Crystallization and preliminary X-ray analysis of CTLA-4 (CD152) membrane-external domain.

CTLA-4 (CD152) is involved in T-lymphocyte co-stimulatory pathways modulating both humoral and cellular immune response. The membrane-external domain has been prepared and crystallized. The unit-cell parameters are a = b = 43, c = 143 A with the symmetry of space group P3(1)21 or its enantiomer and the crystals diffract to 2. 7 A resolution at synchrotron beamlines.

Polyproline binding is an essential function of human profilin in yeast.

Structural analysis of human profilin has revealed two tryptophan residues, W3 and W31, which interact with polyproline. The codons for these residues were mutated to encode phenylalanine and the mutant proteins overexpressed in Eschericia coli. The isolated proteins were diminished in their ability to bind polyproline, whereas phosphatidylinositol 4,5-bisphosphate (PIP2) binding remained unchanged. In many strains of Saccharomyces cerevisiae, disruption of the gene encoding profilin, PFY1, is lethal. It was found that expression of the gene for human profilin is capable of suppressing this lethality. The polyproline-binding mutant alleles of the human gene were cloned into various yeast expression vectors. Each of the mutant genes resulted in suppression of the lethality of pfy1Delta. It was observed that the mutant protein expression levels paralleled the growth rates of the strains. The severity of various morphological abnormalities of the strains was also attenuated with increased protein levels, suggesting that profilin polyproline-binding mutations are deleterious to cell growth unless overexpressed. Both tryptophan mutations were combined to give a third mutant allele that was found both unable to bind polyproline and to suppress the lethality of a pfy1 deletion. Immunoprecipitation experiments suggested that the mutants were unaltered in their affinity for actin and PIP2. These data strongly suggest that polyproline binding is an essential function of profilin.

Structural differences among monoclonal antibodies with distinct fine specificities and kinetic properties.

The mAbs HyHEL-8, HyHEL-26 (HH8, and HH26, respectively) recognize epitopes on hen egg-white lysozyme (HEL) highly overlapping with the structurally defined HH10 epitope, while the structurally related XRPC-25 is specific for DNP and does not bind HEL. All four Abs appear to use the same Vk23 germ line gene, and all but HH8 use the same VH36-60 germ line gene. Of the three anti-HEL Abs, the sequences of HH26 variable regions are closest to those encoded by the respective germ line sequences. HH8 utilizes a different member of the VH36-60 gene family. Thus, the same Vk and VH genes, combined with somatically derived sequence differences, are used to recognize the unrelated Ags HEL and DNP. In contrast, different VH36-60 germ line genes are used to bind the same antigen (e.g. HH8 vs HH10 and HH26). While the affinities of HH10, HH8, and HH26 for HEL vary by less than 10-fold, their affinities for mutated Ag vary over several orders of magnitude. Analyses of Fab binding kinetics with natural species variants and site-directed mutants of lysozyme indicate that these cross-reactivity differences reflect the relative sensitivities of both the association and dissociation rates to antigenic mutation: HH8 has relatively mutation-insensitive association and dissociation rates, HH10 has a relatively mutation-sensitive association rate but more variable dissociation rates, and HH26 has variable association and dissociation rates. Only a few amino acid differences among the antibodies produce the observed differences in the robustness of the association and dissociation rates. Our results suggest that association and dissociation rates and mutation sensitivity of these rates may be independently modulated during antibody repertoire development.

Solution structure of human CTLA-4 and delineation of a CD80/CD86 binding site conserved in CD28.

The structure of human CTLA-4 reveals that residues Met 99, Tyr 100 and Tyr 104 of the M99YPPPY104 motif are adjacent to a patch of charged surface residues on the A'GFCC' face of the protein. Mutation of these residues, which are conserved in the CTLA-4/CD28 family, significantly reduces binding to CD80 and/or CD86, implicating this patch as a ligand binding site.

Design of heterotetrameric coiled coils: evidence for increased stabilization by Glu(-)-Lys(+) ion pair interactions.

