INTRODUCTION

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The cellular receptor for subgroup A avian sarcoma and leukosis virus (ASLV-A) is Tva, a small membrane-associated protein (2, 3, 25). The interaction between Tva and EnvA, the ASLV-A glycoprotein, has been well characterized by several groups. Tva specifically binds EnvA with high affinity (1, 14, 23, 27). Furthermore, the high-affinity binding between Tva and EnvA in vitro can trigger a series of conformational changes on EnvA believed to be essential for postbinding steps during ASLV-A entry (8, 9, 15, 16). Although only avian cells are naturally susceptible to ASLV-A infection, expression of Tva in resistant cells from a wide range of species renders them susceptible to ASLV-A entry. These results appear to support the notion that Tva is the only receptor required for ASLV-A entry in avian cells. Thus, analysis of Tva-EnvA interaction may provide a simple model to study the entry mechanisms of viruses including other retroviruses.

Within the extracellular domain of Tva is a 40-residue, cysteine-rich module that is closely related to the repeat modules of the human low-density lipoprotein receptor (hLDLR). In hLDLR, seven imperfect tandem LDL-A modules form the binding domain for its ligands, lipoproteins apoB and apoE (12, 24). In contrast, the single LDL-A module of Tva appears necessary and sufficient to mediate ASLV-A entry. The LDL-A module of Tva could bind EnvA and mediate efficient ASLV-A infection when it was fused to the membrane-spanning domain of mouse CD8 (20). Many point mutations within the module impaired or abolished the viral receptor function of Tva (21, 26, 27). Furthermore, the LDL-A module of Tva could be functionally replaced by the fourth repeat of hLDLR with minor amino acid substitutions (22). These results demonstrate that a single LDL-A module can independently mediate protein-protein interaction. Since the viral receptor function of Tva is solely determined by this module, it is imperative to characterize the role of this motif in viral infection by an integral approach of molecular, biochemical, and structural techniques in order for us to understand the molecular mechanism of ASLV-A entry.

To date, the role of the LDL-A module of Tva in viral infection has been mainly dissected by mutational analysis. Several residues within this module that appear to be important in mediating ASLV-A infection have been identified (21, 22, 26, 27). However, one drawback of these studies is that it is difficult to distinguish whether a mutation within the motif affects the overall structure of Tva or specifically disrupts the ligand recognition, a common problem in interpreting results with mutational analysis of any protein. Fortunately, structures of several individual LDL-A modules have been recently reported (6, 7, 11, 13, 17, 19). These provide insights regarding the overall folding of the LDL-A module of Tva, since the LDL-A modules reported so far all adopt similar three-dimensional conformations. Each module consists of a short antiparallel  sheet and a one-turn  helix. The structure is stabilized by three pairs of disulfide bonds formed by six invariable cysteines. Furthermore, six amino acids, including four highly conserved acidic residues, form a "calcium cage," coordinating calcium with high affinity (5, 13). However, the role of calcium in Tva folding and function has not been previously examined.

In this study, using biochemical and biophysical techniques, we examined the role of calcium in protein folding of the LDL-A module of Tva and found that calcium is indeed required for its correct folding and structure. Furthermore, we characterized the role of calcium in protein folding of two classes of Tva mutants: those residues that are directly involved in calcium binding and those residues that are not directly involved in calcium coordination but that, when mutated, result in impaired function of Tva. As expected, mutations of those Ca²⁺-binding residues are defective in protein folding. Surprisingly, mutations of the non-calcium-binding residues can also affect protein folding. This study provides new insights on structure and function of Tva in ASLV-A entry.

	MATERIALS AND METHODS

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Cloning and preparation of wt Tva LDL-A module and its mutants. The LDL-A module of wild-type (wt) Tva and its mutants were amplified by PCR from Tva and Tva mutant expression plasmids. To facilitate the cloning procedure, a BamHI site and a XhoI site were engineered into the upstream and downstream primers, respectively. The PCR products were cloned into pGEX-4T-1 (Pharmacia), and the identity of each construct was confirmed by DNA sequencing.

