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J Virol, June 1998, p. 4610-4622, Vol. 72, No. 6
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Antibody-Mediated Neutralization of Human
Rhinovirus 14 Explored by Means of Cryoelectron Microscopy and
X-Ray Crystallography of Virus-Fab Complexes
Zhiwei
Che,1
Norman H.
Olson,1
Donna
Leippe,2
Wai-ming
Lee,2
Anne G.
Mosser,2
Roland R.
Rueckert,2
Timothy S.
Baker,1 and
Thomas J.
Smith1,*
Department of Biological Sciences, Purdue
University, West Lafayette, Indiana 47907,1
and
Institute of Molecular Virology, University of
Wisconsin, Madison, Wisconsin 537062
Received 30 October 1997/Accepted 12 February 1998
 |
ABSTRACT |
The structures of three different human rhinovirus 14 (HRV14)-Fab
complexes have been explored with X-ray crystallography and
cryoelectron microscopy procedures. All three antibodies bind to the
NIm-IA site of HRV14, which is the 
-B--C loop of the viral
capsid protein VP1. Two antibodies, Fab17-IA (Fab17) and Fab12-IA
(Fab12), bind bivalently to the virion surface and strongly neutralize
viral infectivity whereas Fab1-IA (Fab1) strongly aggregates and weakly
neutralizes virions. The structures of the two classes of virion-Fab
complexes clearly differ and correlate with observed binding
neutralization differences. Fab17 and Fab12 bind in essentially identical, tangential orientations to the viral surface, which favors
bidentate binding over icosahedral twofold axes. Fab1 binds in a more
radial orientation that makes bidentate binding unlikely. Although the
binding orientations of these two antibody groups differ, nearly
identical charge interactions occur at all paratope-epitope interfaces.
Nucleotide sequence comparisons suggest that Fab17 and Fab12 are from
the same progenitor cell and that some of the differing residues
contact the south wall of the receptor binding canyon that encircles
each of the icosahedral fivefold vertices. All of the antibodies
contact a significant proportion of the canyon region and directly
overlap much of the receptor (intercellular adhesion molecule 1 [ICAM-1]) binding site. Fab1, however, does not contact the same
residues on the upper south wall (the side facing away from fivefold
axes) at the receptor binding region as do Fab12 and Fab17. All three
antibodies cause some stabilization of HRV14 against pH-induced
inactivation; thus, stabilization may be mediated by invariant contacts
with the canyon.
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INTRODUCTION |
Picornaviruses are among the largest
of animal virus families and include the well-known poliovirus,
rhinovirus, foot-and-mouth disease virus (FMDV), coxsackievirus, and
hepatitis A virus. The rhinoviruses, of which there are more than 100 serotypes subdivided into two groups, are major causative agents of the
common cold in humans (42). The viruses are nonenveloped and
have an ~300-Å-diameter protein shell that encapsidates a
single-stranded, plus-sense RNA genome of about 7,200 bases. The human
rhinovirus 14 (HRV14) capsid exhibits a pseudo-T=3 (P=3) icosahedral
symmetry and consists of 60 copies each of four viral proteins, VP1,
VP2, VP3, and VP4, with VP4 at the RNA-capsid interface
(40). An ~20-Å deep canyon lies roughly at the junction
of VP1 (forming the north rim) with VP2 and VP3 (forming the south rim)
and surrounds each of the 12 icosahedral fivefold vertices. The canyon
regions of HRV14 and HRV16, both major receptor group rhinoviruses,
were shown to contain the binding site of the cellular receptor,
intercellular adhesion molecule 1 (ICAM-1) (8, 24a, 37).
Four major neutralizing immunogenic (NIm) sites, NIm-IA, NIm-IB,
NIm-II, and NIm-III, were identified by studies of neutralization
escape mutants with monoclonal antibodies (MAbs) (46, 47)
and then mapped to four protruding regions on the viral surface
(40).
Several mechanisms of antibody-mediated neutralization have been
proposed. Perhaps the simplest is based on aggregation of virions
(5, 53, 54), which generally occurs over a narrow range of
antibody/virus ratios. This limited range has raised questions about
the role of aggregation in vivo. Alternative suggestions are that
antibodies may neutralize virions by inducing extensive conformational
changes in the capsid (15, 29), abrogate virus attachment to
the host cell (8, 14), or prevent uncoating (57).
There is no universal acceptance of a single neutralization mechanism,
and the various MAbs may neutralize with different combinations of
these mechanisms.
Neutralizing MAbs against HRV14 have been divided into three groups:
strong, intermediate, and weak neutralizers (26, 34). All
strongly neutralizing antibodies bind to the NIm-IA site, which was
defined by natural escape mutations at residues D1091 and E1095 of VP1
on the loop between the -B and -C strands of the VP1 -barrel
(the letter designates the amino acid, the first digit identifies the
viral protein, and the remaining three digits specify the sequence
number). Because strongly neutralizing antibodies form stable,
monomeric virus-antibody complexes with a maximum stoichiometry of 30 antibodies per virion, it was concluded that they bind bivalently to
the virions (26, 34). Weakly neutralizing antibodies form
unstable, monomeric complexes with HRV14 and bind with a stoichiometry
of ~60 antibodies per virion (26, 52). The remaining
antibodies, all of which precipitate the virions, are classified as
intermediate neutralizers (26, 34).
The structures of two complexes, the strongly neutralizing antibody
MAb17-IA and its Fab fragment, Fab17, bound to HRV14, were determined
by means of cryo-transmission electron microscopy (cryo-TEM) and
three-dimensional image reconstruction (51, 52) and
interpreted on the basis of model-building studies that used the atomic
structures of HRV14 (40) and Fab17 (28). These studies showed that no observable conformational changes were induced
in the viral capsid upon Fab or MAb binding. Modeling and site-directed
mutagenesis studies demonstrated that electrostatic interactions play a
key role in the binding of Fab17 to HRV14 (52). In the
complex, the loop of the NIm-IA site on HRV14 sits clamped in the cleft
between the heavy- and light-chain hypervariable regions and forms
complementary electrostatic interactions with Lys58H (on
the heavy chain) and Arg91L (on the light chain) of Fab17.
