Increased Immunogenicity of an Anchor-Modified Tumor-Associated Antigen Is Due to the Enhanced Stability of the Peptide/MHC Complex: Implications for Vaccine Design

Proteins and peptides

Protein was produced by the standard technique of refolding bacterially expressed HLA-A2 (truncated at the transmembrane region) and β₂-microglobulin (β₂m) inclusion bodies in the presence of excess peptide (13). Refolded protein was purified via ion-exchange and size-exclusion chromatography. Peptides were synthesized and purified to >95% commercially (SynPep). Extinction coefficients at 280 nM (units of M⁻¹ cm⁻¹) were 93439 for peptide/HLA-A2 complexes with unlabeled peptide and 103200 for complexes with labeled peptide.

X-ray crystallography

Peptide/HLA-A2 crystals were grown from 25 mM MES, pH 6.5, 24% polyethylene glycol 3350 using sitting drop/vapor diffusion. For cryoprotection, crystals were transferred to 30% polyethylene glycol 3350, 20% glycerol. Diffraction data were collected at the Argonne Structural Biology Center using the 19BM beamline. Data reduction was performed with HKL2000 (14). Structures were solved using molecular replacement with MOLREP from CCP4 (15). The search model was Protein Data Bank entry 1B0R (16), using only the coordinates for the H chain and β₂m. Rigid body refinement, TLS refinement, and restrained refinement were performed with Refmac5 (17). Anisotropic and bulk solvent corrections were performed in all steps of refinement. TLS groups were chosen for residues 1–182 and 183–275 of the H chain, 0–99 of β₂m, and 1–9 of the peptides. After TLS refinement, it was possible to unambiguously position the peptides in 2F_o-F_c maps. Waters were added using ARP/wARP (18). Graphical evaluation of the model and fitting to maps was performed using XtalView (19). Procheck (20) and the template structure check in the WHATIF server (21) were used to evaluate the quality of the structure during and after refinement. Structure factors and coordinates have been submitted to the Protein Data Bank (entries 1TVB and 1TVH). Cavity calculations were performed with SURFNET (22).

IFN-γ ELISPOT assays

PBMC from 95 HLA-A*0201⁺ patients at high risk for recurrence of melanoma were collected using apheresis and cryopreserved during their course of immunization with the gp100_209–2M peptide in protocols reviewed and approved by the Institutional Review Board of the National Institutes of Health. All patients signed an Institutional Review Board-approved consent form and had histologically confirmed melanoma. A total of 106 PBMC samples from these patients were assayed for peptide-specific IFN-γ ELISPOT. The PBMC were collected at various times during the course of immunization, but assays of these samples with the native and modified peptides were always done at the same time. Cryopreserved PBMC were thawed and rested in culture medium overnight and then were added to 1 μM peptide-pulsed C1R-A₂ target cells at a 1:1 ratio (10⁵ of each effector and target cells) in triplicates of 96-well ELISPOT plates (precoated with anti-human IFN-γ Abs from BioSource). After a 24-h incubation, the plates were washed, coated with biotinylated anti-IFN-γ Abs (BD Pharmingen), followed by alkaline phosphatase-conjugated avidin incubation. The spots were developed with alkaline phosphatase substrate. Numbers of spots were corrected by subtracting background spots caused by PBMC incubation with C1R-A₂ cells pulsed with an irrelevant control peptide (gp100₂₈₀; YLEPGPVTA). Nonspecific spots were between 0 and 14/10⁵ cells.

Peptide dissociation kinetics

Dissociation kinetics were measured using fluorescence anisotropy with a Beacon 2000 polarization instrument (Invitrogen Life Technologies) as previously described (23). Briefly, 7.5 nM peptide/HLA-A2 loaded with a fluorescently labeled peptide was mixed with 7.5 μM unlabeled peptide, and the decrease in anisotropy was measured as a function of time. Data were fit to single or biphasic functions of the form , where y₀ is the baseline offset, the summation is over the number of phases i (1 or 2), A_i is the amplitude for phase i, k_i is the rate constant for phase i, and t is the time. Data were analyzed using the program Origin (OriginLab). Error analysis was performed using standard error propagation techniques (24). All measurements were performed in 10 mM HEPES, 150 mM NaCl, pH 7.4 or 6.5, as indicated.

