(Received for publication, May 17, 1996, and in revised form, September 13, 1996)
From the Laboratoire de Résonance
Magnétique Nucléaire, CNRS URA 1129 and the
¶ Unité de Programmation Moleculaire et Toxicologie
Génétique, CNRS URA 1444, Institut Pasteur, 28 rue du
Docteur Roux, 75724 Paris Cedex 15, France
A set of permissive positions that tolerate insertions/deletions without major deleterious consequences for the binding activity of the protein was previously identified in the maltose-binding protein. The C3 epitope from poliovirus VP1 protein (93DNPASTTNKDK103) was inserted into eight of these positions and two nonpermissive control sites. NMR studies were performed on the MalE protein, the insertion/deletion mutants, and the C3MalE hybrids to selectively determine the flexible regions in these proteins. Comparison of the C3 epitope mobility in the different hybrid proteins indicates that, whatever its insertion site and independently from the specific sequences of its linkers, the epitope is mostly flexible. The vector protein was shown to unfold partially only in the two C3MalE hybrids that correspond to nonpermissive positions. For one of them (insertion at site 339), both sides of the insert are flexible, and at most one side for all the other hybrids. This result correlates with the antigenicity data on the inserted epitope (Martineau, P., Leclerc, C., and Hofnung, M. (1997) Mol. Immunol, in press.
Natural or synthetic peptide fragments of proteins are widely used as antigenic and immunogenic probes. However, as a rule, anti-peptide antibodies show less affinity for the native protein than antibodies raised against the protein itself, and similarly, antibodies raised against the native protein bind antigenic peptides less tightly than the native protein. Linear peptides generally poorly mimic the conformation of the antigenic determinants because of their largely unfolded structure in aqueous solution, and restriction of their conformational space has been used for decades to obtain a better mimicry (1). There are a great variety of approaches to carry out this restriction; however, most of them rely on the knowledge of the structure of the epitope in its natural environment: for instance, epitopes in loops will often be mimicked by cyclic peptides, whereas stabilization of elements of secondary or tertiary structure will generally be performed by an appropriate modification of the original sequence (2).
Expression of peptides as fusions within a carrier protein, the
maltose-binding protein (MalE), was proposed by Hofnung et al. (3). This procedure allows anti-peptide antibodies to be elicited without peptide synthesis and without knowledge of the epitope
conformation. A set of "permissive" sites was determined in the
MalE protein. These sites are regions of the protein that accept
modifications of their primary sequence without major deleterious consequences for the biological activity, structure, and cellular localization of the hybrids. Random insertion of a BamHI
octanucleotide linker into the malE gene was first described
to generate series of insertion/deletion mutants (4, 5). Depending on
the reading frame and surrounding nucleotides, there was a linker
insertion that contained 2 or 3 amino acids and was accompanied in most cases by small deletions corresponding to the loss of a few residues. The permissive sites were mainly located in structured regions on the
surface of MalE (6). They were shown to accept the insertions of
heterologous peptides of various length and origin (7, 8, 9, 10, 11). One of the
tolerated insertions was the C3 epitope from poliovirus type I (Mahoney
strain). C3 is a neutralizing epitope (12). In the virus, it forms a
hydrophilic loop comprised between two antiparallel -strands and
encompassing residues 93-103 (DNPASTTNKDK) at the surface of the VP1
envelope protein (13).
Peptide DNPASTTNKDK was inserted into 11 different sites in the MalE protein; its antigenic properties (recognition by antibodies) and immunogenic properties (ability to elicit an immune response) were studied for 10 of these sites (eight permissive and two nonpermissive) (11).1 Depending on the insertion site, the C3 peptide was flanked by linkers of 2 or 3 amino acids with specific sequences (see Table II). It is likely that the fusions at both ends may limit the conformational space of a peptide inserted into a carrier protein in comparison with the free peptide. Its intrinsic flexibility remains constant, but its flexibility, when inserted into the vector, may depend on the site of insertion. It was therefore tempting to investigate whether the flexibility of the C3 epitope was dependent on its localization in the hybrid proteins.
|
NMR is currently used to study the three-dimensional structure of
proteins up to a Mr of 20,000. Studies of larger
proteins are hindered by the loss of spectral resolution. First, there is an overlap of the individual resonances from the increased number of
protons. Second, there is a severe broadening of these resonances due
to the slow overall rotational tumbling of the protein associated with
short transverse relaxation time (T2) values.