In addition, a cluster of lysines on HRV14 (K1236, K1097, and K1085)
interact with two acidic residues, Asp45H and
Asp54H, in the CDR2 (CDR stands for
complementarity-determining region) of the Fab heavy chain
(49). Earlier modeling studies also suggested that bidentate
binding of MAb17-IA to HRV14 is facilitated by rotation of the Fab
constant domains about the elbow axes towards the viral twofold axes
(51). This suggested that the flexibility of the elbow
region (the junction between the variable and constant domains) plays a
role in the bivalent binding process, which in turn increases antibody
avidity. Finally, the 4-Å-resolution crystal structure of the
Fab17-HRV14 complex clearly showed that the virion does not undergo
conformational changes upon Fab binding (49). This crystal
structure determination also revealed that the earlier docking of the
HRV14 and Fab17 atomic structures into the 22-Å cryo-TEM density map
(50) yielded a pseudo-atomic model that was very close to
the real structure of the complex.
We have expanded our complementary X-ray crystallography and cryo-TEM
microscopy studies to examine the structures of two more Fab-virus
complexes, using Fab fragments from two other NIm-IA antibodies,
MAb1-IA (MAb1) and MAb12-IA (MAb12), bound to HRV14. MAb1 and MAb12 are
weak and strong neutralizing antibodies, respectively. Image
reconstructions of these two complexes are interpreted on the basis of
pseudo-atomic models, which substantiate the previous hypothesis that
neutralizing efficacy and binding valency are interrelated
(34). Electrostatic interactions at the epitope-paratope interface are highly conserved and apparently important for the antibody binding to the virion surface. Like Fab17, Fab1 and Fab12 penetrate the canyon. There are, however, differences between the
orientations of the strongly and weakly neutralizing antibodies and in
the contacts made with the receptor binding region of the canyon.
Finally, data suggesting that antibody binding to HRV14 is alone
sufficient for neutralization and that other possible mechanisms are
not required are presented.
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MATERIALS AND METHODS |
Preparation of MAb1-IA and MAb12-IA.
MAb1-IA and MAb12-IA
were produced as previously described (52) and were found to
be immunoglobulin G1 (IgG1) and IgG2a, respectively, by using
Screentype (Boehringer Mannheim Biochemicals, Indianapolis, Ind.).
High-glucose Dulbecco's modified Eagle medium (catalog no. 430-2100;
GIBCO/Bethesda Research Laboratories, Grand Island, N.Y.) containing
10% fetal bovine serum was used for the hybridoma cell cultures grown
in the Cellmax Quad 4 cell culture system (Cellco Corp., Germantown,
Md.). Cells were removed from the culture aliquots with 10-min
centrifugations at 10,000 × g. Antibodies were
precipitated from the cellular supernatant by using a 50% (final
concentration) saturated solution of ammonium sulfate and collected
with 10-min centrifugations at 10,000 × g. The
precipitate was resuspended and dialyzed with 0.1 M sodium phosphate
(pH 7.0) buffer. Aliquots were loaded onto a protein G affinity column
(Pharmacia/LKB Corp., Piscataway, N.J.) and washed with 0.1 M sodium
phosphate (pH 7.0), and antibodies were eluted with 50 mM sodium
acetate buffer (pH 2.0). The pH of the eluant was immediately brought
back up to neutrality by collecting fractions in tubes containing 1 M
sodium phosphate (pH 9.0). The antibody samples were pooled and
dialyzed against 0.1 M sodium phosphate (pH 7.0).
Antibody neutralization plaque assays.
Two different
protocols were used to ascertain the efficacy of the antibodies on
virus neutralization prior to uncoating (method A) and the ability of
the antibodies to prevent plaque formation (method B).
(i) Method A.
Samples of purified HRV14 (at ~5 × 106 PFU/ml) were incubated with various concentrations of
purified antibodies in phosphate-buffered saline with bovine serum
albumin (PBSA) for 1 h at room temperature and then overnight at
4°C. These samples were then serially diluted in PBSA, and 200-µl
aliquots were added to monolayers of HeLa cells. After incubation for
1 h at room temperature to allow for viral attachment to the
cells, each plate was rinsed with 2.5 ml of PBSA. The monolayers were
then covered with 2.5 ml of 0.8% agar in medium P6. The hardened agar
was then covered with 2.5 ml of medium P6 supplemented with 4 mM
glutamine, 4 mM oxaloacetic acid, 2 mM pyruvate, and 0.2% glucose.
Plates were incubated in 5% CO2 for 48 h at 35°C,
and plaques were visualized by removing the overlays, staining the cell
monolayers with 0.5% crystal violet in 20% ethanol, and rinsing with
water.
(ii) Method B.
The ability of antibodies to inhibit plaque
formation was tested by maintaining a high concentration of antibodies
in the plaque assay. Serially diluted samples of HRV14 were allowed to attach to monolayers of HeLa cells for 1 h at room temperature. The monolayers were then covered with the agar and medium overlays as
described above with the exception that antibodies were added to the
overlays (~28-µg/ml final concentration) rather than being washed
away. Subsequent incubation and visualization were performed as in
method A.
Generation and purification of Fab1 and Fab12.
Fab fragments
were generated by papain cleavage at a 1:50 (wt/wt) enzyme-to-antibody
ratio for 12 h at 37°C in the presence of 30 mM
-mercaptoethanol. The reaction was quenched by adding iodoacetamide
to give a final concentration of 75 mM. After extensive dialysis (>3
changes of buffer every 8 h) against 20 mM Tris (pH 7.5), the
digested sample was purified by using a Mono-Q anion-exchange column on
a fast protein liquid chromatography system (Pharmacia/LKB). Pure Fab
fragments eluted in the void volume, whereas Fc fragments and intact
antibodies eluted at 0.1 to 0.2 M NaCl. The Fabs were pooled and
concentrated with Centricon 10 microconcentrators (Amicon Corporation,
Beverly, Mass.).