In vitro refolding of the wt Tva LDL-A module and its mutants. The lyophilized protein samples were dissolved in 6 M guanidinum chloride-50 mM Tris-HCl-1 mM dithiothreitol (pH 8.5). The samples were diluted to approximately 100 µg/ml with folding buffer (50 mM Tris [pH 8.5], 1 mM reduced GSH, 0.5 mM oxidized GSH) and then dialyzed against folding buffer containing either 10 mM CaCl₂ or 1 mM EDTA for at least 24 h at room temperature under oxygen-free conditions. Folded Tva LDL-A modules were purified by reverse-phase HPLC on a Vydac C₁₈ column as described above. The unlabeled purified samples were used for calorimetry analysis, and the ¹⁵N-labeled purified samples were used for nuclear magnetic resonance (NMR) spectroscopy.

Reverse-phase HPLC. To examine whether folding of the Tva LDL-A module is Ca²⁺ dependent, aliquots of the refolding reaction mixtures (either in the presence or in the absence of CaCl₂) were analyzed by reversed-phase HPLC on a Vydac C₁₈ column under the same conditions as for protein purification described above.

NMR spectroscopy. NMR spectra were acquired as described previously (10). Briefly, all NMR spectra were recorded at the University of Illinois at Chicago on a Bruker DRX600 spectrometer equipped with a pulsed-field-gradient accessory and operating at 600.13 MHz for ¹H. Spectra were processed and analyzed using Triad version 6.3 software (Tripos, Inc., St. Louis, Mo.). The lyophilized ¹⁵N-labeled LDL-A module of Tva and its mutants were dissolved in 50 mM Tris-HCl-100 mM NaCl-10% D₂O (pH 7.0). To examine the effect of Ca²⁺ binding on protein folding and structure of the LDL-A module of Tva, CaCl₂ was added either in the folding reaction or in NMR analysis or in both with a final concentration of 10 mM. The final protein concentration was 100 µM. [¹H-¹⁵N] HSQC (heteronuclear single quantum correlation spectroscopy) spectra were recorded at 25°C. The central frequencies were 4.70 and 118 ppm for ¹H and ¹⁵N, respectively.

Isothermal titration calorimetry (ITC). Calcium titrations were performed on a MicroCal MSC isothermal titration calorimeter as specified by the manufacturer (MicroCal Inc., Northampton, Mass.). Experiments were performed at 30°C. Buffers used were 20 mM Tris-HCl, 100 mM NaCl, and 0.02% NaN₃, pH 7.4. HPLC-purified LDL-A module of Tva and its mutants were dialyzed overnight in the above pH 7.4 buffer, containing Chelex 100 (Bio-Rad) to remove any metal ion contamination in the protein samples. Then the samples were diluted to 10 µM in buffer and titrated with a 2-µl injection of 2 mM CaCl₂ in buffer. Fifty injections were used in each experiment. Data were analyzed with Origin (MicroCal) and were fitted to a simple one-binding-site model.

	RESULTS

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Expression and purification of the wt Tva LDL-A module and its mutants. The coding regions of the wt Tva LDL-A module and its mutants (Fig. 1) were amplified by PCR and cloned into an E. coli expression vector, pGEX-4T-1, as GST fusion proteins. We used these mutants in this study because although they are all impaired in the viral receptor function of Tva (Fig. 1), their roles in protein folding and function might differ. Based on structure information for other LDL-A modules, two of these mutants (D46A and E47A) should be defective in calcium binding since the side chains of these residues are predicted to be involved in Ca²⁺ coordination along with four other amino acids in the module. In contrast, L34 and W48 are not predicted to be directly involved in Ca²⁺ binding but are likely to be involved in ligand recognition.

View larger version (12K): [in this window] [in a new window]   FIG. 1.   Amino acid sequences of wt and mutants Tva LDL-A modules in GST fusion constructs. Dashes indicate identical residues; underlines indicate mutated residues. The LDL-A module region is shown as boldface letters. The ability of the wt Tva and Tva mutants to mediate ASLV-A infection was expressed as the number of alkaline phosphatase-positive cells per milliliter of viral stock. The data are from references 21 and 22.