Electrostatic interactions between charged amino acids often affect heterospecificity in coiled coils as evidenced by the interaction between the oncoproteins, fos and jun. Such interactions have been successfully exploited in the design of heteromeric coiled coils in a number of laboratories. It has been suggested that heterospecificity in these dimeric coiled-coil systems is driven not by specific electrostatic interactions in the heterodimers but rather by electrostatic repulsion acting to destabilize the homodimer state relative to the heterodimer state. We show that it is possible to design ion pair interactions that directly stabilize the heterotetrameric coiled-coil state. Synthetic peptides were used whose sequences are based on the C-terminal tetramerization domain of Lac repressor, as a model system for four-chain coiled coils (Fairman et al., 1995). These Lac-based peptides, containing either glutamic acid (Lac21E) or lysine (Lac21K) at all b and c heptad positions, only weakly self-associate but, when mixed, afford a highly stable heterotetramer. This study represents the first experimental evidence for the importance of the b and c heptad positions to the stability of coiled coils. Finally, pH dependence and NaCl dependence studies show that heterotetramer stability is driven by ion pair interactions between glutamate and lysine; these interactions contribute about 0.6 kcal/mol of stabilizing free energy for each potential glutamate-lysine pair.

Characterization of a new four-chain coiled-coil: influence of chain length on stability.

Limited information is available on inherent stabilities of four-chain-coils. We have developed a model system to study this folding motif using synthetic peptides derived from sequences contained in the tetramerization domain of Lac repressor. These peptides are tetrameric as judged by both gel filtration and sedimentation equilibrium and the tetramers are fully helical as determined by CD. The four-chain coiled-coils are well folded as judged by the cooperativity of thermal unfolding and by the extent of dispersion in aliphatic chemical shifts seen in NMR spectra. In addition, we measured the chain length dependence of this four-chain coiled-coil. To this end, we developed a general procedure for nonlinear curve fitting of denaturation data in oligomeric systems. The dissociation constants for bundles that contain alpha-helical chains 21, 28, and 35 amino acids in length are 3.1 x 10(-12), 6.7 x 10(-23), and 1.0 x 10(-38) M3, respectively. This corresponds to tetramer stabilities (in terms of the peptide monomer concentration) of 180 microM, 51 nM, and 280 fM, respectively. Finally, we discuss the rules governing coiled-coil formation in light of the work presented here.

Identification of the poly-L-proline-binding site on human profilin.

Profilin is a ubiquitous protein that has been implicated in the signaling pathway leading to cytoskeletal rearrangement in cells. An unusual property of profilin is its high binding affinity for poly-L-proline (PLP). This binding property is conserved in the profilins from diverse species with little sequence homology. We have monitored the binding of PLP to profilin by fluorescence and nuclear magnetic resonance spectroscopies. NMR spectroscopy has identified several residues whose amide nitrogen and amide hydrogen chemical shifts are significantly perturbed by binding of PLP. The affected residues are located at various locations throughout profilin's primary structure; however, mapping the location of the affected residues onto the recently determined three-dimensional solution structure of human profilin indicates that the effects of PLP binding are highly localized. Poly-L-proline binds profilin at the hydrophobic interface between profilin's NH2- and COOH-terminal helices and the upper face of its antiparallel beta-sheet. In contrast, residues located on the opposite side of the profilin structure are unaffected. The extent of the potential interaction surface of the PLP-profilin complex suggests that as few as 6 contiguous prolines would be sufficient for binding profilin. Examination of sequence data bases indicates that stretches of prolines of this length and longer occur in numerous regulatory proteins, suggesting that the ability of profilin to bind polyproline may be an important component of its signaling capabilities.

Characterization of the three-dimensional solution structure of human profilin: 1H, 13C, and 15N NMR assignments and global folding pattern.

Human profilin is a 15-kDa protein that plays a major role in the signaling pathway leading to cytoskeletal rearrangement. Essentially complete assignment of the 1H, 13C, and 15N resonances of human profilin have been made by analysis of multidimensional, double- and triple-resonance nuclear magnetic resonance (NMR) experiments. The deviation of the 13C alpha and 13C beta chemical shifts from their respective random coil values were analyzed and correlate well with the secondary structure determined from the NMR data. Twenty structures of human profilin were refined in the program X-PLOR using a total of 1186 experimentally derived conformational restraints. The structures converged to a root mean squared distance deviation of 1.5 A for the backbone atoms. The resultant conformational ensemble indicates that human profilin is an alpha/beta protein comprised of a seven-stranded, antiparallel beta-sheet and three helices. The secondary structure elements for human profilin are quite similar to those found in Acanthamoeba profilin I [Archer, S. J., Vinson, V. K., Pollard, T. D., & Torchia, D. A. (1993), Biochemistry 32, 6680-6687], suggesting that the three-dimensional structure of Acanthamoeba profilin I should be analogous to that determined here for human profilin. The structure determination of human profilin has facilitated the sequence alignment of lower eukaryotic and human profilins and provides a framework upon which the various functionalities of profilin can be explored. At least one element of the actin-binding region of human profilin is an alpha-helix. Two mechanisms by which phosphatidylinositol 4,5-bisphosphate can interfere with actin-binding by human profilin are proposed.

