneously?
Ca2 Ce
Cg4
Cg2
Ca1
Cg1
Cg3 Cd Cm
Sg3 Cm Cd
Cg3
VDJ
Cg1
Sg1
Ca1 Cm Cd
Cg3
VDJ
Cg3
VDJ
Ca1
Cg3
VDJ
IgG3 produced.
Switch from IgM
VDJ
Ca1
IgA1 produced.
Switch from IgG3
VDJ
Ca1
IgA1 produced.
Switch from IgM
N.B. Remember Molecular Genetics of Immunoglobulins lecture – No Cd switch region
Consider similarities with mechanism allowing secreted and membrane Ig by the same cell

32. Splicing of IgM and IgD RNA
Cg1
Cg3 Cd Cm V D J
Cm1
Cm2
Cm3
Cm4
Cd1
Cd2
Cd3
DNA
pA1
pA2 V D J
Two types of mRNA can be made simultaneously in the cell by differential usage of alternative polyadenylation sites and splicing of the RNA
RNA cleaved and polyadenylated at pA1
AAA V D J Cm
IgM mRNA
Cm1
Cm2
Cm3
Cm4
Cd1
Cd2
Cd3 V D J
AAA
RNA cleaved and polyadenylated at pA2 V D J Cd
IgD mRNA
Cm1
Cm2
Cm3
Cm4
Cd1
Cd2
Cd3
pA1 V D J

33. Summary B cells develop in the foetal liver and adult bone marrow
Stages of B cell differentiation are defined by Ig gene rearrangement
Pre-B cell receptor ligation is essential for B cell development
Allelic exclusion is essential to the clonal nature of immunity
B cells have several opportunities to rearrange their antigen receptors
IgM and IgD can be expressed simultaneously due to differential RNA splicing
So far, mostly about B cells in the bone marrow - what about mature peripheral B cells?

34. What are the external signals that activate B cells?
Although Fab fragments bind to membrane Ig (mIg), no signal is transduced through the B cell membrane
Fab anti-mIg
mIg
Bridging (or ‘Cross-linking’) of different mIg allows the B cell receptor to transduce a weak signal through the B cell membrane
(Fab)2 anti-mIg
Anti-(Fab)2
Extensive cross linking of (Fab)2 bound to mIg using an anti-(Fab)2 antibody enhances the signal through the B cell membrane

35. Ring staining Patching Capping Ig is evenly distributed
around the cell surface
Patching
Ig is aggregated in
uneven ‘clumps’ as
a result of mild
cross-linking of Ig
Capping
Ig is collected at a pole of the cell in a ‘cap’ as a result of extensive cross-linking of Ig

36. Transduction of signals by the B cell receptor
Extracellular antigen
recognition domains
The cytoplasmic domains of the Iga and Igb contain Immunoreceptor Tyrosine -based Activation Motifs (ITAMS) - 2 tyrosine residues separated by 9-12 amino acids - YXX[L/V]X6-9YXX[L/V]
Iga
Igb
Intracytoplasmic signalling domains

37. Phosphorylation by Src kinases
Kinase domain
Unique region
SH3 domain
SH2 domain
Enzyme domain
phosphorylates tyrosines
(to give phosphotyrosine)
Phosphotyrosine
receptor domain
Adaptor protein recruitment domain
ITAM binding domain
Phosphorylation changes the properties of a protein by changing its conformation
Changes in conformation may activate or inhibit a biochemical activity or create a binding site for other proteins
Phosphorylation is rapid, requires no protein synthesis or degradation to change the biochemical activity of a target protein
It is reversible via the action of phosphatases that remove phosphate

38. Regulation of Src kinases
Kinase domain
Unique region
SH3 domain
SH2 domain
Activating tyrosine residue
Inhibitory tyrosine residue
Phosphorylation of ‘Activating Tyrosine’ stimulates kinase activity
Kinase domain
Unique region
SH3 domain
SH2 domain
Phosphorylation of ‘Inhibitory Tyrosine’ inhibits kinase activity
by blocking access to the Activating Tyrosine Residue

39. Regulation of Src kinases by Csk and CD45
Kinase domain
Unique region
SH3 domain
SH2 domain
C terminus
Resting cells: Src kinase is inactivated by a constitutively expressed C -terminal Src kinase - (Csk)
Activated cells: a phosphatase associated with the Leukocyte Common Antigen - CD45, removes the C terminus phosphate allowing the activating tyrosine to be phosphorylated
Kinase domain
Unique region
SH3 domain
SH2 domain
The balance between Csk and CD45 phosphatase activity sets the threshold for initiating receptor signalling

