Immunological diversity Gilbert Chu January 2004.
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Transcript of Immunological diversity Gilbert Chu January 2004.
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Immunological diversityGilbert Chu
January 2004
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Discovery of antibody diversity430 BC Thucydides On bubonic plague: ”It was with those who had recovered from disease that the sick and the dying found most
compassion. These knew what it was from experience, and had now no fear themselves; for the same man was never attacked twice - never at least fatally.”
1796 Jenner Noted that cowpox was rarely followed by smallpox
Showed that cowpox innoculum protected from smallpox
Pasteur coined “vaccine” from vacca, cow in Latin
1901 Landsteiner Discovered antibodies against ABO blood antigens
Made antibodies against many organic molecules: specificity and diversity
Discovered antibodies against the red blood cell antigen in paroxysmal cold
hemoglobinuria: autoimmunity
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The antibody molecule
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Mouse immunoglobulin genes
V1-V500 D1-D12 J1-J4
H chain locus (Chr 12)
C C C3 C1
C2b C2a C C
V1-V250 J1-J5 C
V2 J2 C2
chain locus (Chr 6)
chain locus (Chr 16)
C3 C1V1 J3 J1
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Mechanisms for generating antibody diversity
V(D)J recombination
Somatic hypermutation
Class switch recombination
V1-V500 D1-D12 J1-J4 constant regions
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V(D)J recombination
Mechanisms for generating antibody diversity
V1-V500 D1-D12 J1-J4 constant regions
Hozumi and Tonegawa, PNAS 1976
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V(D)J recombination
Mechanisms for generating antibody diversity
V1-V500 D1-D12 J1-J4 constant regions
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V(D)J recombination
Mechanisms for generating antibody diversity
V1-V500 D1-D12 J1-J4 constant regions
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V(D)J recombination
D to J joining
Mechanisms for generating antibody diversity
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V(D)J recombination
D to J joining
Mechanisms for generating antibody diversity
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V(D)J recombination
V to DJ joining
Mechanisms for generating antibody diversity
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V(D)J recombination
Somatic hypermutation
** *
Somatic mutations
Mechanisms for generating antibody diversity
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** *
V(D)J recombination
Somatic hypermutation
Class switch recombination
Class switch
Mechanisms for generating antibody diversity
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V(D)J recombination
Somatic hypermutation
Class switch recombination
** *
Class switch
Mechanisms for generating antibody diversity
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V(D)J recombination
Somatic hypermutation
Class switch recombination
** *
V(D)J recombination and class switch recombination involve double-strand breaks
Mechanisms for generating antibody diversity
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Recombination signal sequence (RSS) direct V(D)J recombination
23
CACAGTG–––––––ACAAAAACC23
GGTTTTTGT–––CACTGTG12
heptamer nonamer nonamer heptamer
12
V J
12/23 : The rule recombination occurs between 12 23 a RSS with a bp spacer and a RSS with a bp spacer
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V(D)J recombination involves DNA cleavage and end-joining
coding join signal join
cleavage
end-joining
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Cleavage is initiated by RAG1/RAG2 (recombination activating genes)
RAG1/RAG2 nick DNA at two RSSs....
then catalyze nucleophilic attack by 3' OH on the opposite strand
5' OH
5' OH
5'
5'
generating hairpin coding ends and blunt signal ends
van Gent, Gellert et al. Cell 1995
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DNA ends are modified by addition and deletion
N-nucleotide addition by terminal deoxynucleotidyl transferase (TdT)
P-nucleotide addition by asymmetric opening of hairpin coding ends
Nucleotide deletion
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Addition at DNA ends
TCAAGT
TCAAGT
N-nucleotide additionaddition at 3' ends by TdT
addition
Germ-line gene Rearranged gene Mechanism
GATCACTAGT
P-nucleotide additionhairpin formation andasymmetric cleavageaddition
TCAAGT
GATCAT
ATAGTTATCA
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Deletion at DNA ends.