Line widths predicted by a simple model for macromolecules are indeed
in the range of 50-100 Hz or even greater for motions on the order of
5 × 108 to 5 × 10
6 s (14). Since in
a two-dimensional experiment, the cross-peak intensities decrease as
T2, most of the signals merge into the background. If, however, some regions of the molecule present a local
flexibility, that is when internal motion occurs on a much faster time
scale, on the order of 10
9 to 10
8 s, this
will generate higher values of T2. Narrowing of
the corresponding resonances, typically to 5-20 Hz, will lead to the
emergence of the corresponding cross-peaks from the background and to
their specific observation. NMR dynamic filtering can thus be used to detect selectively regions of greater mobility in large proteins.
NMR studies were therefore performed to investigate the flexible regions of the MalE protein, of the insertion/deletion mutants, and of the C3 hybrids in order to determine if the insertion and deletion modifications of the structure of the wild-type protein affected its mobility. Flexibility of the C3 epitope in the different hybrid proteins was compared and analyzed with respect to the insertion site localization. This study is part of a more general work on the structural and immunological characteristics of heterologous peptides inserted into the MalE vector and on a potential correlation between these properties and the peptide environment in the hybrid proteins.1,2,3
Insertion/deletion mutants corresponding to BamHI sites introduced after residues 133, 161, 206, 211, 285, 296, 303, 339, and 363 were obtained as described previously (5). Hybrid proteins were prepared by insertion of an oligonucleotide coding for the C3 peptide into the previously introduced BamHI sites (11). Except for site 339, all these insertion sites were permissive.1 The C3 peptide was also inserted into the natural BclI nonpermissive site located after residue 348.1
Mutant genes were expressed on multicopy plasmids derived from pBR322
in Escherichia coli strain PD28, which carries a nonpolar deletion in the chromosomal malE gene
(malE444) and is constitutive for malE gene
expression (malTc1) (4, 15). Cultures were grown
in LB medium (16) supplemented with 0.2% maltose and 100 µg/ml
ampicillin for 7 h at 30 °C. Final A600
was between 2 and 3 (1-2 × 109 bacteria/ml). MalE
proteins were released from the periplasm by osmotic shock (17).
All proteins, except the insertion/deletion mutant MalE339, the corresponding hybrid MalE339C3, and the hybrid MalE348C3, in which C3 is introduced at a natural BclI site, were purified by affinity chromatography on a cross-linked amylose column according to Ferenci and Klotz (18). The MalE339, MalE339C3, and MalE348C3 proteins, which were unable to bind to the amylose column, were purified by ion-exchange chromatography on a MonoQ fast protein liquid chromatography column (Pharmacia Biotech Inc.) equilibrated in 20 mM Tris-HCl buffer, pH 7.5. Elution was performed with a linear gradient from 0 to 150 mM NaCl.1 Purified MalE protein derivatives were precipitated with ammonium sulfate at 80% saturation and stored at 4 °C.
NMR ExperimentsProteins (~10 mg) were recovered by centrifugation; suspended in a minimum volume of 10 mM sodium phosphate buffer, pH 6.5; exhaustively dialyzed against the same buffer; and freeze-dried. Samples were dissolved in 650 µl of either H2O/D2O (9:1, v/v) or 99.96% D2O (Euriso-top). Unless otherwise indicated, maltose was added to 1 mM. The final concentration of MalE proteins was 0.2-0.6 mM, depending on the sample, and that of the salt concentration was ~10 mM. When needed, acidification to pH 4.2 was performed by addition of diluted H3PO4.
Concentration of the wild-type MalE protein was calculated from its UV
absorbance at 280 nm using an extinction coefficient of 68,750 M1
cm
1.4 Mutants were quantified
by colorimetric assay using the Bio-Rad kit and wild-type MalE as a
standard (19). Homogeneity of the MalE proteins was checked on
SDS-polyacrylamide gel (12%) before and after the NMR experiments
(20).