Relaxation study of the backbone dynamics of human profilin by two-dimensional 1H-15N NMR.

The dynamic properties of 111 backbone HN sites in uncomplexed human profilin, a protein of 139 residues, have been characterized by two-dimensional inverse-detected 1H-15N NMR spectroscopy. Heteronuclear (1H)-15N nuclear Overhauser effects and 15N longitudinal and transverse relaxation rates have been analyzed in terms of model-free spectral density functions and exchange contributions to transverse relaxation rates. Relatively high mobilities on the nanosecond time-scale are observed for Asp26 and Ser27, which form part of a loop connecting beta-strands A and B, and for Thr92 through Ala95, which are in a loop connecting beta-strands E and F. Significant exchange contributions, indicative of motions on the microsecond to millisecond time-scale, have been obtained for 30 residues. These include Leu77, Asp80 and Gly81 of a loop between beta-strands D and E, Ser84 and Met85 of beta-strand E, Gly121 of a loop connecting beta-strand G and the C-terminal helix, and Gln138, which is next to the C-terminal residue Tyr139. Some of the regions showing high flexibility in profilin are known to be involved in poly-L-proline binding.

Patterns of antibody specificity during the BALB/c immune response to hen eggwhite lysozyme.

We tested 49 BALB/c antilysozyme mAb from seven intervals during the immune response to lysozyme for patterns of specificity and avidity. We found that the antibody epitopes in composite covered at least 80% of the lysozyme surface, and their patterns of overlap suggest a continuum of potential antibody epitopes. Previously observed regional specificities, which emerged at different times in the immune response, were more discretely defined in late response antibodies, when the majority of mAb could be assigned to one of three functionally nonoverlapping complementation groups. The area covered by each antigenic region may be greater than an individual epitope, and may include multiple epitopes that overlap structurally and functionally to varying degrees. Connectivity between antigenic regions was seen in interactions among early and late stage antibodies, and among secondary stage mAb, but not among tertiary stage mAb from hyperimmunized mice. Patterns of overlap of early and late response antibodies suggest that the organization of antibody specificities change during the progression from primary to secondary to tertiary response. Over the same period in the response, the average relative avidity of IgG1 kappa mAb did not increase, suggesting that "affinity maturation" of serum antibodies reflects an increase in the number and diversity of antibodies, rather than an overall increase in the avidity of individual antibodies.

Experimental analysis by site-directed mutagenesis of somatic mutation effects on affinity and fine specificity in antibodies specific for lysozyme.

To experimentally examine the functional roles of somatically derived structural variation in the lysozyme-binding mAb HyHEL-10, we have introduced three different point mutations and one insertion at two different sites in HyHEL-10 by site-directed mutagenesis and expression of the mutant antibodies. Mutation of Asp----Ala at position 101 of the H chain returns a somatically mutated residue to its germline sequence for HyHEL-10, and reduces affinity for chicken lysozyme by approximately 9000-fold. Lengthening the third H chain hypervariable region by two amino acids reduces affinity by about 2000-fold. Two mutations, Asp----Thr at position 101 in the H chain and Lys----Thr at position 49 in the L chain, model somatic differences found in another structurally related but functionally distinguishable mAb and minimally decrease affinity for chicken lysozyme. The H chain mutation Asp101VVH----Thr has little effect on affinity for other avian lysozymes but does alter relative fine specificity for these lysozymes. The L chain mutation Lys49VK----Thr increases affinity for duck lysozyme by approximately fivefold. Neither of the positions mutated, 101 in the H chain nor 49 in the L chain, nor the residues near the insertion contact lysozyme in the x-ray structure of the HyHEL-10 F(ab)-HEL complex. The results suggest that these mutations, which model observed somatic mutations, produce functional variation by indirect or long-range effects.