The crystal structures of the gp100₂₀₉ and gp100_209–2M peptides bound to HLA-A2 are indistinguishable

The crystal structures of the native gp100₂₀₉ and anchor-modified gp100_209–2M peptides bound to HLA-A2 were determined at 1.8 Å resolution via molecular replacement. Both complexes crystallized in space group P2₁ with two molecules per asymmetric unit (molecules “A” and “B”). For both complexes, unambiguous electron density was observed for the peptides (Fig. 1⇓). Crystallographic data and refinement statistics are provided in Table I⇓.

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FIGURE 1.

Overview of the gp100₂₀₉/HLA-A2 and gp100_209–2M/HLA-A2 crystal structures. A, Orientation of the two molecules observed in the two asymmetric units. Molecule A is blue and molecule B is yellow. This image shows the T2M-modified structure, but the overall structure with the native peptide is identical. B, 2F_o-F_c electron density maps contoured at 1 σ for the peptides from the A molecules. Native peptide is on top, the T2M variant is on the bottom.

In both the native and T2M-modified gp100₂₀₉/HLA-A2 crystal structures, both molecules in the asymmetric unit are nearly identical. There are, however, differences in the positioning of Gln⁴, Phe⁷, and Ser⁸ of the peptide. As shown in Fig. 2⇓, A and B, though, these differences are common to both the native and T2M-modified structures. Comparison of the two sets of peptides thus reveals that the T2M substitution has little, if any, effect on peptide conformation. For the A molecules, all common atoms in the peptides superimpose to a root mean square deviation (RMSD) of 0.20 Å. For the B molecules, the superimposition is 0.21 Å (a detailed comparison of the two structures is provided in Table II⇓). The largest differences in the peptides are the side chains of positions 4, 7, and 8, the same positions which show differences between the A and B molecules (Fig. 3⇓). Thus we cannot attribute the small differences between the native and modified peptides to the T2M substitution, as the differences are in the same positions and are of lower magnitude than the differences observed between the A and B molecules in both structures. The temperature factors for the atoms of these side chains do not differ significantly from the average in either structure. Thus, these differences may reflect different side chain conformations that interconvert on a slow timescale, captured by crystallization, or alternatively, the influence crystal packing has on otherwise mobile side chains. We note that similar differences in exposed side chains are seen elsewhere in the structures, for example Lys¹⁹ in β₂m, a full 42 Å away from the site of the T2M substitution. The side chain differences are thus reminiscent of the kind of differences one observes when comparing different structures of the same protein. For example, when comparing the original structure of the Tax peptide bound to HLA-A2 reported in 1993 (25) with a higher resolution structure reported in 2000 (26), all atoms of the peptides superimpose to an RMSD of 0.21 Å, identical to the values obtained for the superimposition of the gp100₂₀₉ and gp100_209–2M peptides reported in this study (Table II⇓).

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FIGURE 2.

Superimposition of the peptides from the gp100₂₀₉/HLA-A2 and the gp100_209–2M/HLA-A2 crystal structures. The native peptide is blue, the T2M-modified peptide is yellow. A and B, Superimposition of the two A molecules (top) and B molecules (bottom). The P2 side chain is indicated as T/M2. Note the repositioning of Q4, F7, and S8 between the A and B molecules (compare top to bottom), but note also how these differences are the same whether one examines the structure with the native or T2M-modified peptide (compare blue to yellow in both images). C, Cross-eyed stereo image of the fit of the Thr² and Met² side chains in the HLA-A2 P2 pocket. Methionine is blue; the carbons of threonine are gray; and the oxygen is red. The surface of HLA-A2 is gray, except for the carboxylate of Glu⁶³ which is red. Glu⁶³ and Lys⁶⁶ are indicated.

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FIGURE 3.

Interatomic distances between superimposed gp100₂₀₉ and gp100_209–2M peptides. Hatched bars indicate backbone atoms, dark gray indicate side chains. The figure corresponds to the superimpositions in Fig. 2⇑, A and B. Note that the backbone differences are miniscule and without any trends, and that, excluding the site of the substitution, the most significant differences are for atoms in positions 4, 7, and 8, the same positions which show differences between the two molecules in each asymmetric unit. Atoms with distances ≥0.30 Å are labeled.