NMR spectra were recorded at 35 °C on a Varian Unity 500 spectrometer equipped with Sun Sparc computers. TOCSY5 experiments using MLEV17 to produce isotropic mixing (21, 22) were carried out with mixing times ranging from 20 to 80 ms. NOESY experiments (23) were recorded with mixing times of 60 and 100 ms. Saturation of the solvent proton resonance was accomplished by selective irradiation during the relaxation delay (2 s) and also during the mixing time in the NOESY experiments. Data sets were collected in the phase-sensitive mode with the hypercomplex scheme (24). Spectra were recorded with a sweep width of 7000 Hz in both dimensions and 32 scans/T1 increment. A total of 512 free induction decays of 2048 data points were collected in T2. Prior to Fourier transformation, spectra were zero-filled to final matrices of 2048 × 4096 points in T1 and T2, respectively, and matrices were multiplied by a shifted squared sine bell window function to enhance the resolution.
The overall structure of MalE consists of two distinct globular
domains separated by a deep groove, in which maltose binds, and
connected by three short segments. Both domains exhibit similar supersecondary structure: a core of -sheets flanked on both sides with
-helices (Fig. 1) (25). Secondary structure
element characterization according to Kabsch and Sander (27) gives 50%
of the residues in
-helices, 22% in
-sheets, and the remaining
28% in loops and coils. As expected for a molecule of this size, no
flexible region was detected by NMR with our criteria in the wild-type protein. TOCSY and NOESY spectra of the protein in
H2O/D2O showed only a few cross-peaks. Signal
intensity was very low, and these signals could hardly be distinguished
from the background, especially in the NH-
H region. The lack of
cross-peaks in this region was not due to an exchange of the amide
protons with deuterium since spectra recorded at pH 6.5 and 4.2 were
similar. Only a few spin systems could be determined, and corresponding
residues did not fit with any continuous sequence in the protein.
As with the wild-type protein, MalE mutants showed spectra with very low amide proton signals in H2O/D2O (9:1, v/v). Therefore, only TOCSY experiments in D2O were performed to investigate the MalE protein flexible regions. Fingerprints of the insertion/deletion mutants, of the corresponding C3 hybrids, and of wild-type MalE were compared three by three and carefully analyzed. The cross-peaks with significant intensity that were not present in the wild-type MalE spectra and that appeared in the mutant spectra were identified to known spin systems. Reconstitution of sequences present in the inserts and in the vector was attempted from the corresponding residues. Such sequences determining mobile segments were found in all the hybrids and in some of the insertion/deletion proteins. To discard the possibility that some signals of the protein and of the maltose overlap, preventing the identification of other residues, spectra of samples without maltose were recorded. No significant difference with spectra of samples containing 1 mM maltose was observed. The location of the insertion sites within the secondary structure of MalE is shown in Table I, and results on the respective mobility of the MalE proteins are presented Table II.
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The insertion/deletion mutant MalE133
comprises a deletion of 9 residues in helix IV at the surface of the C
domain and an insertion of 2 residues, DP. The corresponding hybrid
MalE133C3 presents an insertion of 15 residues, the 11 residues of the
C3 insert and the 4 residues of the flanking sequences, DP and DP. The
MalE133 spectrum did not show any significant change as compared with
the MalE spectrum, whereas in MalE133C3, new cross-peaks appeared (Fig.
2). One proline, 1 alanine, 1 serine, and 2 threonines could be unambiguously identified from their characteristic spin systems and their chemical shifts (28). Lysine and five spin systems
which could agree with aspartic acid or asparagine were also detected.
The only sequence that could be reconstituted from these residues in
the hybrid protein was therefore DNPNKDKD, provided both lysines had
approximately similar chemical shifts. This sequence corresponds to
that of the C3 epitope, DNPNKDK, extended with the first residue of its
C terminus flanking sequence, DP.