Preparation of HRV14-Fab1 and HRV14-Fab12 complexes.
Fabs
and HRV14 (prepared as previously described [16]) were
mixed at a ratio of four Fab molecules per NIm-IA site (240 Fabs per
virion). The mixture was incubated at 4°C overnight and then passed
through a Superose 6 column (Pharmacia/LKB) equilibrated with 50 mM
sodium phosphate buffer (pH 7.0) to separate the complex and the
unbound Fab molecules. Pure complexes were concentrated to ~10 mg/ml
with Centricon 10 microconcentrators (Amicon Corp.).
Cryo-TEM and image reconstructions of HRV14-Fab1 and HRV14-Fab12
complexes.
Cryo-TEM of the HRV14-Fab complexes was performed
essentially as previously described (3, 7, 36, 49).
Micrographs were recorded at a magnification of ×49,000, at ~1.2
µm for Fab1 and ~1.3 µm underfocus for Fab12, and under minimal
dose conditions (~20 e
/Å2), on an EM420
electron microscope (Philips Electronic Instruments, Mahwah, N.J.)
equipped with a 626 cryotransfer holder (Gatan, Warrendale, Pa.).
Twenty-six images of the Fab1 complexes and 41 images of the Fab12
complexes were used to calculate 3D reconstructions according to
established protocols (2, 17). Effective resolutions of 30 and 27 Å were achieved for the Fab1 and Fab12 reconstructions, respectively. The calculated eigenvalues of each data set exceeded 10.0, which indicated that random and unique data were used for each
reconstruction (11). The reconstructions were then corrected for effects of the phase-contrast transfer function as described previously (52).
Sequence determinations of Fab1 and Fab12.
The amino acid
sequences of the variable domains of Fab1 and Fab12 were derived from
cDNAs by using the Mouse Ig-Prime kit (Novagen, Madison, Wis.). Total
RNAs from MAb1 and MAb12 hybridoma cells were isolated by the rapid
GuSCN method, which is similar to conventional phenol-chloroform
extraction. cDNAs for both light chains were synthesized and amplified
by PCR with the primer pair MuIgkVL5'-G-MuIgkVL3'-1, whereas the primer
pairs MuIgVH5'-B-MuIgGVH3'-2 and
MuIgVH5'-C-MuIgGVH3'-2 were used in the
synthesis and PCR amplification of the heavy chains of Fab1 and Fab12,
respectively. The PCR products were cloned into a T-A vector (pT7BlueT)
and then transformed into competent Escherichia coli
(NovaBlue). E. coli containing plasmids with cDNA inserts
produced white colonies after the transformed competent cells were
plated onto ampicillin-X-Gal (5-bromo-4-chloro-3-indolyl--D-galactopyranoside)
plates. These plasmids were extracted and purified from the minipreps
grown out of the white colonies. Double-stranded DNA sequencing was then performed with a Sequenase version 2.0 DNA sequencing kit (United
States Biochemical, Cleveland, Ohio). Each sequence was determined from
at least three independent PCRs. The amino acid sequences were derived
from the nucleotide sequences and aligned to the Fab17 sequence
according to previously published nomenclature (23).
Fab1 crystal structure determination.
Details of the X-ray
crystallographic structure determination of Fab1 will be published
elsewhere. Briefly, Fab1 crystals were obtained by the sitting-drop
method with 18 to 22% polyethylene glycol 8000, 0.1 M sodium phosphate
buffer (pH 6.0), and 1% 2-methyl-2,4-pentanediol and an Fab1
concentration of 18 mg/ml. Crystals appeared within a day and continued
growing for a week to maximum dimensions of 0.5 to 0.7 mm. Oscillation
X-ray diffraction data were collected from two crystals, using an
R-axis imaging detector and a Rigaku X-ray generator. The oscillation
angle was 1°, and the exposure time was 10 min for each image. The
intensities were integrated and merged by using the programs DENZO and
SCALEPACK (38). The final data set extended to a 2.7-Å
resolution. The crystal belonged to space group
P21212, with unit cell dimensions of
a = 92.17, b = 135.95, and
c = 81.08 Å and two Fab molecules in the asymmetric unit. The structure was determined by the molecular replacement method
(41) with the Fab17 structure (28) as the initial
phasing model. Rotation and translation functions were calculated with a combination of X-PLOR (6) and AMORE (34a) in
the CCP4 program suite (1). The model was built by using
"O" (22), taking into account the differences in Fab17
and Fab1 sequences, and was refined with X-PLOR with all reflections in
the range of 6 to 2.7 Å. The final R factor was 16.9%
(Rfree = 26.6%), with root mean square deviations in bond
lengths and angles of 0.010 Å and 1.45°, respectively. From
Ramachandran analysis, 85.2% of the residues were in the most favored
regions and none of the residues were in disallowed regions.
Modeling of the HRV14-Fab1 complex.
Initial modeling studies
of the HRV14-Fab1 complex were performed with the program "O"
(22) by fitting the atomic structures of HRV14 and Fab1 into
the electron density map of the complex generated by cryo-TEM and image
reconstruction. The SFALL program in the CCP4 program suite
(1) was used to generate structure factors from the cryo-TEM
maps. The rigid-body refinement algorithm within X-PLOR (6)
was then used to refine the initial models against the computed
structure factors. The HRV14 structure was constrained, and only the
position and orientation of Fab1 were refined.
Effect of antibodies on acid inactivation.