Comparing the backbones of the gp100₂₀₉ and gp100_209–2M peptides in the two structures, for both the A and B molecules, the backbone of the gp100₂₀₉ peptide superimposes on that of the gp100_209–2M peptide with an RMSD of ∼0.1 Å, near the estimated coordinate error (Table I⇑). Thus, within the limit of the x-ray data, the T2M substitution has no effect on the structure of the peptide in the HLA-A2 binding groove.

Comparison of the HLA-A2 α1 and α2 helices in the two structures indicates that the T2M substitution does not induce changes into the structure of the peptide binding domain. The backbones of these helices superimpose to RMSDs of 0.09 and 0.11 Å, respectively. The side chains of HLA-A2 amino acids that contact TCRs in known TCR/peptide/HLA-A2 structures likewise show no significant differences. For example, the side chains of Lys⁶⁶ and Gln¹⁵⁵, implicated as important positions for most HLA-A2 restricted TCRs (27, 28), are virtually indistinguishable, with equivalent atoms differing by no more than 0.45 Å when the peptide binding grooves are superimposed. As with the peptides, the positions of some side chains differ slightly when comparing the A and B molecules. Again though, as summarized in Table II⇑, these differences tend to be equal to or greater than any differences observed between the structures with the native and modified peptides.

The structure with the native peptide reveals how the polar side chain of Thr² is accommodated in the apolar HLA-A2 P2 pocket, inserting itself into a network of hydrogen bonds strongly conserved in peptide/HLA-A2 structures (7, 16, 25, 26, 29, 30, 31, 32, 33, 34, 35). As shown in Fig. 4⇓, the threonine at position 2 hydrogen bonds with Glu⁶³ of the HLA-A2 H chain. Glu⁶³ also hydrogen bonds with the conserved water molecule near the peptide amino terminus and forms a salt-bridge with Lys⁶⁶. Lys⁶⁶ in turn hydrogen bonds to the carbonyl oxygen of Thr². Substitution of Thr² with methionine removes the hydrogen bond between the side chain and Glu⁶³, but Glu⁶³, Lys⁶⁶, and the position 2 carbonyl oxygen are undisturbed.

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FIGURE 4.

Cavities and hydrogen bonding in and around the P2 pocket in the two peptide/MHC structures. In the structure with the native peptide (A), the hydroxyl group of the Thr² side chain hydrogen bonds with Glu⁶³, a participant in a network of hydrogen bonds strongly conserved in peptide/HLA-A2 structures. B, The hydrogen bond to Glu⁶³ is lost when Thr² is substituted with Met. Numbers indicate hydrogen bond distances. The red sphere is a conserved water whose position is slightly altered in the T2M structure. Two large cavities are present within the P2 pocket when Thr is at position 2 (yellow polygons). The smaller cavity is occupied by the -S-CH₃ moiety of the Met side chain in the modified structure. The larger cavity increases in response to removal of the Thr hydroxyl and repositioning of the γ carbon. This figure was generated using the A molecules, but the conclusions are identical if the B molecules are compared. A conserved hydrogen bond between Glu⁶³ and the amide nitrogen of P2 is not shown for clarity.

As the two structures are so similar, one expectation is that replacement of the smaller threonine with the larger methionine should alter packing in and around the HLA-A2 P2 pocket. In the structure with the native peptide, cavity calculations (22) between the side chain of Thr² and HLA-A2 reveal the presence of cavities in and around the P2 pocket, shown in Fig. 4⇑A. The same calculation on the modified structure confirms that substitution of Thr² with Met reduces total cavity volume. The larger cavity shown in Fig. 4⇑A increases in volume from 15.4 to 25.6 ų in response to removal of the threonine hydroxyl and repositioning of the γ carbon (Fig. 4⇑B). However, the smaller cavity (volume of 14.8 ų) is not present in the modified structure, as this space is occupied by the -S-CH₃ moiety of the methionine side chain. The total reduction in cavity volume upon making the T2M substitution is thus 4.6 ų. The H chain atoms defining the cavities shown in Fig. 4⇑ superimpose to an RMSD of 0.14 Å, indicating that the overall size and shape of the P2 pocket is not altered due to the T2M substitution.