40. P Phosphorylation of ITAMs by Src kinases P P P P ITAM ITAM ITAM ITAM
1. Csk inactived Src interacts with low affinity with the ITAMs of ‘resting’ receptors P
ITAM
ITAM
2. Antigen clusters B cell receptors with CD45 phosphatases.
Src kinases are phosphorylated P
ITAM
ITAM P P
ITAM
3. Src kinases bind to phosphorylated ITAMS and are activated to phosphorylate adjacent ITAMS P
and are activated to phosphorylate ITAMS

41. Syk protein Tyrosine kinases
CD45 phosphatase allows activation of Src family kinases Blk, Fyn & Lyn
Receptor cross-linking activates Src kinases that phosphorylate ITAMs in the Iga and Igb
ITAM P
ITAM
One Syk binds to Iga, one to Igb - each Syk transphosphorylates the other
Syk - 2 x SH2 domains spaced to bind to two phosphotyrosines on an ITAM P P

42. The B cell co-receptor CD21 (C3d receptor) CD19 CD81 (TAPA-1) CD45 Iga
Igb
The B cell co-receptor

43. Co-receptor phosphorylation
C3d opsonised bacterium
C3d binds to CD21, the complement receptor 2 (CR2)
Antigen
recognition
Src family kinases then bind the phosphorylated CD19 P P P
mIg and CD21 are cross-linked by antigen that has activated complement
CD21 is phosphorylated and receptor-associated kinases phosphorylate CD19
Phosphorylated CD19 activates more Src family kinases
Ligation of the co-receptor increases B cell receptor signalling ,000 fold

44. Activation of signals that affect gene transcription
ITAM P
Cell membrane-associated B cell Linker protein - BLNK - contains many Tyrosine residues
BLNK
Activated Syk phosphorylates BLNK P
BLNK binds Tec kinases
Tec
Tec kinases activate
phospholipase C- g (PLC-g)
PLC-g cleaves phosphotidylinositol bisphosphate (PIP2) to yield diacylglycerol (DAG) and inositol trisphosphate (IP3)
Activated Syk phosphorylates
Guanine-nucleotide exchange factors (GEFS) that in turn activate small GTP binding proteins Ras and Rac
Ras and Rac activate the MAP
kinase cascade

45. Transmission of signals from the cell
surface to the nucleus
B cell-specific parts of the signalling cascade are associated with receptors unique to B cells - mIg, CD19 etc.
Subsequent signals that transmit signals to the nucleus are common to many different types of cell.
The ultimate goal is to activate the transcription of genes, the products of which mediate host defence, proliferation, differentiation etc.
Once the B cell-specific parts of the cascade are complete, signalling to
the nucleus continues via three common signalling pathways via:
The mitogen-activated protein kinase (MAP kinase) pathway
Increased in intracellular Ca2+ mediated by IP3
The activation of Protein Kinase C mediated by DAG

46. Simplified scheme linking antigen recognition with transcription of B cell-specific genes
MAP Kinase cascade
Small G-protein-activated MAP kinases found in all multicellular animals - activation of MAP kinases ultimately leads to phosphorylation of transcription factors from the AP-1 family such as Fos and Jun.
Increases in intracellular calcium via IP3
IP3, produced by PLC-g, binds to calcium channels in the ER and releases intracellular stores of Ca++ into the cytosol. Increased intracellular [Ca++] activate a phospatase, calcineurin, which in turn activates the transcription factor NFAT.
Activation of Protein Kinase C family members via DAG
DAG stays associated with the membrane and recruits protein kinase C family members. The PKC, serine/threonine protein kinases, ultimately activate the transcription factor NFkB
The activated transcription factors AP-1, NFAT and NFkB induce B cell proliferation, differentiation and effector mechanisms

47. Differentiation in the peripheryB B Y B Y
Mature peripheral
B cell
B cell recognises
non-self antigen
in periphery
Ig-secreting plasma cell

48. B Plasma cells High Yes No Yes Yes Yes Low No Yes No No No
Mature B cell
Plasma cell
Surface Surface High rate Growth Somatic Isotype
Ig MHC II Ig secretion hypermut’n switch
High Yes No Yes Yes Yes
Low No Yes No No No

49. Summary You should know:
Where B cells come from
What happens to B cells in the bone marrow
How B cell differentiation is linked with Ig gene rearrangement
The B cell developmental ‘check points’ that ensure each cell produces a single specificity of antibody that does not react with self
How B cells transmit information from the shape and charge of an antigen through the cell membrane to allow the expression of genes in the nucleus
What do mature B cells do once activated by an antigen in the periphery?