Examination of Ca²⁺-dependent protein folding by reverse-phase HPLC. HPLC has been previously used by others to examine in vitro Ca²⁺-dependent folding of several LDL-A modules (5, 19). It was demonstrated that LDL-A modules were eluted as many broad peaks in the absence of calcium but as a sharp single peak in the presence of calcium. These results suggest that correct folding of an LDL-A module is dependent on calcium and that without it, the module will fold as various isomers. Therefore, we used reverse-phase HPLC to characterize the folding patterns of the wt Tva LDL-A module as well as its mutants either in the presence or absence of calcium.

View larger version (33K): [in this window] [in a new window]   FIG. 2.   Elution profiles of wt and mutant Tva LDL-A modules by reverse-phase HPLC. The purified proteins were folded in vitro in the presence (A, C, E, G, and I) or absence (B, D, F, H, and J) of calcium and then eluted by reverse-phase HPLC.

Examination of Ca²⁺-dependent protein folding by NMR spectroscopy. To further characterize Ca²⁺-dependent protein folding of the wt Tva LDL-A module and its mutants, the ¹⁵N-labeled proteins were prepared for acquisition of two-dimensional NMR spectra ([¹H-¹⁵N] HSQC spectra) after in vitro folding either in the presence or in the absence of calcium. It is known that correctly folded proteins display well-dispersed spectra in both proton and amide ¹⁵N dimensions, while unfolded or misfolded proteins give ill-defined and poorly dispersed spectra.

View larger version (30K): [in this window] [in a new window]   FIG. 3.   Two-dimensional [1H-15N] HSQC spectra of the LDL-A module of Tva and its mutants. The purified 15N-labeled proteins were folded in vitro in the presence (A, B, E, F, G, and H) or absence (C and D) of calcium, and two-dimensional [1H-15N] HSQC spectra were acquired either with added calcium (A, C, E, F, G, and H) or with no added calcium (B and D) as described in Materials and Methods. For example, wt +Ca/+Ca (A) indicates that calcium was present in the folding reaction (+Ca/) and with added calcium in NMR analysis (/+Ca).

Measurement of Ca²⁺-binding affinity by ITC. ITC was used to directly measure Ca²⁺-binding affinity of the wt Tva LDL-A module and its mutants. Calcium titrations were performed on a MicroCal MSC isothermal titration calorimeter. A CaCl₂ solution (2 mM) was added in 2-µl increments up to a molar ratio of 15:1 for each protein (10 µM). As shown in Fig. 4A, Ca²⁺ binding of the wt LDL-A module gave a measureable heat change with an apparent dissociation constant (K_d) of 40 µM at 30°C. The Ca²⁺ binding of W48A (Fig. 4B) and L34A (Fig. 4C) proteins was also measurable, with apparent dissociation constants of approximately 48 and 100 µM, respectively. These results are in agreement with those for HPLC and NMR spectra, indicating that the wt Tva LDL-A module binds calcium with a relatively high affinity, while W48A and L34A proteins are slightly impaired in Ca²⁺ binding (wt > W48A > L34A). In contrast, under the same conditions, neither D46A nor E47A mutant protein displayed any detectable Ca²⁺-binding activity (data not shown), indicating that these mutations greatly reduced the Ca²⁺-binding affinity of Tva. A major difference between the L34A variant and either wt Tva or the W48A variant was in the thermodynamics of binding. Although wt Tva shows slightly endothermic binding of Ca²⁺ (H = 0.84 kcal mol¹), while the W48A and L34A variants show slightly exothermic (H = 0.35 kcal mol¹) and strongly exothermic (H = 5.38 kcal mol¹) binding, respectively, the more significant difference is in the relative contributions of entropy to the binding process. For wt and the W48A variant, binding is driven primarily by entropic considerations, with TS° being 7.28 kcal mol¹ (out of G° of 6.44 kcal mol¹) and 5.98 kcal mol¹ (out ofG° of 6.33 kcal mol¹), respectively. In marked contrast, calcium binding to the L34A variant is predominantly enthalpic (H = 5.38 kcal mol¹ out of G° of 5.86 kcal mol¹), with only a minor contribution from entropy (TS° = 0.48 kcal mol¹). This is consistent with similar folds and structures of wt and W48A Tva but a major structural difference for the L34A variant, as indicated both by the NMR HSQC spectra and the HPLC elution profiles. It may be that the leucine present in wt Tva becomes buried upon correct folding and plays an important role in such folding. This might be expected to release considerable solvent and so contribute to the favorable entropy of binding and folding. Such favorable entropy would be largely lost upon replacement of the large hydrophobic leucine side chain with the small alanine and might no longer provide the impetus for folding along the correct pathway.