It is informative to compare our findings with other structural studies of native and modified peptides presented by MHC molecules. In studying the Hb peptide presented by the murine class II MHC I-E^k, Kersh et al. (6) found that changing the P6 anchor from glutamic to aspartic acid resulted in a subtle (0.4–0.6 Å) but crystallographically significant shift in the position of the peptide backbone (6). Although the change was maximal at the site of the substitution, the effects propagated from the site of the substitution all the way to the peptide C terminus. No such trends are observed in our data; indeed, the backbone differences tend to be at or below the estimated coordinated error. Sharma et al. (7) obtained similar results with variants of the HER-2/neu peptide bound to HLA-A2: with the leucine at position 9 changed to valine, a significant change in the conformation of the peptide backbone in the center of the peptide was observed (7). Again, no such changes are detected in this study.

Other structural studies have revealed conformational changes in peptide/MHC complexes when the peptides are modified (e.g., Refs. 36 and 37), but our findings of no conformational changes occurring upon modifying the gp100₂₀₉ peptide are not without precedent. With the RT_309–317 peptide bound to HLA-A2, Kirksey et al. (32) found that changing the P1 residue from isoleucine to either phenylalanine or tyrosine did not alter the structure of the peptide/HLA-A2 complex (32), despite large changes in peptide/HLA-A2 stability and immunogenicity. Likewise, with the NY-ESO_157–165 peptide bound to HLA-A2, modifications to P9 did not alter the structure (38). Finally, in a ternary complex between the A6 TCR and the Tax peptide presented by HLA-A2, the conformation of the Tax peptide was found to be identical whether a proline or an alanine was present at position 6, despite the fact that the P6A substitution changes the peptide from a strong agonist to an antagonist (8, 39).

T cells from vaccinated patients are unable to distinguish between the native and T2M-modified peptides

To investigate whether T cells can distinguish between the native and T2M-modified gp100₂₀₉ peptides, 106 PBMC samples from 95 patients at high risk for recurrence of melanoma and who had been vaccinated with the T2M-modified peptide were assayed for peptide-specific IFN-γ release using ELISPOT. As shown in Fig. 5⇓, across this large sample size, the number of cells activated by the native peptide is highly correlated with the number of cells activated by the T2M-modified peptide. The slope of the regression line, 1.1 ± 0.1, indicates that there is little, if any, trend indicating the existence of T cells that can discriminate between the two peptides. The slightly positive value of the slope in favor of the T2M-modified peptide may reflect its improved binding affinity and slower dissociation rate (5, 10).

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FIGURE 5.

The frequency of T cells recognizing the native gp100₂₀₉ peptide mirrors the frequency of those recognizing the T2M-modified peptide. The figure shows results from ELISPOT assays conducted on 106 PBMC from 95 individuals, identifying the number of Ag-specific T cells per 10⁵ cells. The line represents a linear regression through the data, characterized by a slope of 1.1 ± 0.1.

Because ELISPOT only measures the frequencies of Ag-specific T cells, we could not confirm whether a gp100_209–2M-reactive T cell was indeed gp100₂₀₉-reactive. However, if some or all of the T cell subsets tested were capable of specifically recognizing only the T2M peptide, against which these patients were immunized, in Fig. 5⇑ we would expect to see a large number of points “pinned” to the y-axis, with greatly diminished recognition of the native peptide. However, in 106 samples from 95 patients, the majority had nearly identical frequencies of gp100₂₀₉ and gp100_209–2M-specific T cells. This strongly suggests that T cells specific for gp100₂₀₉ presented by HLA-A2 cannot distinguish between the native and T2M-modified peptide, in accordance with the crystallographic data. Very recent data indicate that the T cell reactivity against these peptides seen in ELISPOT is also a measure of their reactivity toward tumors, which likely present much lower amounts of the native peptide than is achieved with the 1 μM pulse to cultured APCs performed in this study (N. P. Restifo, manuscript in preparation).