50. Recirculating B cells normally pass through
lymphoid organs
B cells in
blood
T cell area
B cell area
Efferent
lymph

51. Recirculating B cells are trapped by foreign antigens in lymphoid organs
B cells leave blood & enter lymph node via
high endothelial venules
B cells
proliferate
rapidly
Antigen enters
node in afferent
lymphatic Y
Germinal centre
releases B cells
that differentiate
into plasma cells
GERMINAL CENTRE
Transient structure of
Intense proliferation

52. B cells (stained brown) in the Germinal Centre
P = Paracortex, Mn = Mantle zone SC = Subcapsular zone

53. Follicular Dendritic cells (stained blue)in the Germinal Centre

54. Retention of Antigens on Follicular Dendritic Cells
Radiolabelled antigen localises on the surface of Follicular Dendritic cells and persists there, without internalisation, for very long periods

55. Maturation of Follicular Dendritic cells
Club-shaped tips of developing dendrites
Filiform dendrites
Bead formation on dendrites
Bead formation on dendrites

56. Association of antigen with FDC
Antigen enters the germinal centre
in the form of an immune complex with C3b and antibodies attached
The Immune complexes bind to Fc and complement receptors on the FDC dendrites
Complement receptor 3
Ig Fc receptor
FDC surface
The filiform dendrites of FDC develop beads coated with a thin layer of immune complexes

57. Iccosome formation and release
Iccosomes (black coated particles) bind to and are taken up by B cell
surface immunoglobulin
DC veils
The veils of antigen-bearing dendritic cell surround the beads and the layer of immune complexes is thickened by transfer from the dendritic cell.
These beads are then released and are then called ICCOSOMES

58. Uptake of Iccosomes/Antigen by B cells
Anti- B cell
Iccosomes bearing different antigens B Y
CD40
Surface Ig captures antigen
Cross-linking of antigen receptor activates B cell
Activated B cell expresses CD40

59. B B Fate of Antigens Internalised by B cells
1. Capture by antigen specific Ig maximises uptake of a single antigen B
2. Binding and internalisation via Ig induces expression
of CD40
3. Antigen enters exogenous antigen processing pathway
4. Peptide fragments of antigen are loaded onto MHC molecules intracellularly. MHC/peptide complexes are
expressed at the cell surface

60. Signal 1 antigen & antigen receptor
T cell help to B cells
Signal 2 - T cell help Th Th B Y
1. T cell antigen receptor
2. Co-receptor (CD4)
Signal 1 antigen & antigen receptor
3.CD40 Ligand

61. Y Th B T cell help - Signal 2 Cytokines Signal 2 Cytokines Signal 1
IL-4 IL-5
IL-6 IFN-g
TGF-b
Cytokines
B cells are inherently prone to die by apoptosis
Signal 1 & 2 upregulate Bcl-XL in the B cell and
Bcl-XL prevents apoptosis
Signal 1 & 2 thus allow the B cell to survive
T cells regulate the survival of B cells and thus control the clonal selection of B cells

62. Y T cell help - Signal 2 activates hypermutation Th B
Receipt of signal 2 by the B cell also activates hypermutation in the CDR - encoding parts of the Ig genes
Signal 2, and thus T cells, regulate which B cells are clonally selected.
Low affinity Ig takes up and presents Ag to T cells inefficiently.
Inefficient presentation to T cells does not induce CD40.
With no signal 2 delivered by CD40, low affinity B cells die.
Only B cells with high affinity Ig survive - This is affinity maturation
Clone 1
Clone 2
Clone 3
Clone 4
Clone 5
Clone 6
Clone 7
Clone 8
Clone 9
Clone 10
CDR1
CDR2
CDR3
Day 6
Day 8
Day 12
Day 18
Deleterious mutation
Beneficial mutation
Neutral mutation
Lower affinity - Not clonally selected
Higher affinity - Clonally selected
Identical affinity - No influence on clonal selection