Although weakly packed on the central -sheet in the C domain, helix
IV was not found to be mobile in MalE. Deletion of three-quarters of
its residues did not reveal any flexible region in the
insertion/deletion mutant MalE133. It has already been suggested that
-helix deletion accommodation in insertion/deletion mutants occurred
by shifting the packing and bonding of both the small inserted linker
and the vector residues on each side of the insert (6). In view of the
pitch per residue between an
-helix (1.5 Å) and a
-strand (3.5 Å), one proposed mechanism to compensate for a deletion in a helix was
the creation of a strand. Our results are compatible with this
hypothesis. On the contrary, when replaced by peptide C3 in the
MalE133C3 hybrid, helix IV changes for a flexible segment of 12 residues, the 11 residues of C3 and 1 residue of the flanking sequence.
Peptide C3 has no intrinsic propensity to form a helix and corresponds
to a loop in the original poliovirus VP1 protein. Due to its number of
residues, it would not be able to form a strand without major changes
in the vector structure when inserted into MalE and should therefore
form a loop. The loop, too long to interact with the C domain central
-sheet, would move freely. Results show that the flanking regions of
the vector protein, a turn of helix on one side and a small coiled
segment on the other, are not destabilized.
In MalE161, which lacks the entire G
strand and part of the H strand of the C domain two-stranded
antiparallel GH -sheet plus a part of helix V, 16 residues are
deleted and 3 inserted (GIR). The corresponding MalE161C3 hybrid
comprises a 16-residue insertion, including the flanking sequences RI
and GIR.
Spectra of MalE161 and of the wild-type protein were rather similar. Differences principally occurred in the aromatic region, where some cross-peaks disappeared in the mutant. As the deleted sequence contains 3 tyrosines (positions 167, 171, and 176) and 1 phenylalanine (position 169), missing signals are probably related to some of these residues. In spite of the length of the deletion, no flexible region became apparent. This suggests an important shift of the packing and bonding of the linker and of the vector flanking residues together with the existence of interactions between these residues and both helices XIII and XIV.
The sequence ASTTNKDKGIR could be unambiguously reconstituted from the
identified residues in the spectrum of MalE161C3. The fact that no
glycine was observed indicates that its two -protons have similar
chemical shifts, which is in agreement with a great flexibility of this
residue. This result shows that the first 3 residues of C3 (DNP)
present tight interactions with the other structural elements of the C
domain. The fact that helix V extends to the linker RI and to these
residues may not be excluded. As in the MalE133C3 hybrid, other deleted
secondary structure elements are replaced by a flexible loop, probably
without consequence on the tertiary structure of the vector.
MalE206 and MalE211 comprise
deletions of 10 or 9 residues, respectively, in helix VII, which faces
the binding cleft in the C1 domain, and insertions of 3 (RIR) or 2 (GS)
residues, respectively. Spectra of the two mutants did not reveal any
mobile region. Although helix VII is well packed on the central
-sheet of the C domain, removal of its first two (MalE206) or last
two (MalE211) turns did not induced any flexible region in the
molecule. It is likely that accommodation of the deletion within helix
VII occurs with the same mechanism as that suggested for the MalE133
mutant.
Spectra of both the MalE206C3 and MalE211C3 hybrids allowed the
reconstitution of the C3 epitope sequence, with 2 extra serine residues
most probably belonging to sequences flanking the insert in MalE211C3.
It appears from these results that C3 peptides are inserted in
positions 206 and 211 as loops flexible throughout their length and
that their insertion does not produce the unfolding of the remaining
parts of helix VII or their unpacking from the C domain central
-sheet. A similar observation was made for helix IV in the MalE133C3
hybrid.
MalE285 presents no deletion, but only an insertion of 3 residues (RIR) in the coiled segment connecting the two helices IX and X of the N domain. No mobile region was observed in this mutant.
In the corresponding MalE285C3 hybrid, 13 residues fitting in the sequence DNPNKDKGIRT were unambiguously detected. Since a few residues of the vector protein on one side at least of insertion site 285 had to move to allow the C3 insertion, it is therefore likely that the opening of the main chain is just large enough to tolerate the insertion. Indeed, 1 residue only of the vector (Thr286) became mobile, and helices IX and X did not unfold.
Insertion Sites 296 and 303Deletions in MalE296 and MalE303
are located in the same region of the N domain, but they widely differ
in length. MalE296 comprises deletions of -strand M and of helix XI,
i.e. 16 residues, and includes a TDP insertion. MalE303
lacks only a part of helix XI, 6 residues, and includes a PDP
insertion. Spectra of the insertion/deletion mutants did not show any
mobile region.