Activation thermodynamics for dissociation indicate hydrophobicity as the mechanism for the improved stability of the gp100_209–2M/HLA-A2 complex

The crystallographic structures described above do not directly indicate the physical mechanism behind the increased stability of the gp100_209–2M/HLA-A2 complex. Filling cavity space is an established way of enhancing protein stability, but at 24–33 cal/mol/ų of cavity space (40), the net decrease in volume of only 4.6 ų (Fig. 4⇑) provides for very little gain.

To gain insight into how substitution of Thr² with Met enhances peptide/HLA-A2 stability, we examined peptide dissociation kinetics as a function of temperature, determining activation thermodynamics for peptide dissociation via transition state analysis. Peptide dissociation measurements were performed with soluble, purified peptide/HLA-A2 molecules using steady-state fluorescence anisotropy. We used fluorescent derivatives of the gp100_209–217 and gp100_209–2M peptides with a single amino acid substituted with a fluorescein-conjugated lysine. Data were collected over the range of 4–37°C in the presence of a large excess of unlabeled peptide. Fig. 6⇓ shows dissociation data for peptides modified at Val⁵. The decreased dissociation rate for the T2M-modified peptide is evident at all temperatures studied.

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FIGURE 6.

Dissociation of the gp100₂₀₉ (A) and gp100_209–2M (B) peptides from HLA-A2 as a function of temperature. The decreased dissociation rate of the T2M-modified peptide is evident at all temperatures. Data for lower temperatures were taken for hundreds of hours (>2000 for 4°C), but are not shown for clarity. Lines represent exponential fits to the data as described in the Materials and Methods.

Consistent with similar quantitative analyses of peptide dissociation from class I MHC molecules (23, 41, 42, 43), the majority of the data in Fig. 6⇑ were best fit with a double-exponential decay function, consisting of a slow phase accounting for the bulk of the data and a minor, faster phase typically accounting for much smaller (5–10%) of the total amplitude. In similar measurements, the minor phase has been attributed to the presence of a small amount of peptide/H chain heterodimer, from which peptide more rapidly dissociates (23, 41). The major phase thus represents the more physiologically relevant dissociation of peptide from the complete class I MHC complex.

Table III⇓ summarizes complete data for measurements at 37°C, as well as measurements for peptides with fluorescein-conjugated lysine substitutions at Gln⁴ and Phe⁷. From Table III⇓, it is clear that the position of the fluorescein label can influence the measured off-rates, with substitutions at Phe⁷ differing substantially from those at Val⁵ and Gln⁴. However, the effect of the T2M substitution is independent of the position of the fluorescein label, as the rate of peptide dissociation from the fully assembled complex at physiological temperature (k₁ in Table III⇓) is a relatively constant 6- to 8-fold slower when methionine is present at position 2 compared with threonine.

Fig. 7⇓ shows Eyring plots for the data in Fig. 6⇑. Via transition state theory, analysis of kinetic data in this fashion permits determination of activation thermodynamics, with the slope of the line proportional to the activation enthalpy (ΔH^‡) and the intercept proportional to the activation entropy (ΔS^‡) (see Ref. 23). The thermodynamic parameters derived from this analysis are shown in Table IV⇓. The most important parameters are the differences between the native and T2M-modified peptides (ΔΔH^‡ and ΔΔS^‡). The values indicate that the slower dissociation of the T2M-modified peptide results from a more unfavorable activation entropy change (ΔΔS^‡ < 0), but this is offset by a favorable activation enthalpy change (ΔΔH^‡ < 0). As discussed further below, these data are most consistent with the increased hydrophobicity of the T2M-modified peptide (resulting in the unfavorable ΔΔS^‡) and the loss of a stabilizing hydrogen bond between Thr² and Glu⁶³ (resulting in the favorable ΔΔH^‡).

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FIGURE 7.

Eyring plots for the peptide dissociation data indicate the thermodynamic basis for the enhanced stability of the gp100_209–2M/HLA-A2 complex. Slopes of these lines are proportional to the enthalpic barriers for dissociation, whereas intercepts are proportional to entropic barriers. The steeper slope for the native peptide indicates a more unfavorable enthalpic barrier for dissociation, whereas the greater intercept indicates a more favorable entropic barrier. As the entropic component is larger, the native peptide dissociates faster.