View larger version (15K): [in this window] [in a new window]   FIG. 4.   Calcium titration of the Tva LDL-A module and its mutants by ITC. The Ca2+-binding affinity and enthalpy of binding of wt and mutant Tva LDL-A modules were measured by ITC. D46A and E47A mutant proteins did not display detectable Ca2+ binding by ITC (data not shown). x axis, Ca2+/protein molar ratio; y axis, heat release or uptake upon calcium binding. Note that the scales differ among the three panels.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

In this report we demonstrated that the LDL-A module of Tva, like other LDL-A modules, requires calcium for correct folding. This conclusion is based on in vitro folding studies of the wt LDL-A module and the mutants of Tva by several different methods. We have shown that the wt LDL-A module of Tva was eluted as a single sharp peak by reverse-phase HPLC and gave a well-dispersed NMR spectrum when the module was folded in the presence of calcium. In contrast, when the module was folded in the absence of calcium, it was eluted as several broad peaks in HPLC profiles, and the NMR spectrum was ill defined and highly clustered. When two of the Ca²⁺-binding residues were mutated (D46A and E47A), the LDL-A module of Tva was not correctly folded either in the presence or in the absence of calcium. In addition, we have shown that mutations of the non-calcium-binding residues (W48A and L34A) could also influence Ca²⁺-dependent folding of Tva. Compared to the wt LDL-A module of Tva, W48A and L34A mutant proteins have only slightly lower Ca²⁺-binding affinity (K_d = 40 µM for wt versus 48 and 100 µM for W48A and L34A mutant proteins) but show large differences in the importance of entropy in forming the Ca²⁺-bound conformation. This study, reveals for the first time the critical role of calcium in Tva folding, structure, and function.

As demonstrated by molecular and mutational analysis previously, the viral receptor function of Tva is solely determined by a single LDL-A module within the extracellular domain of Tva (20, 26). Since the LDL-A module of Tva is highly conserved compared to other LDL-A motifs, it is reasonable to assume that the LDL-A module of Tva adopts a three-dimensional conformation similar to other reported LDL-A structures. Thus, it was hypothesized, and supported by mutational analysis, that six invariable cysteines in Tva form three pairs of disulfide bonds as C₁-C₃, C₂-C₅, and C₄-C₆ (4), like other LDL-A modules. However, it appears that the correct pairing of these cysteines is Ca²⁺ dependent. The facts that the wt Tva LDL-A module was eluted as multiple broad peaks by reverse-phase HPLC and gave highly clustered two-dimensional NMR spectra when folded in the absence of calcium suggest that at least several isomers were formed. Theoretically, there are 15 possible combinations of disulfide bonds with six cysteines in the LDL-A module of Tva. It is obvious, however, that when calcium is present in the folding reaction, the LDL-A module of Tva folds as a single isomer, presumably the biologically active, native form in vivo. When the Ca²⁺-binding residues such as D46 or E47 in Tva are mutated, Tva cannot coordinate efficient Ca²⁺ binding. Thus, the protein is misfolded even in the presence of calcium, as we proposed previously (21, 22). This study provides direct biochemical evidence to bolster our hypothesis that the role of the Ca²⁺-binding residues (such as D46 and E47) of Tva is probably structural in nature. Thus, it is expected that E47A mutant protein should be impaired in EnvA binding and in mediating ASLV-A infection. Indeed, this mutant protein did not display detectable EnvA binding, measured either by an enzyme-linked immunosorbent assay (21) or by flow cytometry (27). One plausible explanation that may reconcile the discrepancy between the folding defect of E47A protein reported in this study and its ability to mediate ALSV-A infection as reported previously by us (21) (Fig. 1) and by others (27) is that although the majority of E47A mutant protein was misfolded, a small fraction of this protein could adopt the native conformation, and this small fraction was sufficient to mediate ALSV-A infection since the mutant protein was overexpressed in our infection assay, as we previously suggested (21). Consistent with this explanation, we found that several Tva mutants, including E47A, displayed a more pronounced defect in mediating ALSV-A infection when they were expressed at lower levels on the cell surface (data not shown), indicating that overexpression of Tva mutant proteins can mask the defective phenotype.