63. Control of Affinity & Affinity Maturation
Five B cell antigen receptors - all specific for , but with different affinities
due to somatic hypermutation of Ig genes in the germinal centre B
Only this cell, that has a high affinity for antigen can express CD40. Only this cell can receive signal 2
Only this cell is rescued from apoptosis i.e. clonally selected
The cells with lower affinity receptors die of apoptosis by neglect

64. Germinal Centre Macrophages (stained brown) Clean Up Apoptotic Cells
GC = Germinal Centre, TBM = Tingible Body Macrophages

65. Y Role of T cell cytokines in T cell help Th B Cytokines Signal 2 PC
IL-4 IL-5
IL-6 IFN-g
TGF-b B B B B PC B B B B B B B B B
Proliferation & Differentiation
IgM IgG3 IgG1 IgG2b IgG2a IgE IgA
IL4 inhibits inhibits induces inhibits induces
IL augments
IFN-g inhibits induces inhibits induces inhibits
TGF-b inhibits inhibits induces induces

66. Regulation of specificity - Cognate recognition
1. T cells can only help the B cells that present antigen to them
2. B cells are best at presenting antigens that they take up most efficiently
3. B cells are most efficient at taking up antigens that their B cell antigen receptors bind to
4. T and B cells help each other to amplify immunity specific for the same antigen
i.e. Regulates the Characteristics of Adaptive Immunity
Sharply focuses specificity - Pathogen specificity
Improves specificity & affinity - Better on 2nd exposure
Is specific antigen dependent - Learnt by experience
Seeds memory in T and B cell pools

67. Synaptic tethering of a B cell (red)
to a T cell (green)

68. T cell (in centre) surrounded by B cells with
cytoskeleton stained green

69. Recirculating B cells are trapped by foreign antigens in lymphoid organs
B cells leave blood & enter lymph node via
high endothelial venules
B cells
Rapidly
proliferate
in follicles
Antigen enters
node in afferent
lymphatic Y
Germinal centre
releases B cells
that differentiate
into plasma cells
GERMINAL CENTRE
Transient structure of
Intense proliferation

70. B cells (90%) and T cells (10%) migrate to form a primary follicle
1. Antigen loaded dendritic cells migrate from subcapsular sinus to paracortical area of the lymph node DC
B cells (90%) and T cells (10%) migrate to form a primary follicle B T
Primary follicle formation T
3. T cells proliferate T
2. T cells migrate through HEV and are trapped by antigen on DC B B
4. B cells migrate through HEV - most pass through the paracortex and primary follicle.
HEV
Some interact with T cells and proliferate to form a primary focus

71. T cell motility in the lymph node

72. Germinal Centre Microanatomy
Primary Follicles become
secondary follicles when germinal centres develop
Germinal Centre Microanatomy
2. B cells (centrocytes) upregulate
surface Ig, stop dividing and
receive costimulatory signals
from T cells and FDC
4. Selected cells leave lymph
node as memory
cells or plasma cells
Dark zone
Light zone T
Follicular dendritic
cells select useful
B cells B
3. Apoptosis of
self-reactive &
unselected cells
1. B cells (centroblasts) downregulate
surface Ig, proliferate, somatically hypermutate their Ig genes.
AFFINITY MATURATION

73. Distinct B cell precursor
Two B cell lineages B
B cell precursor B
Mature B cell
Plasma cell Y PC
IgG B
Distinct B cell precursor ?
B2 B cells
CD5 B Y
B1 B cells ‘Primitive’ B cells found in pleura and peritoneum Y Y Y
IgM - no other isotypes

74. Few non-template encoded (N) regions in the IgM
B-1 B Cells
IgM uses a distinctive & restricted range of V regions
CD5 B Y
IgM
Few non-template encoded (N) regions in the IgM
Recognises repeating epitope Ag such as phospholipid phosphotidyl choline & polysaccharides
NATURAL ANTIBODY
NOT part of adaptive immune response:
No memory induced
Not more efficient on 2nd challenge
Present from birth
Can make Ig without T cell help

75. Comparison of B-1 and B-2 B cell properties
Property B-1 cells B-2 cells
N regions Few Extensive
V region repertoire Restricted Diverse
Location Peritoneum/pleura Everywhere
Renewal Self renewal in situ Bone marrow
Spontaneous Ig production High Low
Isotypes IgM IgM/G/A/D/E
Carbohydrate specificity Yes Rarely
Protein specificity Rarely Yes
Need T cell help No Yes
Somatic hypermutation of Ig No High
Memory development No Yes
Yes Rarely
Rarely Yes
No Yes
Carbohydrate specificity
Protein specificity
Need T cell help
Specificity & requirement for T cell help suggests strikingly different types of antigens are seen by B-1 and B-2 B cells