In the MalE296C3 hybrid, all the C3 residues were identified, but none
of the flanking sequences, TDP and DP. In the MalE303C3 hybrid, the
sequence DNPASTTNKDKDPELA could be reconstituted from the residues
identified, i.e. the C3 epitope, its C-terminal flanking sequence, and the first 3 residues of the vector on the same side. An
ambiguity remained about the mobility of the 4th residue of the vector
Lys313 because of the overlapping of the lysine
cross-peaks. Insertion of epitope C3 as a loop in site 296 did not
destabilize the vector protein, although two of its secondary structure
elements, -strand M and helix XI, were deleted. In MalE303C3,
however, in which only a part of helix XI was suppressed, insertion of
peptide C3 made the remaining last turn of helix flexible, most
probably via its unfolding. Such a destabilization had not been
observed in the MalE133C3, MalE206C3, and MalE211C3 hybrids, although
deletions also involved parts of helices.
MalE339 comprises a deletion of 17 residues, including the last three turns of helix XIII and the segment connecting helix XIII to the C-terminal helix XIV, and an insertion of 3 residues, SDP. The spectrum showed that its C-terminal region was entirely flexible, from Ser337 to Lys370, which indicates that the remaining first turns of helix XIII and of helix XIV were destabilized and have most probably lost their secondary structure.
As with MalE339, the corresponding MalE339C3 hybrid was flexible from residue 337 to the C terminus of the molecule. The C3 epitope, both flanking sequences SDP and DP, and 15 residues of the vector, 3 on the N-terminal side of the insert and 11 on the C-terminal side, were identified, indicating the unfolding of both helices XIII and XIV as in the insertion/deletion mutant. Cross-peaks related to the C-terminal 358-370 residues were superimposable in both MalE339 and MalE339C3.
Insertion Site 348 (Nonpermissive)As MalE348C3 was obtained by insertion of the C3 coding oligonucleotide in a natural restriction site of the malE gene, there was no corresponding insertion/deletion mutant, and the spectrum of the hybrid was directly compared with that of the wild-type protein. MalE348C3 comprises an insertion of 13 residues in the last turn of helix XIII, the C3 epitope extended with a GI flanking sequence on its C-terminal side. The spectrum of the hybrid protein presented a large number of cross-peaks, which allowed the reconstitution of a sequence including the last 7 residues of the epitope (STTNKDK), the flanking sequence GI, and the entire C-terminal region of the vector NAASGRQTVDEALKDAQTRITK. An ambiguity remained about the C3 alanine residue since 4 more alanines were present in the mobile region and the corresponding cross-peaks overlapped. Chemical shifts of residues 358-370 were close to those of the same residues in the MalE339 and MalE339C3 mutants. In the MalE348C3 hybrid, the first 3 or 4 N-terminal residues of C3, DNP(A), are not flexible. On the other hand, the vector completely unfolds on the C-terminal side of the insert. We can imagine that the last turn of helix XIII corresponding to the sequence NAAS is withdrawn from the helix by the insertion of C3, but is replaced by another turn formed from the DNP or DNPA sequence of the insert. As with the sequence NAAS, the sequence DNP(A) would therefore be quite motionless. Insertion accommodation of the other residues of C3 and of the NAAS sequence between helices XIII and XIV would induce the destabilization of helix XIV and its entire unfolding.
Insertion Site 363Deletion in the insertion/deletion mutant MalE363 occurs in the C-terminal region of the MalE protein and comprises the last turns of helix XIV. Insertion involves 2 residues, GS, encoded by the BamHI linker and 9 residues, ECCEMPDAA, encoded by an open reading frame of the intergenic malE-malF region due to the deletion of the stop codon of the malE gene. The inserted sequence could be reconstituted from residues identified in the spectra. The 2 sequential cysteines, not observable, are likely to be implicated in a disulfide bridge, which makes them less flexible. In MalE363C3, the segment including the flanking sequence GS, epitope C3, and the open reading frame of the intergenic region appeared to be mobile. Chemical shifts of residues implicated in that region were similar in both the insertion/deletion and hybrid proteins. The fact that no residue of the vector C-terminal region could be detected in MalE363 and in MalE363C3 indicates that the two remaining turns of helix XIV were not destabilized in either of the mutants.