Altered immunoglobulin expression and functional silencing of self-reactive B lymphocytes in transgenic mice.

Immunological tolerance has been demonstrated in double-transgenic mice expressing the genes for a neo-self antigen, hen egg lysozyme, and a high affinity anti-lysozyme antibody. The majority of anti-lysozyme B-cells did not undergo clonal deletion, but were no longer able to secrete anti-lysozyme antibody and displayed markedly reduced levels of surface IgM while continuing to express high levels of surface IgD. These findings indicate that self tolerance may result from mechanisms other than clonal deletion, and are consistent with the hypothesis that IgD may have a unique role in B-cell tolerance.

A three-dimensional model of an anti-lysozyme antibody.

The primary amino acid structure of the lysozyme-binding antibody, HyHEL-10, as determined by amino acid and nucleotide sequencing was utilized to construct a scale model of the Fv (variable region domain of immunoglobulin) using energy-minimized torsional angles of the McPC603 Fv as a prototype template. This model was in turn used as a template for generating a computer-built set of co-ordinates, which were subjected to a total of 600 steps of Adopted Basis Newton-Raphson energy minimizations using the program CHARMM. Only minimal shifts of the backbone (root-mean-square 0.76 A) were required to give an energetically stable structure with a favorable van der Waals' energy. Several notable features were evident from both the scale model and the energy-minimized computer model: (1) the shape of the antibody combining region is that of a very shallow concavity approximately 20 A X 25 A; (2) the concavity is acidic and non-hydrophobic and is bordered by hydrophobic segments; (3) the lower portion of the combining site is dominated by a cluster of tyrosine residues over the L3 and H2 areas; (4) a somatic mutation encoded by the J region of the heavy chain (JH) may contribute significantly to the complementarity of heavy chain H3 to the epitope on hen egg white lysozyme. In addition, the space-filling energy-minimized model revealed that residue 49L, a framework residue, was prominently exposed and accessible in the center of the combining-site concavity. The model suggests that variation in length of complementarity-determining regions may function not only to change directly the shape of the antibody combining site, but may also influence indirectly the nature of the antibody surface by changing the accessibility of residues not usually involved in antigen binding.

Antigenic regions defined by monoclonal antibodies correspond to structural domains of avian lysozyme.

The epitopes recognized by six new BALB/c hybridomas specific for the protein antigen hen egg-white lysozyme (HEL) were mapped in detail. Although fine specificities of all the antibodies were distinct, many of the epitopes overlap in complex patterns. The antibodies could be grouped into three complementation groups, one of which also included the previously characterized HyHEL -5 which is specific for Arg68 . Complex interactions were observed among the antibodies, both among and within complementation groups, including nonreciprocal competition and enhanced binding. Two of the complementation groups mapped near the catalytic site in a new antigenic region. The antibodies HyHEL -8 and HyHEL -10 had very similar and over-lapping specificities, and may recognize very closely related epitopes. The results suggest that the epitopes may form a continuous antigenic surface, and that antigenic regions correspond to structural domains defined by the tertiary structure of HEL.

VL-VH expression by monoclonal antibodies recognizing avian lysozyme.

Seven BALB/c hybridoma antibodies directed against the protein antigen, hen egg-white lysozyme c (HEL), were characterized on the basis of their ability to bind lysozymes from 10 species of birds, and their ability to bind HEL competitively. The hybridomas were separable into three complementation groups based upon competitive interactions. The fine specificities of all antibodies were distinct, but two, HyHEL-8 and HyHEL-10, had very similar and overlapping reactivity patterns. To test the hypothesis that VL-VH pairing correlates with binding specificity, the N-terminal amino acid sequences were determined to identify the VL and VH isotopes (subgroups) of the anti-HEL antibodies. HyHEL-8 and -10 shared the VK23 light chain isotype and nearly identical heavy chains in Kabat subgroup I, whereas the heavy and light chain isotypes of all other antibodies differed from HyHEL-8 and -10 and from each other. The heavy and light chain isotypes expressed by HyHEL-8 and -10 are also expressed by XRPC-25, a DNP-binding myeloma protein that does not bind lysozyme. These results are discussed with respect to the contributions of various genetic sources of structural diversity to antibody functional diversity.