The crystals of the two complexes were grown from drops at pH 6.5, yet the measurements above were performed at pH 7.4. To control for the effect of pH, we repeated the measurements with the two peptides labeled at position 5 at pH 6.5, 37°C (data not shown). Under these conditions, the half-life of the T2M-modified peptide/MHC complex is ∼5-fold longer than the half-life of the native peptide/MHC complex, compared with ∼7-fold longer at pH 7.4. These results indicate that while pH does influence peptide dissociation rates, the slower dissociation of the T2M-modified gp100₂₀₉ peptide is unlikely to arise from differences in the two structures at pH 7.4 that are not visible at pH 6.5, where the two complexes were crystallized.

The improved immunogenicity of gp100_209–2M correlates with the enhanced stability of the peptide/HLA-A2 complex

The crystallographic structures of the native and T2M-modified gp100₂₀₉ peptides bound to HLA-A2 indicate that the T2M substitution in gp100₂₀₉ does not alter the structure of the peptide/HLA-A2 complex. In accordance with the structures, in PBMC from 95 individuals, we were unable to determine different frequencies of T cells reactive toward either the native or T2M-modified peptides. Our findings strongly support the interpretation that the enhanced immunogenicity of the T2M-modified peptide is attributable to its enhanced affinity for HLA-A2, rather than TCR cross-reactivity or qualitatively different T cell responses (e.g., partial agonism or antagonism) resulting from different peptide conformations (note that as the T2M substitution in gp100₂₀₉ does not change the surface that is presented to TCRs, our data imply that Ag-specific TCRs would be unable to distinguish between the native and modified gp100₂₀₉/HLA-A2 complexes, i.e., TCR binding affinity and kinetics for the gp100₂₀₉/HLA-A2 complex should be no different from the values for the gp100_209–2M/HLA-A2 complex).

As the ∼9-fold enhancement in peptide binding affinity is composed of a ∼7-fold decrease in peptide dissociation rate, our data are most consistent with the increase in immunogenicity resulting from the slower dissociation rate of the T2M-modified peptide. Although the predicted small increase in peptide association rate could also play a role in influencing immunogenicity, the ∼7-fold greater half-life of the complex with the native peptide indicates that in the time for 50% of the modified peptide to dissociate from HLA-A2, only ∼0.8% of the native peptide would remain bound. The greater numbers of gp100_209–2M/HLA-A2 complexes on the surfaces of APCs could thus yield a more stable immunological synapse with Ag-specific T cells, leading to more productive signaling.

Comparison with other studies of the effects of the T2M-substitution in gp100₂₀₉

Our results contradict those of Clay et al. and Denkberg et al. (44, 45), who concluded that significant structural changes result from the T2M substitution in the gp100₂₀₉ peptide. Clay et al. identified T cell “cloids” that were capable of recognizing the T2M-modified but not the native gp100₂₀₉ peptide presented by HLA-A2. In light of our data, the findings of Clay et al. may be best attributable to TCR affinity or avidity: T cells expressing TCRs with weak affinity for the native gp100₂₀₉ peptide presented by HLA-A2 may not respond well to the native peptide as the fast peptide dissociation rate results in too few TCR-peptide/MHC interactions to support the formation of a stable immunological synapse. Conversely, with the T2M-modified peptide, the increased density of peptide/MHC complexes on the APC cell surface increases the likelihood that sufficient TCR-peptide/MHC interactions will occur, despite weak TCR affinity. This interpretation is supported by the experiments of Yu et al. (10), where CTL recognition of APC pulsed with the native gp100₂₀₉ peptide was substantially reduced when a significant time delay was introduced into the experiment, whereas the those pulsed with the T2M-modified peptide were unaffected.