Germ-line gene Rearranged gene Mechanism
CAGT
TCAAGT
Nucleotide deletionrandom
deletion
TCAAGT
Nucleotide deletionmicrohomology directed
deletion
TCAAGT
CAGT
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DNA pathways in V(D)J recombination
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Evolution of V(D)J recombination
RAG1 and RAG2 contain no introns and are tightly linked on the same chromosome
RAG1 and RAG2 are conserved back to the evolution of jawed fish
Evolutionary hypothesis: a transposon with RAG1, RAG2, and associated RSSs infected a precursor of jawed fish
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RAG1 and RAG2 do not exist in jawless fish
hagfishlamprey
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Hypothetical RAG transposon
RAG1 RAG2
excision
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Transposon integration
5' 5'
5'
5' 5'
5'
OH OH
Agrawal, Eastman and Schatz Nature 1998
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Origin of the immunoglobulin genes
D JV
ancient receptor gene
V
gene duplication
D×12 J ×4V×500 C
first transposon integration
second transposon integration
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The scid mouse Mouse with severe combined immunodeficiency,
lacking mature B and T cells
Defective in the joining of coding ends Normal in the joining of signal ends
Hypersensitive to ionizing radiation
The scid mouse suggested a link between V(D)J recombination and
the repair of DNA double-strand breaks
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Mutant nonlymphoid cells can be tested for V(D)J recombination
Mutagenesis of Chinese hamster epithelial cells generated several X-ray sensitive cell lines
These cells were co-transfected with RAG1, RAG2, and V(D)J recombination substrates
The cells were then assayed for either coding joint formation or signal joint formation
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V(D)J recombination substrates
stopcatamp catamp
stopcatamp catamp
plasmid for coding joins coding join
signal join
Lieber et al. (1988) Cell 55, 7-16
plasmid for signal joins
Lieber, Gellert et al. Cell 1998
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Mutants in V(D)J recombination and X-ray resistance
impairedX
impairedX
RAG1/RAG2 cleavage at RSS signal sequence
coding sequence
normal group 7 (scid) groups 4, 5, 6
precise precise
modified impairedX
signal joins
coding joins
Taccioli, Alt et al. Science 1993
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Mechanisms for repairing DNA double-strand breaks
Homologous recombination
Non-homologous end-joining
V(D)J recombination mutants are defective in non-homologous end-joining
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Proteins involved in non-homologous end-joining
Protein Enzymatic activity
Ku DNA end-binding
DNA-PKcs DNA-dependent protein kinase
XRCC4/ Ligase 4 DNA ligase
Artemis exonuclease
Rad50/ Mre11/ Nbs1 exo/endonuclease
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Human diseases with defects in non-homologous end-joining
Severe combined immunodeficiency with radiation sensitivity (Artemis)
Ataxia telangiectasia-like disorder (Mre11)
Nijmegan breakage syndrome (NBS1)
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Ku recruits DNA-PKcs to DNA ends
DNA-PKcsKu Ku
DNA-PKcs
DNA-PKcs then brings DNA ends together
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Stoichiometry of the synaptic complex
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Kinase inhibition does not affect synapsis
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DNA-PK is activated cooperatively by DNA(Phosphorylation occurs after synapsis)
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Leuther, Hammarsten, Kornberg, and Chu, EMBO J 1999
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DNA with single-stranded ends activates DNA-PKcs most efficiently
Hammarsten, DeFazio and Chu, J Biol Chem 2000
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DNA ends with single-strand loops fail to activate DNA-PKcs
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DNA ends blocked with streptavidin fail to activate DNA-PKcs
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Model for activation of DNA-PKcs
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Smider, Rathmell, Lieber, and Chu, Science 1994
Non-homologous end-joining
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Hammarsten and Chu, PNAS 1998
Non-homologous end-joining
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Non-homologous end-joining
DeFazio, Stansel, Griffith, and Chu, EMBO J 2002
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Non-homologous end-joining
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Non-homologous end-joining
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A jawed fish (trout)
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Alex’s model for end-joining, 1995
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Questions about end-joining Protein questions
What are the DNA polymerases?
What are the nucleases?
Phosphorylation questions Which proteins are targeted by DNA-PK?
How does phosphorylation regulate these proteins?
How does DNA-PK phosphorylate these proteins before phosphorylating itself?
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Somatic hypermutation (SHM)
SHM targets immunoglobulin genes (but not T cell receptor genes)
SHM requires active transcription
SHM involves DNA single-strand breaks
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Model for somatic hypermutation Activation-induced deaminase (AID)
Expressed only in activated B cells
Converts C to U in single-stranded DNA
Other proteins insert mutations Uracil DNA glycosylase converts U to an apurinic site
AP endonuclease nicks the DNA adjacent to the AP site
Exonuclease removes the AP ribose
An error-prone polymerase fills in the gap
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Model for somatic hypermutation
How is C mutated on both strands with the same frequency?How does SHM target the Ig locus, but not other loci?
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Class switch recombination (CSR) CSR rearranges the constant regions to
generate different antibody isotypes
CSR regions
located 5’ to each CH gene, except for C
consist of repeats of GAGCT and GGGGGT; e.g., switch region is [(GAGCT)nGGGGGT]150
CSR requires active transcription
AID initiates CSR
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CSR occurs via double-strand breaks
CSR requires Ku and DNA-PKcs
CSR junctions show characteristics of non-homologous end-joining Deletions to regions of microhomology
Duplications from DNA polymerase activity
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Model for class switch recombination
How does AID initiate CSR at one locus and SHM at another?(The C-terminus of AID is required for CSR, but not SHM.)
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Summary Diversity is generated by multiple mechanisms
V(D)J recombination
Somatic hypermutation
Class switch recombination
Some components are lymphocyte-specific RAG1/RAG2, TdT, AID
Other components are ubiquitous Double-strand break repair, base excision repair
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