Both MalE363 and MalE363C3 proteins are able to bind to an amylose column, in contrast to MalE339, MalE339C3, and MalE348C3. The MalE339 and MalE339C3 proteins lack Trp340, an amino acid crucial for the binding of maltose (29). An unfolding of their C-terminal helices XIII and XIV was shown by NMR. In MalE348C3, while helix XIII remains structured, helix XIV unfolds completely. In the MalE363 and MalE363C3 proteins, which present a deletion of the two C-terminal turns of helix XIV, helix XIII and the three first turns of helix XIV remain stable. This observation is in agreement with previous data showing that deletion of both helices XIII and XIV resulted in a loss of the maltose binding activity (5).
NMR studies of the different MalE hybrid proteins showed that,
wherever its insertion site in the MalE vector, peptide DNPASTTNKDK was
fully or mostly flexible: 3 residues (DNP) were not observed in hybrids
MalE161C3 and MalE348C3, and in all the other C3 mutants, the 11 residues were detected. This flexibility is not restricted only to the
side chains, but concerns the whole inserted fragment as spin systems
could be reconstituted from H protons up to the end of the chain.
Based on line width analysis, the C3 epitope motions are therefore at
least 10 times faster than the overall tumbling of the molecule. This
result is in agreement with x-ray data on MalE133C3. Whereas structures
of the MalE part of the hybrid protein and of MalE were essentially
similar, the C3 epitope was too mobile to be seen in the crystal
(30).
The C3 insertion sites are located within various elements of secondary
structure of the MalE protein, the -helix,
-sheet, and coiled
segment. Although on the surface, these elements are tightly packed
with the rest of the protein since no flexible regions were noticed in
the wild-type protein. Their partial or total deletion did not produced
any unpacking of the molecule, except in MalE339, in which deletion
involves parts of both C-terminal helices XIII and XIV. Insertion of
peptide C3 in place of the deleted residues or merely inside a coiled
segment (MalE285C3) or a helix (MalE348C3) destabilized the vector
protein only when the insertion site was located in helix XIII
(MalE339C3 and MalE348C3). The inserted residues thus adopt a loop
conformation in hybrid proteins MalE133C3 to MalE303C3. In hybrid
proteins MalE339C3, MalE348C3, and MalE363C3, they are included in the
flexible C-terminal part of the molecule. As shown by Martineau
et al.,1 all the hybrid proteins bind to an
anti-C3 monoclonal antibody with a highly increased antigenicity when
compared with the free peptide, except MalE339C3, which does not
present any detectable activity for the monoclonal antibody. In both
MalE339C3 and MalE348C3, the vector protein unfolds on the C-terminal
side of the insert, and in MalE363C3, the open reading frame of the
intergenic region is mobile. However, in MalE348C3 and in MalE363C3,
the C3 insert is constrained on its N-terminal side, whereas in
MalE339C3, it is totally unrestrained and likely able to adopt a range
of conformations similar to that of the free C3 peptide. This excess of
mobility would explain the lack of antigenicity of the MalE339C3
hybrid.
The flanking sequences on the C-terminal side of the insert were observed in most of the hybrids, without an obvious correlation between their composition and their intrinsic conformational freedom. The sequence GS, a most hydrophilic and flexible sequence, was indeed observed in both MalE211C3 and MalE363C3, but the sequence GIR, which was not seen in the MalE206C3 hybrid, was identified in MalE161C3 and MalE285C3. And while the sequence DP, which contains the most constrained amino acid, proline, was not detected in MalE296C3, it was partly observed in MalE133C3 and totally in MalE303C3 and MalE339C3. It should be noted, however, that in the MalE339C3 hybrid, DP is included in a flexible region. The flanking sequence on the N-terminal side of the inserted peptide was only detected in two or three proteins: hybrid MalE363C3 and possibly hybrid MalE211C3, in which this sequence was GS, and hybrid MalE339C3, for which insertion was shown to destabilize the vector protein on both sides of the insert.