Aliquots of
4 × 1010 virions were incubated with 2 × 1012 antibodies in 200 µl of PBSA at room temperature for
3 to 4 h, except for MAb3, -4, -6, and -7, whose concentrations
are unknown because they could not be purified by protein-A affinity
chromatography and precipitated upon purification by ion-exchange
chromatography. In these cases, enough antibody was added to neutralize
>99.99% of infectivity. Ten microliters of this mixture was diluted
into 490 µl of 10 mM citrate buffer containing 0.4% BSA at various pH values. After incubation at room temperature for 10 min, 50 µl of
each treated sample was diluted 10-fold into 450 µl of PBSA to
neutralize the pH. Each sample was then serially diluted with PBSA and
frozen at 
70°C to dissociate the antibodies from the virions. After
1 h or more, each diluted sample was thawed, and the surviving
infectivity was measured on HeLa cell monolayers.
Calculation of Fab-virus surface contacts.
The buried
surfaces within the Fab-virus contact interfaces were determined by
using the programs MSPDB, MS, MSSEP, and MSAV (9) and ATMSRF
(45) and a solvent probe radius of 1.7 Å. The Fab17 portion
of the complex crystal structure (49) and the Fab1 structure
from the cryo-TEM fit were used with the surface of HRV14 around the
epitope region that had been generated by using the native HRV14
structure (40) and icosahedral symmetry.
Atomic coordinates.
The atomic coordinates for Fab1-IA have
been deposited in the Brookhaven Protein Database (accession no. 1a6t).
| |
RESULTS |
Antibody neutralization properties.
Experiments were performed
to ascertain the relative neutralizations (neutralization assay method
A) and aggregation efficacies of the NIm-IA antibodies MAb17, MAb12,
and MAb1. Both MAb17 and MAb12 were highly efficacious at inhibiting
HRV14 infection, with MAb12 being slightly better than MAb17 (Fig.
1). Under optimal neutralization
conditions, both antibodies inhibited plaque initiation by about 5 orders of magnitude. However, neither antibody formed appreciable
amounts of precipitate over the same antibody/virus ratios. These
results, and previous results demonstrating a maximal antibody/virus
stoichiometry of ~30, strongly suggest that both MAb12 and MAb17
(26, 52) bind bivalently to the virion surface and that
virion aggregation cannot account for neutralization.
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FIG. 1.
Fab12 and Fab17 neutralization and precipitation
properties. (A) The abilities of MAb12 and MAb17 to inhibit plaque
formation were measured (method A) at various antibody concentrations.
(B) The abilities of the antibodies MAb12 and MAb17 to precipitate the
virions were measured over a comparable range of antibody
concentrations.
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In contrast, MAb1 only weakly inhibited plaque formation, with a
maximum inhibition of ~2 orders of magnitude and with a slight
enhancement in neutralization at intermediate antibody/virus ratios
(Fig.
2). Unlike the other two MAbs, MAb1
strongly aggregated
the virions over the same range of ratios at which
neutralization
enhancement was observed. At very high antibody/virus
ratios,
there was little precipitation but significant
(~1.5-log-unit)
neutralization. Therefore, MAb1 does not neutralize
HRV14 solely
by precipitating it, but neutralization is enhanced by
aggregation
at intermediate antibody/virus ratios. Since MAb1 strongly
aggregates
HRV14, cannot form stable, monomeric virus-antibody species,
and
binds with a maximal stoichiometry of ~60 antibodies/virion, this
antibody binds monovalently to the virion surface. It is important
to
note, however, that when antibodies are maintained in the plaque
assay
overlays (method B), all three antibodies neutralize HRV14
infectivity
with comparable efficacies. This latter result may
more accurately
represent in vivo conditions where antibodies
are not removed after the
first round of viral attachment.
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FIG. 2.
Neutralization ( ) and precipitation ( ) properties
of the NIm-IA antibodies MAb1 (strong precipitator, weak neutralizer),
MAb23 (strong precipitator, strong neutralizer), and MAb14 (strong
precipitator, weak neutralizer).
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For comparison, results for MAb23-IA (MAb23) and MAb14-IA (MAb14) are
also shown in Fig.
2. Both of these antibodies precipitate
HRV14 over a
wider range of antibody concentrations than MAb1.
Since MAb23 is also a
strong neutralizer, bivalent binding is
not a prerequisite for
efficient neutralization. This can be explained
if antibody avidity
mainly dictates neutralization efficacy and
the intrinsic affinity of
MAb23 for HRV14 is greater than that
of either MAb1 or MAb14.
Image reconstructions of strongly and weakly neutralizing
antibody-virus complexes.
The cryo-TEM structures of three
Fab-HRV14 complexes and one MAb-HRV14 complex were determined to
explore possible correlations between the orientations and locations of
antibody binding and neutralization efficacy (Fig.
3). The orientation of Fab17 on the viral
surface suggested that MAb17 would bind bivalently across icosahedral
twofold axes (Fig. 3). Bivalent binding of MAb17 was clearly
demonstrated in the subsequent image reconstruction of the MAb17-HRV14
complex (Fig. 3) (51). To test whether this binding mode is
common to other strongly neutralizing antibodies, the cryo-TEM image
reconstruction of the Fab12-HRV14 complex was determined (Fig. 3). Even
though both MAb12 and MAb17 are IgG2a antibodies from the same mouse,
it was assumed that they were unique since MAb12 is more soluble (data
not shown) and a stronger neutralizer (Fig. 1) than MAb17. Nonetheless,
the image reconstructions of the respective virus-Fab complexes
appeared to be virtually identical. Any differences in these
reconstructions were accounted for by the higher resolution of the
Fab12-HRV14 density map. As was demonstrated for the Fab17-HRV14
complex, the binding orientation of Fab12 strongly supports the
contention that MAb12 binds to virions in a bivalent manner.
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FIG. 3.
Shaded, surface representations of the cryo-TEM image
reconstructions of HRV14-Fab17, HRV14-MAb17, HRV14-Fab1, and
HRV14-Fab12. Fab17, MAb17, Fab1, and Fab12 are blue, brown, green, and
mauve, respectively, with the surface of HRV14 shown in gray.
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The cryo-TEM image reconstruction of the Fab1-HRV14 complex (Fig.
3)
clearly differs from those of the other virus-Fab complexes.