Denkberg et al. based their conclusions of structural alterations resulting from the T2M modification on an Ab (1A9) that could recognize the T2M-modified but not the native gp100₂₀₉ peptide bound to HLA-A2 (45). These experiments, which were unlikely to be influenced by the more rapid dissociation of the native peptide, are clearly at odds with our findings. As indicated above, there are no physical differences in the surfaces of the gp100₂₀₉ and gp100_209–2M/HLA-A2 molecules, and electrostatic calculations of surface potentials do not show any effects stemming from removal of the hydrogen bond made from Thr² to Glu⁶³ (calculations not shown). The temperature factors in the two structures do not suggest different levels of motion between the two peptides. It is conceptually possible that there are differences not visible in the two structures even at the relatively high resolution of 1.8 Å, but if so, this would imply a level of discrimination not previously observed in Ab-Ag recognition. Although it is thus impossible to tell from the structures what, if any, differences the 1A9 Ab may be discerning, we do note that other studies have shown clear differences between Ab and TCR recognition of peptide/MHC complexes (46). Finally, we note the possibility that, as with any x-ray structure, the ensemble-averaged conformation present in vivo may differ from what is observed crystallographically. However, from the data presented in this study, there is no reason to expect that any conformational differences between in vivo and in vitro structures should differ between the complexes of gp100₂₀₉ and gp100_209–2M with HLA-A2.

Implications for vaccine design

The structure with the native gp100₂₀₉ peptide indicates how the polar threonine side chain is accommodated in the HLA-A2 P2 pocket, forming a hydrogen bond with Glu⁶³ of the HLA-A2 α1 helix. Given the polar environment around the rim of the pocket (Fig. 4⇑), the hydrogen bond made to Glu⁶³ is likely to be strongly stabilizing, as there should be little desolvation penalty for formation of this hydrogen bond. This interpretation is supported by the thermodynamic measurements summarized in Table IV⇑: the native peptide has a much higher enthalpic barrier for dissociation than the T2M-modified peptide, consistent with the need to break a strong hydrogen bond between Thr² and Glu⁶³, which is not present in the structure with the T2M-modified peptide. Dissociation of the T2M-modified peptide is unfavorable entropically, consistent with the greater hydrophobicity of methionine over threonine (47). Thus, hydrophobicity is the likely reason for the increased stability (and thus immunogenicity) of the gp100_209–2M/HLA-A2 complex (although side chain conformational entropy could play a role, its contribution is expected to be small relative to hydrophobicity; Refs. 48 and 49). However, the increase in hydrophobicity is offset considerably by the loss of the Thr²-Glu⁶³ hydrogen bond, accounting for the relatively small ∼9-fold enhancement in binding affinity for the T2M-modified peptide (5) (one caveat to this thermodynamic argument is we have measured activation energies for dissociation, rather than complete binding thermodynamics).

When the native and T2M-modified structures are superimposed, there is no overlap of the β-hydroxyl group of threonine at position 2 of the native peptide with any of the atoms of the methionine in the modified peptide (Fig. 2⇑C). This suggests that it should be possible to achieve further gains in peptide/MHC stability through addition of a β-hydroxyl moiety to methionine—essentially crossing threonine and methionine, producing a β-hydroxy-methionine amino acid capable of hydrogen bonding to Glu⁶³. As there are no structural differences induced by replacement of threonine with methionine, it is reasonable to hypothesize that the structure of gp100₂₀₉ with β-hydroxy-methionine at position 2 should likewise be unchanged. Thus, our results suggest an approach for engineering the gp100₂₀₉ peptide to achieve further gains in peptide/MHC stability and, potentially, immunogenicity. Such an approach may also be applicable to other TAA presented by HLA-A2, particularly those for which anchor-fixing using standard amino acids has failed to achieve immunologically significant gains.

In conclusion, we have shown that the T2M substitution in the gp100₂₀₉ TAA does not alter the structure of the gp100₂₀₉/HLA-A2 complex. Consistent with this finding, we were unable to identify higher frequencies of T cells specific for either the native or modified peptide in PBMC from a large number of human subjects. These data strongly support the conclusion that the greater immunogenicity of the gp100_209–2M peptide is due to the enhanced stability of the peptide/MHC complex, validating the anchor-fixing approach for generating therapeutic vaccine candidates. Finally, the structural and thermodynamic data suggest a route for generating improved APL vaccine candidates using nonstandard amino acids.