Residues Asn94, Pro95, Ser97, and
Asn100 of the C3 insert were assigned in all the MalE
hybrids. These residues were represented only once in some of the
observed sequences, as in MalE161C3, and their proton chemical shifts
were so constant from one hybrid to another that they could be
unambiguously identified in the different proteins. Ala96
was attributed to hybrids MalE133C3 to MalE303C3 only because of the
overlap of its H-
H cross-peak with those of the other alanines
also observed in hybrids MalE339C3 to MalE363C3. Assignment of both
threonines was arbitrarily performed, with position 98 being given to
the one presenting the lower
H chemical shift. With this agreement,
Thr98 was assigned in all the C3 hybrids and
Thr99 in hybrids MalE133C3 to MalE303C3 only, with the
other threonines observed in these proteins presenting too similar
chemical shifts. Lys101 and Lys103, which
always merged into one another, were identified in all the hybrids.
Asp93 and Asp102 could not be assigned since
the
H and
H chemical shifts of most of the aspartic acids
observed in the spectra of the different hybrids were very close,
respectively. As shown Fig. 3, the
H chemical shifts
of the C3 residues are close to those expected for random coil residues
(28). The 4.92-4.97 ppm values observed for Asn94 indeed
correspond to the fact that
H chemical shifts of residues located
before a proline are significantly shifted downfield (31). Aspartic
acids of the flexible DP flanking sequences of hybrids MalE133C3,
MalE303C3, and MalE339C3 could be assigned for the same reason since,
due to their positions, their
H chemical shift values (4.83-4.89
ppm) highly exceeded the values determined for the other observed
aspartic acids (4.54-4.62 ppm). The C3 residue chemical shift data are
thus in agreement with the flexible loop or coiled segment conformation
suggested above. Differences observed between Thr98 and
Thr99
- and
-protons are more likely to be due to a
sequential than to a structural effect since they were observed when
the peptide was tightly maintained at both its extremities as well as
when it was freely moving with the C-terminal region of the MalE
vector.
The crystal structure of the complex between the peptide corresponding
to residues 86-103 of the VP1 protein and the Fab fragment of a
neutralizing monoclonal antibody raised against the heat-inactivated virion was recently determined at 3-Å resolution (32). Residues 93-103 corresponding to peptide C3 adopt mostly an S-shaped
conformation, with 3 residues in an extended conformation (residues
93-95) and two type I -turns in series (residues 96-103). Only
residues 96-103 directly contact the Fab fragment. Residues 96-99
(ASTT) adopt an identical conformation in the peptide and in the
corresponding region of the VP1 protein, with main chains superimposing
with a root mean square of 0.68 Å. The conformation of residues 93-95 is somewhat similar, but that of residues 100-103 is substantially different. When the Fab fragment was docked on the virus VP1 protein by
superimposition of the 4 residues ASTT in the complex and in the VP1
protein, many unfavorable interactions occurred between the Fab
fragment and the VP1 C3 loop C-terminal region (from C3 residue
Asn100). Furthermore, the docked model was not completely
consistent with the virus binding and neutralization. Wien et
al. (32) therefore proposed a two-step binding process in which
the antibody induces conformational changes in the C3 loop after
attachment to the virus, which would allow the C-terminal part of the
loop to adopt the conformation seen in the complex. When inserted in MalE at positions 133 and 303, the C3 peptide is antigenic (11). It is
detected by a polyclonal antibody as well as by a monoclonal antibody
recognizing the C3 epitope in the native virion. Insertion in most of
the other sites also produces antigenic hybrids.1 It is
likely that in these hybrids, the C3 peptide adopts a conformation similar or at least close to that present in the complex. In contrast to residues 93-95, residues 96-103, forming the real epitope, as
determined in the peptide-Fab complex structure, were found to be
flexible in all the hybrids we studied. This flexibility, often
increased in the peptide C-terminal region by that of the C-terminal
flanking sequence, would allow the C3 epitope to adapt its conformation
to that of the antibody.
The atomic coordinates for the structure of maltose-binding protein
complexed with D-maltose have been deposited in the NCBI Molecular Modeling
Database under the accession number
2789 and were previously reported by Spurlino et al. (1991).
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