The Fab
arms of the weakly neutralizing, strongly aggregating
MAb1 bind in a
more radially directed orientation on the capsid,
and they are rotated
~25° about their long axes compared to Fab12
and Fab17. In this
orientation, the constant domains of the symmetry-related,
bound Fab1
fragments point away from each other. Unlike the case
for MAb17
(
51), rotation of the constant domain about the elbow
axis
cannot generate a bivalently bound model of MAb1. The large
separation
of neighboring Fab1 molecules and the more radial orientation
of the
constant region in Fab1 presumably favor monovalent binding.
Although
the hinge region of antibodies is known to be highly
flexible (
55,
58), the distance between icosahedral twofold-related
NIm-IA
sites is sufficiently large to cause this relatively small
difference
between the Fab17 and Fab1 binding orientations to
have a profound
effect on binding valency. A similar distance
constraint on bivalent
binding has been demonstrated for the antibody-FMDV
complex
(
20).
The HRV14 capsid surfaces in all three virus-Fab complexes appear to be
similar to that in HRV14 alone. Hence, the binding
of Fab12 or Fab1
does not induce conformational changes that can
be detected in the
cryo-TEM reconstructions. This correlates with
the results of the
determination of the crystal structure of the
HRV14-Fab17 complex at a
4-Å resolution, in which antibody-induced
conformational changes in
the viral capsid were not observed (
49).
Fitting of atomic models into the cryo-TEM density maps.
Interpretation of each virus-Fab complex is based on docking
experiments in which the atomic models of Fab17 (28) and
Fab1 (6a) were fitted into the cryo-TEM density maps of the
virus-Fab12 and virus-Fab1 complexes (Fig.
4), together with the atomic model of
HRV14 (40). The 4-Å-resolution map of the
Fab17-HRV14 crystal structure (49) guided the interpretation
of these pseudo-atomic models. The model of Fab12 was built by starting
with the Fab17-HRV14 crystal structure and then making adjustments to
account for the 10-residue difference between the Fab12 and Fab17
sequences. Each Fab model was first fit manually into the cryo-TEM map
and then refined as a rigid body by using X-PLOR.
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FIG. 4.
Pseudo-atomic fitting of different Fab models into
cryo-TEM density maps. The top panels and middle left panels show the
C- backbones of VP1, VP2, VP3, VP4, the Fab light chains (L), and
the Fab heavy chains (H). The electron density is represented by the
black lines. The RNA interior is towards the bottom of the panels, and
the nearest fivefold axis is at the left. The middle right panel shows
orientations of the bound Fab1 and Fab12 in the same view as the top
row. The bottom two panels are a stereo diagram of the Fab1 and Fab12
models with the view direction from the nearest fivefold axis towards
the nearest twofold axis. This figure was generated with the program
MOLVIEW (48) (http://bilbo.bio.purdue.edu/~tom).
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The 4-Å structure of the Fab17-HRV14 complex provided an important
means to ascertain the effectiveness of X-PLOR rigid-body
refinement.
We first tested whether the radius of convergence
of the rigid-body
refinement was sufficiently large to be effective
at the resolution of
the cryo-TEM studies. The Fab17-HRV14 model
was used to calculate
structure factors (from 200- to 25-Å resolution)
from which an
electron density map was calculated. The Fab17 model,
using the elbow
angle as determined from the crystal structure,
was then purposely
displaced halfway (~20 Å) out of the Fab density
envelope. The
rigid-body refinement process correctly moved the
model back to its
original position, with initial and final R
factors of 56 and 0%,
respectively. With the cryo-TEM-derived
structure factors, refinement
of a variety of starting models
(R factor = 60%) led to final
fits (R factor = 40%) that were
consistent with each other but
not identical to the crystal structure
of the Fab17-HRV14 complex.
Compared to the crystal structure,
X-PLOR refinement reduced the
average C-
error from 4.0 Å in
the original model to 2.1 Å. No
significant improvement was afforded
when the constant domains were
refined separately from the variable
domains. Given the success of
these tests, this X-PLOR rigid-body
refinement procedure was then used
to place the Fab1 structure
into the cryo-TEM density map of the
Fab1-HRV14 complex. All three
Fab models gave good qualitative fits to
the respective image
reconstructions (Fig.
4, top and middle, left).
The results of the atomic model fitting experiments validate the
proposed binding modes for weakly and strongly neutralizing
antibodies.
For the three NIm-IA antibodies we studied, the two
strong neutralizers
bound bivalently to the virion, whereas the
weak neutralizer bound in
an orientation that favors interparticle
cross-linking (Fig.
4,
bottom), although bidentate binding may
occur to a small extent. Thus,
these image reconstruction studies
correlate well with the proposal
that links the neutralizing efficacies
of these antibodies with their
binding modes. Previous studies
of
X174 modified with
2,4-dinitrophenol showed that bivalently
bound IgGs have a
1,000-fold-higher affinity to virions than monovalently
bound Fab
fragments (
21). Therefore, the correlation between
valency
and neutralization efficacy may be due entirely to these
avidity
differences. If this hypothesis is correct, the intrinsic
affinity of
MAb23 (Fig.
2) should be equivalent to the avidity
(bidentate binding)
of MAB17 and MAb12.
Sequences of Fab variable domains.
All three of our modeling
studies as well as the crystal structure determination for the Fab17
complex have indicated or shown that charged residues at the
capsid-Fab17 interface are determinants of binding (28, 49,
52). Asp54H and Asp56H in the CDR2 loop
of the Fab17 heavy chain contact R1094 and K1097 at the base of the
NIm-IA loop in HRV14. At the top of the NIm-IA loop, E1091 and D1095
interact with Arg91L in the CDR3 loop of the light chain.
To determine if similar coulombic interactions occur in the Fab12 and
Fab1 virion contacts, the variable domains of these antibodies were
cloned and sequenced (Fig. 5). Fab17 and
Fab12 have nearly identical sequences: the respective heavy and light
chains each differ by only five residues. Because only a few nucleotide
differences distinguish these two monoclonal antibodies and because
both hybridoma cell lines were isolated from the same mouse, the B
cells probably originated from the same mother cell prior to somatic
hypermutations. Hence, this sequence comparison cannot by itself prove
that these charge interactions are conserved among all NIm-IA
antibodies.