One important finding of this study is that we now have a better understanding of the structure-function relationship of Tva in viral entry. Residues leucine 34 and tryptophan 48 have been found previously to be critical for the viral receptor function of Tva (22, 27). Because these residues are not predicted to be Ca²⁺ binding, it was hypothesized that these residues might be directly involved in ligand recognition. However, the results presented in this study suggest that this hypothesis is likely too simplistic. Although W48A and L34A mutant proteins behaved more like the wt Tva module than D46A and E47A mutant proteins in Ca²⁺-dependent folding in vitro, they displayed distinct differences in HPLC elution profiles, [¹H-¹⁵N] HSQC spectra, and Ca²⁺-binding affinity. First, both mutant proteins were eluted as a predominant sharp peak corresponding to that of the wt protein, but there were several detectable shoulders with these proteins (Fig. 2G and I), indicating that several different isomers were folded even in the presence of calcium. Furthermore, examination of the NMR spectra of these mutant proteins indicates that the spectra were not as well dispersed as that of wt Tva, particularly for the L34A mutant protein (compare Fig. 3G and H to Fig. 3A). These results indicate that although L34 or W48 of Tva is not directly involved in Ca²⁺ binding, mutations of these residues nevertheless exert an adverse effect on the structure of Tva to such an extent that they impair Ca²⁺-mediated folding to the correct conformation. These results are consistent with a report by others showing that a non-Ca²⁺-binding residue in an LDL-A module can affect Ca²⁺ coordination (18). Therefore, we now believe that although it is still likely that both L34 and W48 are involved in ligand recognition, the defect of L34A or W48A mutant protein in mediating ASLV-A entry (Fig. 1) is at least partially due to structural alteration in Tva.

Another important aspect of this study is that an integral approach of molecular, biochemical, and structural techniques is needed for us to elucidate how a simple receptor like Tva can mediate efficient ASLV-A infection. Three techniques used in this study, HPLC, two-dimensional NMR, and calorimetry, gave not only internally consistent but also very complementary results. For example, reverse-phase HPLC indicated that L34A or W48A mutant protein did not fold exactly like the wt Tva module in the presence of calcium. The two-dimensional NMR spectra suggested that even the predominant sharp peak of L34A mutant protein may not be a single isomer. Furthermore, ITC data basically confirmed that the wt Tva module binds calcium with a higher affinity than L34A and W48A proteins. Somewhat surprisingly, the wt and W48A Tva modules bound to calcium predominantly as a result of favorable increase in entropy, while the L34A mutant protein relied mainly on enthalpy for binding (Fig. 4 and Results). Again these results suggest that L34A protein is very different from wt Tva, while the W48A variant, though not identical, is more closely similar to wt Tva.

In conclusion, this study firmly established the critical role of calcium in Tva folding and function. In addition, the well-defined two-dimensional NMR spectra of the wt LDL-A module of Tva suggest that it is feasible to use NMR to determine the three-dimensional structure of the viral interaction domain of Tva. Structure-function analysis of this receptor may yield new insights on how a receptor mediates efficient viral infection.