Antibody
Recognition of Antigen
David Marcey
© 2007
I.
Introduction
II. Recognition of a globular antigen
III. Recognition of a peptide
antigen
IV.
Recognition of a hapten antigen
V. References
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I.
Introduction
Note:
this tutorial assumes knowledge of the basics of immunoglobulin structure
- see An Introduction
to Immunoglobulin Structure.
The staggeringly large repertoire of antibodies with different
antigen-binding specificity is the basis for the immune system's ability
to recognize virtually all foreign antigens. The structural basis
for the repertoire can be found in the variations of VL
and VH structure in different antibodies. These two amino-terminal
domains lie at each tip of the branches of the immunoglobulin. The
VL and VH hypervariable regions (CDR's) project
from the end of their domains, ready for antigen binding. This tutorial
will use three examples of antibody-antigen complexes to illustrate
some structural features of antibody recognition of epitope. First
we'll look at antibody bound to a globular protein antigen. Then we'll
examine the mechanisms of peptide antigen binding. We'll finish by
studying antibody recognition of a small antigenic molecule, a hapten.
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II.
Recognition of a globular antigen
To
the left is a crystal structure (at 2.5 Å resolution) of a Fab
fragment (VLCL-VHCH1)
from an anti-lysozyme antibody complexed with a globular antigen,
hen egg white lysozyme (HEL)
(Fischmann, et al., 1991).
The variable
VL and VH
domains make extensive contacts with
HEL across
a broad, flat surface at the Fab tip.
Viewing
just the
VL and
VH domains
plus HEL,
we can examine these contacts more closely.
Potential hydrogen bonding between
donor-acceptor pairs on 5
VL residues (Tyr32,
Tyr50, Thr53, Phe91, Ser93)
and 3 HEL
residues (Asp18,
Asn19, Gln121)
has been identified .
The VH
domain has 5 residues (Gly53,
Asp54, Asp100, Tyr101, Arg102)
that can form H-bonds with 7 residues in HEL
(Gly22,
Ser24,
Asn27,
Gly117, Asp119, Val120,
Gln121) .
Note
that both antibody main chain and side chain atoms contact both main
and side chain atoms of the HEL
epitope. Water molecules at the antibody-antigen
interface (not shown) also contribute to the complex hydrogen
bonding pattern between the molecules.
There is exquisite
complementarity of the surfaces of the molecules at their interface.
In addition to the hydrogen bonding patterns just discussed, numerous
van der Waals interactions result .
The
antigenic epitope
is noncontiguous, comprising twelve
HEL residues divided
into two stretches (residues 18, 19,
22, 24, 27 and residues 117,
118, 119, 120, 121, 124, 125).
Residues
in all six CDR's (VL
CDR1,
CDR2, CDR3
and
VH
CDR1,
CDR2, CDR3)
of the antibody participate in recognition
of the HEL epitope.
The
reader is encouraged to repeat this section of the tutorial, rotating
the molecules in the left frame by clicking and dragging and changing
the magnification using either of the buttons below. The molecules
(VL
and VH
plus HEL)
can be reset to their starting magnification and orientation.
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III.
Recognition of a peptide antigen
*
*This
composite PDB file was produced by combining 1hil and 1ifh.
Rini
et al. (1992) have compared the structures of a Fab fragment
of a monoclonal antibody to influenza virus hemagglutinin (HA) in
both ligand-bound and unliganded forms . If you are interested in
hemagglutinin structure, see Viral
Antigens: Influenza Hemagglutinin.
At far left
is displayed the 3-D structure (at 2.8 Å
resolution) of
the VL
and VH
portions of the
Fab complexed with the heptapeptide epitope
from HA (liganded). To
the right of this is the structure of VL
and VH
from the same Fab without
bound antigen (unliganded). Examination of the antigen
binding pocket in both structures
reveals that a pronounced conformational change has occurred upon
antigen binding. The pocket is deformed by
antigen, closing
around it.
The
binding pocket deformation is mostly caused by a shift in the orientation
of CDR3 of
VH.
Note In particular the orientation of
Asp99 and
Asn100 in both
structures.
This
structural comparison provides strong evidence in support of an induced
fit model for the mechanism of antibody-antigen recognition. Induced
fit may explain why some antibodies can recognize both intact protein
antigens and small, free peptide epitopes from such proteins, even
though an epitope embedded in a globular protein is presented in a
considerably different environment from that of a free peptide. Also,
an induced fit mechanism may confound some attempts to define the
shape of antibody combining sites based on the structure of unliganded
Fabs.
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IV.
Recognition of a hapten antigen
To
the left is shown a 2.9 Å
resolution structure of the
VL
and VH
portions of an
anti-dinitrophenyl monoclonal antibody Fab bound to its hapten antigen,
DNP (Bruenger, et al., 1991).
In contrast to
the binding of protein and peptide antigens, antibody binding to smaller
hapten molecules usually involves the insertion of the hapten into
a deep crevice or pocket between the CDR loops of the antibody. This
type of binding, reminiscent of the interaction of enzyme with substrate,
holds promise for the production of catalytic antibodies, using haptens
that resemble a transition state of a particular substrate as antigens.
In the
case at hand, the DNP can be observed
to fit into the molecular canyon between VL
and VH.
This crevice is lined with numerous tyrosine
residues .
Two tryptophan
residues, one each from VL
and VH,
sandwich the DNP .
Interestingly, neither of these
trp residues accounts for the specificity of DNP
binding because the germline variable region
genes from which the heavy and light chains of this antibody were
likely to have been derived have been characterized: both encode trp
at the same positions as the
trps under
consideration.
However, a
residue that is different from that predicted from the germline gene
is tyrosine
31 from
VL.
The codon for this residue, presumably generated through gene rearrangement
during B cell differentiation, produces a tyr
that is stacked perpendicularly to the
VL trp
involved in sandwiching DNP.
This tyr
residue of the monoclonal antibody may therefore be instrumental in
forming the DNP-specific
binding site.
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V.
References
Brunger, A.T.,
Leahy, D.J., Hynes, T.R., Fox, R.O. (1991). 2.9 A resolution structure
of an anti-dinitrophenyl-spin-label monoclonal antibody Fab fragment
with bound hapten. J.Mol.Biol. 221: 239-256.
Fischmann, T.O.,
Bentley, G.A., Bhat, T.N., Boulot, G., Mariuzza, R.A., Phillips, S.E.V.,
Tello, D., and R.J. Poljak (1991). Crystallographic Refinement of
the Three-dimensional Structure of the FabD1.3-Lysozyme Complex at
2.5-Å Resolution. J. Biol. Chem. 266: 12915-12920.
Padlan,
E. (1994) Anatomy of the Antibody Molecule. Molecular Immunology
31: 169.
Rini, J.M., Schulze-Gahmen,
U., Wilson, I.A. (1992). Structural evidence for induced fit as a
mechanism for antibody-antigen recognition. Science 255:
959-965.
Schulze-Gahmen, U., Rini,
J.M., Wilson, I.A. (1993). Detailed analysis of the free and bound
conformations of an antibody. X-ray structures of Fab 17/9 and three
different Fab-peptide complexes. J.Mol.Biol. 234:
1098-1118.
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