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FIG. 5.
Sequence comparisons between Fab17, Fab12, and Fab1
light-chain (A) and heavy-chain (B) variable domains. The numbering
scheme (23) is shown above the amino acid sequences, and the
CDR regions are noted below the sequences. Residues that are common to
Fab17 are highlighted in gray, and residues in contact with HRV14 are
outlined in boxes. The GenBank accession numbers for
Fab12-VL, Fab12-VH, Fab1-VL, and
Fab1-VH are AF045893, AF045892, AF045894, and AF045895,
respectively.
|
|
The crystal structure of the HRV14-Fab17 complex showed that several
residues in the FR1 and FR3 framework regions of the
Fab heavy chain
contact the south wall of the canyon (
49). Two
of the five
amino acid differences between the heavy chains of
Fab17 and Fab12
(32
H and 34
H) lie within the CDR1 loop. The
remaining three (68
H, 82a
H, and
76
H) are in the FR3 region, with the first two making
contact with
the south wall of the canyon (Fig.
5 and
6). It seems unlikely
that this cluster
of mutations would occur by coincidence at the
south wall interface.
Thus, these FR3 residues may contribute
to the higher neutralization
efficacy of Fab12 compared to Fab17
(Fig.
1).
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FIG. 6.
The C- backbone of the HRV14-Fab17 complex, with the
residues that differ from Fab12 in the framework (FR) and hypervariable
(CDR) regions highlighted. The orientation and program used are the
same as for Fig. 4.
|
|
Fab1, which was isolated from a different mouse than Fab17, differs
from Fab17 by 42 residues in the heavy chain and 23 residues
in the
light chain. Fab1 binds in an orientation distinct from
that of Fab17
(Fig.
4). This is also manifested in their footprints
on the viral
surface (Fig.
7), which indicate that
Fab1 contact
is more towards the west of the NIm-IA
site. However, both Fabs
contain what appear to be two key aspartic
acid residues in the
CDR2 loops of their heavy chains. In Fab1, these
Asp residues
(52
H and 53
H) lie upstream
compared to those in Fab17 (54
H and 56
H). The
crucial role of these Asp residues in the HRV14-Fab17 epitope-paratope
interactions provides evidence that a pair of charged residues
may
likewise be important in the binding of other antibodies at
the NIm-IA
site. This interpretation is further corroborated by
the effects of
site-directed mutations (see below).
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FIG. 7.
(Left) Surface diagrams of HRV14 denoting the Fab17 and
Fab1 contact regions within an icosahedral asymmetric unit. The contact
region for Fab17 was determined by using the Fab17-HRV14 crystal
structure, whereas the Fab1 contact area was determined from the
pseudo-atomic model derived from the cryo-TEM density. (Right) Stereo
views of a portion of the HRV14 van der Waals surface, with the Fab17
(upper panels) and Fab1 (lower panels) contact areas in blue and the
remainder of the viral surface in gray (made by using the program GRASP
[35rsqb;).
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|
The structure-based alignment of Fab17 and Fab1 reveals other regions
of paratope conservation. The electrostatic characters
of both paratope
surfaces are quite similar (Fig.
8). In
Fab17,
Arg91
L (which interacts with D1091 and E1095)
contributes to a positively
charged patch located in the cleft between
the heavy and light
chains. The two aspartic acid residues
(Asp54
H and Asp56
H) in the CDR2 loop of the
Fab17 heavy chain form a negatively
charged patch juxtaposed with viral
residues R1094 and K1097.
Fab1 also has a positively charged patch, but
it is comprised
of heavy-chain residues Arg50
H and
Arg95
H. The negatively charged patch is formed by the two
conserved
aspartic acid residues Asp52
H and
Asp53
H. Interestingly, the two charged patches are aligned
in Fab1 in
an orientation that is rotated counterclockwise by ~25°
compared
to that in Fab17, and this directly correlates with the
differences
in the Fab1 and Fab12 binding orientations. This agrees
with the
previous suggestions that electrostatic field interactions may
be important in NIm-IA antibody binding (
52) and with recent
calculations of electrostatic field complementarity at protein-protein
interfaces (
32).
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FIG. 8.
Electrostatic character of the Fab17 and Fab1 paratope
surfaces. The positive charge (blue) and the negative charge (red) are
mapped onto the van der Waals surface. The heavy-chain hypervariable
region is towards the bottom of the image and the light chain is
towards the top. This figure was made by using the program GRASP
(35).
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|
Interactions between HRV14 and NIm-IA antibodies.
Despite
differences in the orientation of bound Fab1 compared to those of Fab17
and Fab12, the light-chain CDR2 loops of all three antibodies contact
very little of the viral surface (Fig. 5). As the light chains of these
antibodies contact a steep surface east of the NIm-IA site, it is
difficult for them to make extensive contact. In contrast, the heavy
chain fits quite well into the canyon, thereby allowing all three
heavy-chain CDRs to contact the viral surface (Figs. 5 to 7). Such
dominance of antigen contact via the antibody heavy-chain contact has
been observed in other Fab-antigen complexes (see, e.g., reference
10) and is not unexpected in view of the inherent
genetic diversity of heavy chains compared to light chains (e.g., the D
genetic cassettes and the activation of terminal dideoxynucleotide
transferase during heavy-chain somatic recombination). In addition,
recent results with camelid antibodies have shown that antibodies
comprised of only heavy chains do occur in vivo and bind antigens
(13).
Electrostatic interactions dominate the interface between the NIm-IA
loop region and Fab1 (Table
1; Fig.
5).
E1095, one of
the two residues that define the NIm-IA site, is clamped
by the
positively charged cleft between the heavy- and light-chain
hypervariable
regions (Fig.
