Structural basis for the binding of an anti-cytochrome c antibody to its antigen: crystal structures of FabE8-cytochrome c complex to 1.8 A resolution and FabE8 to 2.26 A resolution.

A complete understanding of antibody-antigen association and specificity requires the stereochemical description of both antigen and antibody before and upon complex formation. The structural mechanism involved in the binding of the IgG1 monoclonal antibody E8 to its highly charged protein antigen horse cytochrome c (cyt c) is revealed by crystallographic structures of the antigen-binding fragment (Fab) of E8 bound to cyt c (FabE8-cytc), determined to 1.8 A resolution, and of uncomplexed Fab E8 (FabE8), determined to 2.26 A resolution. E8 antibody binds to three major discontiguous segments (33 to 39; 56 to 66; 96 to 104), and two minor sites on cyt c opposite to the exposed haem edge. Crystallographic definition of the E8 epitope complements and extends biochemical mapping and two-dimensional nuclear magnetic resonance with hydrogen-deuterium exchange studies. These combined results demonstrate that antibody-induced stabilization of secondary structural elements within the antigen can propagate locally to adjacent residues outside the epitope. Pre-existing shape complementarity at the FabE8-cytc interface is enhanced by 48 bound water molecules, and by local movements of up to 4.2 A for E8 antibody and 8.9 A for cyt c. Glu62, Asn103 and the C-terminal Glu104 of cyt c adjust to fit the pre-formed VL "hill" and VH "valley" shape of the grooved E8 paratope. All six E8 complementarity determining regions (CDRs) contact the antigen, with CDR L1 forming 46% of the total atomic contacts, and CDRs L1 (29%) and H3 (20%) contributing the highest percentage of the total surface area of E8 buried by cyt c (550 A2). The E8 antibody covers 534 A2 of the cyt c surface. The formation of five ion pairs between E8 and flexible cyt c residues Lys60, Glu62 and Glu104 suggests the importance of mobile regions and electrostatic interactions in providing the exquisite specificity needed for recognition of this extremely conserved protein antigen. The highly homologous VL domains of E8 and anti-lysozyme antibody D1. 3 achieve their distinct antigen-binding specificities by expanding the impact of their limited sequence differences through the recruitment of different sets of conserved residues and distinctly different CDR L3 conformations.

Structural basis for the root effect in haemoglobin.

The remarkable ability of root effect haemoglobins to pump oxygen against high O2 gradients results from extreme, acid-induced reductions in O2 affinity and cooperativity. The long-sought mechanism for the root effect, revealed by the 2 angstrom crystal structure of the ligand-bound haemoglobin from Leiostomus xanthurus at pH 7.5, unexpectedly involves modulation of the R-state. Key residues strategically assemble positive-charge clusters across the allosteric beta1 beta2-interface in the R-state. At low pH, protonation of the beta N terminus and His 147(HC3)beta within these clusters is postulated to destabilize the R-state and promote the acid-triggered, allosteric R-->T switch with concomitant O2 release. Surprisingly, a set of residues specific to root effect haemoglobins recruit additional residues, conserved among most haemoglobins, to produce the root effect.

Biochemical implications from the variable gene sequences of an anti-cytochrome c antibody and crystallographic characterization of its antigen-binding fragment in free and antigen-complexed forms.

To study the nature of antibody-antigen interactions, we have determined the variable gene sequences of the anti-cytochrome c immunoglobulin G1 (IgG1) monoclonal antibody E8, and obtained diffraction-quality crystals of the E8 antigen-binding fragment (Fab), both free and bound to its antigen, horse cytochrome c. The FabE8 crystals belong to space group P21 with unit cell dimensions of a = 45.0 A, b = 85.1 A, c = 63.3 A and beta = 105.5 degrees, have one FabE8 molecule per asymmetric unit and diffract to at least 2.1 A resolution. Crystals of the FabE8-cytochrome c complex belong to space group P212121 with unit cell dimensions of a = 84.3 A, b = 73.3 A and c = 94.9 A, accommodate one complex per asymmetric unit and diffract to 2.4 A resolution. In the nucleotide-derived amino acid sequences, the light-chain variable domain (VL) but not the heavy-chain variable domain (VH) of E8 is nearly identical to that of the anti-lysozyme antibody D1.3, differing by only five amino acid residues. Only one of these interacts with lysozyme in the D1.3-lysozyme crystal structure. Six negative and four positive charges in the VH complementarity determining regions of E8 complement four positive and three negative charges in the E8 epitope on cytochrome c. These data suggest that only a subset of the residues in an antibody-protein interface may be critical for binding and that the VH may play a dominant role in antigenic recognition.

Surface interactions of gamma-crystallins in the crystal medium in relation to their association in the eye lens.

A comparative study of intermolecular interactions in crystals of two homologous low molecular weight proteins, gamma-II and gamma-IIIb crystallins, from calf eye lens was carried out. Crystal packings for these proteins are very different: intermolecular contact areas compose about 33% of the total accessible surface area of gamma-II as compared with 13% in gamma-III. Two key residues seem to be mainly responsible for the differences in protein association in the crystal medium. These are Ser 103 and Leu 155 in gamma-II, which are replaced by Met 103 and His 155 in gamma-IIb. A similar substitution of these residues is observed in different gene products of gamma-crystallins from a number of vertebrates. This is consistent with the existence of a genetically controlled mechanism for determining intermolecular association of gamma-crystallins in the native medium of the lens.