76. T Independent Antigens (TI-2)
TI-2 Antigen Y
Immature B-2 Cell Y
Mature
B-1
Immature B cells that bind to multivalent self Ag undergo apoptosis
B-2 cell repertoire is purged of cells recognising multivalent antigens during development in the bone marrow Y Y Y Y
IgM
Non-bone marrow derived B-1 cells are directly stimulated by antigens containing multivalent epitopes.
No T cells are necessary
Induces the expression of natural antibodies specific for TI-2 antigens

77. T Independent Antigens (TI-1)
LPS
LPS binding
protein
Bacterial Lipopolysaccharides, (TI-1 antigens), bind to host LPS binding protein in plasma
TLR 4
LPS/LPSBP is captured by CD14
on the B cell surface
CD14
B Cell
Toll - like receptor 4 (TLR4) interacts
with the CD14/LPS/LPSBP complex
Activation of B cell

78. TI-1 antigens are called MITOGENS
T Independent Antigens (TI-1 e.g. LPS)
LPS complexes with CD14, LPSBP & TLR4 B B B B B B Y Y Y Y Y Y
Six different B cells will require 6 different antigens to activate them
At high dose TI-1 antigens (like LPS) will POLYCLONALLY ACTIVATE all of the B cells irrespective fo their specificity.
TI-1 antigens are called MITOGENS Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y

79. T Dependent & Independent Antigens
Induce responses in babies Yes Yes
Induce responses in athymics No Yes Yes
Prime T cells Yes No No
Polyclonally activate B cells No Yes No
Require repeating epitopes No No Yes
T Dependent & Independent Antigens No

80. Y Y Y Y Y Y Why are babies unresponsive to TI-2 antigens? In adults:
Immature B-2 Cell Y
Mature
B-1
Adult immature B cells that bind to multivalent self Ag undergo apoptosis Y Y Y Y
IgM
Adult non-bone marrow derived B-1 cells are directly stimulated by antigens containing multivalent epitopes produce IgM WITHOUT T cell help.

81. Y Why are babies unresponsive to TI-2 antigens? In babies:
All B cells, B-1 & B-2, are immature
TI-2 Antigen
Immature B cells that bind to multivalent self Ag undergo apoptosis Y
Immature B-1 Cell
As with adult B cells, immature B cells that bind multivalent self Ag undergo apoptosis
Hence babies do not respond to TI-2 antigens.
Babies are, therefore susceptible to pathogens with multivalent antigens such as those on pneumococcus

82. T Dependent & Independent Antigens
Induces response in babies Yes Yes No
Induces response in athymia No Yes Yes
Primes T cells Yes No No
Polyclonally activates B cells No Yes No
Requires repeating epitopes No No Yes
TD: Activate B-1 and B-2 B cells
TI-1: Activate B-1 and B-2 B cells
TI-2: Activate only B-1 B cells
Examples
TD: Diptheria toxin, influenza heamagglutinin, Mycobacterium tuberculosis
TI-1: Bacterial lipopolysaccharides, Brucella abortis
TI-2: Pneumococcal polysaccharides, Salmonella polymerised flagellin

83. Immune effector mechanisms against extracellular pathogens & toxins
NEUTRALISATION
Toxin Y ` Y `
Bacterium Y `
Adhesion to
host cells blocked
Prevents
invasion
Toxin release
blocked
Prevents
toxicity Y `
NEUTRALISING ANTIBODIES

84. Effector mechanisms against extracellular pathogens
OPSONISATION
Bacteria in extracellular space Ab +
Fc receptor
binding
Phagocytosis
OPSONISATION

85. Effector mechanisms against extracellular pathogens
COMPLEMENT Activation
Bacteria in plasma
Lysis
Ab &
COMPLEMENT +
Phagocytosis
binding
Complement &
Fc receptor
Opsonisation

86. Summary
B cell tolerance of self is by clonal deletion or anergy of self-reactive cells
Receptor editing increases the efficiency of B cell development
Follicular dendritic cells acquire antigen and transfer it to B cells
T cell help to B cells is via CD40L and cytokines
CD40 expression indirectly leads to Ig affinity maturation
Germinal centre microanatomy & function
There are two lineages of B cells - B1 and B2 B cells
The dependency of B cells upon T cells varies