8). The Fab1 heavy-chain arginines
(Arg50
H and Arg95
H) have direct interactions
with E1095. The other NIm-IA residue,
D1091, lies outside this region
of positive charge. The side chain
of D1091 in the crystal structure of
Fab17-HRV14 rotates to form
interactions with the corresponding bases
in Fab17. K1097 interacts
with only one aspartic acid residue
(Asp52
H) in Fab1 but with two (Asp54
H and
Asp56
H) in Fab17. The other aspartic acid of Fab1
(Asp53
H) forms a salt bridge with K1240, which lies near
the NIm-IA loop.
R1094 is located close to the negatively charged
region. It is
quite possible that its side chain would move into this
region,
as was observed in the Fab17-HRV14 crystal structure.
Further study of HRV14 site-directed mutants, constructed previously
for our Fab17-virus complex work (
52), supports our
interpretations of the two new Fab-virus complexes and demonstrates
the
importance of electrostatic interactions in Fab binding to
the NIm-IA
site. Of the residues tested, mutation of K1097, which
makes extensive
interactions with Fab17 (
49), had the greatest
effect on the
neutralization of all NIm-IA antibodies (Table
2).
The K1097E mutation reduced NIm-IA
antibody neutralization by
10
2- to 10
4-fold.
This mutation is just as effective as a naturally occurring
escape
mutation in blocking neutralization. When an uncharged
residue (Gln)
was substituted for K1097, little to no effect was
observed except for
MAb17. The K1085E mutation affected almost
all NIm-IA antibodies by
about 10-fold, whereas the K1236E mutation
had little to no effect on
any of these antibodies. This result
agrees with the crystal structure
study of the Fab17-HRV14 complex,
in which Fab17 was observed to
contact K1085 but made very little
contact with K1236. These
mutagenesis results demonstrate that
coulombic interactions with these
viral surface lysine residues
(not identified in the initial selection
of naturally occuring
escape mutations) are very important to both
weakly and strongly
neutralizing antibodies.
Antibody-mediated stabilization of HRV14 against acid
inactivation.
The crystal structure of the Fab17-HRV14 complex
demonstrated that large conformational changes in the virion are not
required for antibodies to mediate neutralization. Thus, antibodies may achieve their effect by stabilizing virions without necessitating large
conformational changes. To test this hypothesis, HRV14 was complexed
with several antibodies, incubated in buffers at various pHs, and
examined for residual infectivity (Table
3). Interestingly, all NIm-IA antibodies
stabilized virions against acid inactivation, whereas antibodies to the
other antigenic sites did not. For NIm-IA antibodies, stabilization was
independent of binding valancy, since both aggregating MAb1, -14, and
-23) and nonaggregating (MAb3, -4, -6, -7, -17, and -20) antibodies
protected HRV14. Although binding orientation and valency differ among
these antibodies, Fab1, Fab12, and Fab17 make extensive contact with
the bottom and north side of the canyon. The NIm-IB, NIm-II, and
NIm-III sites are further from the canyon than NIm-IA, and antibodies to these sites are less likely to make extensive contact with the
canyon. Therefore, the stabilization of virions by antibodies is
probably mediated by direct contact with the canyon region, but such
stabilization is not necessary for neutralization.
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TABLE 3.
Effects of antibodies on pH inactivation of HRV14
with strong neutralizers (SN), intermediate neutralizers (IN), weak
neutralizers (WN), precipitating antibodies (P), and
nonprecipitating antibodies (NP) to all four antigenic sites
|
|
| |
DISCUSSION |
Mechanism of antibody-mediated neutralization of HRV14.
Several mechanisms for antibody-mediated neutralization of
picornaviruses have been proposed. These include aggregation, induction of conformational changes, virion stabilization, and abrogation of
cellular attachment.
(i) Aggregation.
It has been suggested that aggregation occurs
concomitantly with neutralization and that virus/antibody ratios in
vivo are conducive to aggregation (4, 5, 54). However, our
data strongly suggest that aggregation is not a major contributor to neutralization of HRV. First, antibodies that bind bivalently to
virions do not aggregate them over a wide range of antibody/virus ratios, yet such antibodies are strong neutralizers (Fig. 1). Second,
even antibodies that are strong aggregators neutralize virus at
antibody/virus concentration ratios that do not favor aggregation. The
neutralization profile for aggregating antibodies sometimes displays a
dip that is often coincident with aggregation. Hence, in such
circumstances, neutralization may be enhanced in a narrow range of
antibody/virus ratios that favors precipitation. This enhancement may
result from a decrease of independent infectious particles or from
avidity effects caused by antibodies bound bivalently, in an
interparticle manner, to the large immunocomplexes. Although aggregation probably does not play a significant role in vitro, it may
facilitate innate immunological responses via opsonization in vivo.
(ii) Stabilization.
It has also been suggested that antibodies
might neutralize virions by stabilizing the capsid (34),
which might then prevent uncoating or receptor-induced conformational
changes. All antibodies that bind to NIm-IA (aggregating and
nonaggregating) stabilize virions against acidic pH to various extents.
However, none of the non-NIm-IA antibodies that we tested cause such
stabilization, although some are efficacious neutralizers. Therefore,
these stabilization effects do not correlate well to neutralization
efficacy or binding valency. In addition, antibodies to all four sites
have been shown to block cellular attachment (8), and this
would precede any stabilization effects. Notably, all known escape
mutations map only to residues around the epitope. An escape mutation
which does not affect antibody binding but prevents neutralization has not yet been observed. If capsid stabilization-destabilization was a
major determinant of neutralization, at least some escape mutations
that abrogated these effects might be expected to arise. Analogous
distal-site resistance mutations have been found when poliovirus and
rhinovirus are grown in the presence of capsid-stabilizing antiviral
agents (19).
(iii) Conformational changes.
Antibodies and Fab fragments
cause an apparent decrease in the pI of the viral capsid concomitant
with neutralization (8, 29). This fact has been cited as
evidence that antibodies neutralize by distorting the capsid. The
crystal structure of the Fab17-HRV14 complex clearly demonstrated that
efficacious neutralization occurs in the absence of large
conformational changes. Instead, Fab17 undergoes large conformational
changes to better accommodate the epitope without inducing structural
changes in the virion (49). Even though all antibodies to
the four different antigenic sites that were tested (MAb13, -17, -21, -28, -29, -33, -34, and -35) caused apparent changes in the pI of the
capsid (8), it seems unlikely that dissimilar antibodies,
which bind to distinct epitopes, would all cause the same effect on the
capsid. Antibodies might cause conformational changes in protein
structure upon binding, but such changes would be expected to occur on
flexible portions of the viral structure. Antibody-induced
conformational changes on less flexible regions would cost significant
Gibbs free energy and would greatly affect antibody affinity.
Therefore, it seems unlikely that induction of conformational changes
contributes significantly to antibody neutralization.
(iv) Abrogation of cellular attachment.
Previous studies have
clearly demonstrated that antibodies to all four HRV14 antigenic sites
block cellular attachment (8). The three NIm-IA antibodies
that we have studied clearly bind in a manner that overlaps the ICAM
footprint as determined by cryo-TEM (37). Steric hindrance
effects can be used to explain the competition between receptor and
antibody binding. NIm-II is immediately adjacent to the ICAM binding
region, and the ~600- to 900-Å2 contact region of these
antibodies possibly overlaps the ICAM site as well. However, NIm-III is
quite distal (~40 Å away) to the receptor binding region, yet
NIm-III antibodies also compete with receptor binding (8).
Perhaps, then, antibody competition with the receptor is merely a
result of the sheer bulk of an antibody molecule (an IgG is ~140 Å long and approximately equal to the radius of HRV14) and does not
require direct overlap with the ICAM binding region. This steric model
would also explain why cellular attachment is inhibited at a
nonsaturating stoichiometry of 7 to 10 antibodies per virion (25,
52).
Summary.
Consideration of all of these results suggests that
the mechanism of HRV neutralization in vitro may be much simpler than previously envisioned: antibodies bound to the surface of HRV14 are
sufficient to block attachment of virus receptors. For poliovirus and
rhinovirus, interactions with their receptors appear to be essential
for the proper release of RNA into the cytoplasm of the host cell.
Indeed, antibody-poliovirus complexes were shown to enter cells, but
this import mode led to digested viral RNA (29). In
contrast, the picornavirus FMDV needs its receptor only to enter the
cell and not for RNA release (31), yet this virus is also
effectively neutralized by antibodies. Therefore, a simple steric
effect in which antibody binds to the virion surface and blocks
receptor attachment is sufficient to explain the neutralization behavior of many antibodies. Although some antibodies might induce secondary effects (e.g., causing conformational changes in the viral
capsid) upon binding (12, 27, 30, 60), such effects are not
required for neutralization. In addition, antibodies that induce such
secondary effects could not be exclusively selected for during B-cell
clonal expansion.
Our results clearly do not rule out the existence of antibodies that
induce changes in virion structure upon binding, just
as they do not
imply that all antibodies neutralize by abrogating
cellular attachment.
For example, the details of antibody interactions
with FMDV and
poliovirus might be expected to be quite different.
The receptor
binding region of FMDV is located on the end of a
highly mobile,
immunodominant loop. Receptor or antibodies binding
to this loop are
unlikely to transmit conformational changes to
the virion but will most
certainly affect cell attachment. In
contrast, the top of the canyon
region of poliovirus is involved
in both receptor and antibody binding
(
18,
59). For poliovirus,
therefore, some antibodies might
bind to this region and either
mimic receptor binding and cause
conformational changes or inhibit
changes in this region. Indeed,
FMDV-antibody complexes can infect
cells that have Fc receptors,
whereas poliovirus-antibody complexes
cannot (
31).
Antibodies to human immunodeficiency virus apparently
neutralize by
blocking attachment or events after uncoating, depending
on which viral
protein is targeted by the antibody (
56). Antibodies
to the
hemagglutinin of influenza virus can prevent attachment
and
replication, but antibodies to the neuraminidase only interfere
with
virus release (
24). Therefore, the effects of antibodies
on
viruses can be as diverse as the viruses.
Notably, in vivo studies have clearly shown that the types of in vitro
mechanisms that we have described may be of limited
consequence in
protecting animals from viral infections. For example,
antibodies that
are not efficacious in vitro against Sindbis virus
(
43) and
FMDV (
33) are still capable of protecting animals
from viral
challenge. Although antibodies against neuraminidase
from influenza
virus are not neutralizing, they do affect disease
progression in vivo
(
44). Therefore, the primary role of antibodies
in vivo may
be to act synergistically with other components of
the immune system.
This further implies that the design of vaccines
should focus on the
production of high-affinity antibodies rather
than on a particular in
vitro neutralization property. This has
been recently shown to be true
in the case of human immunodeficiency
virus type 1, where the occupancy
of binding sites on the virus
is the major factor in neutralization
efficacy irrespective of
the epitope specificity (
39). This
goal of eliciting high-affinity
antibodies is clearly more
straightforward than having to create
vaccines that yield antibodies
which neutralize by a particular
mechanism.
| |
ACKNOWLEDGMENTS |
We thank E. S. Chase for growing the hybridoma cells for
MAb12 and MAb1, T. J. Schmidt for helpful suggestions in the
processing of the Fab1 crystallographic data set, and Z. Zhu for help
and advice in the sequence determinations of Fab1 and Fab12.
This work was supported by grants from the National Institutes of
health (GM10704 to T.J.S. and GM33050 to T.S.B.).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biological Sciences, Lilly Hall of Life Sciences, Purdue University, West Lafayette, IN 47907-1392. Phone: (765) 494-8038. Fax: (765) 496-1189. E-mail: tom{at}bragg.bio.purdue.edu.
| |
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J Virol, June 1998, p. 4610-4622, Vol. 72, No. 6
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
