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Journal of Virology, June 2001, p. 4984-4989, Vol. 75, No. 11
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.11.4984-4989.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Kinetic Analysis of the Effect of Poliovirus
Receptor on Viral Uncoating: the Receptor as a Catalyst
Simon K.
Tsang,1
Brian M.
McDermott,2
Vincent R.
Racaniello,2 and
James M.
Hogle1,3,*
Committee on Higher Degrees in Biophysics,
Harvard University, Cambridge, Massachusetts
021381; Department of Microbiology,
Columbia University College of Physicians and Surgeons, New York, New
York 100322; and Department of
Biological Chemistry and Molecular Pharmacology, Harvard Medical
School, Boston, Massachusetts 021153
Received 2 November 2000/Accepted 6 March 2001
 |
ABSTRACT |
We examined the role of soluble poliovirus receptor on the
transition of native poliovirus (160S or N particle) to an infectious intermediate (135S or A particle). The viral receptor behaves as a
classic transition state theory catalyst, facilitating the N-to-A
conversion by lowering the activation energy for the process by 50 kcal/mol. In contrast to earlier studies which demonstrated that
capsid-binding drugs inhibit thermally mediated N-to-A conversion through entropic stabilization alone, capsid-binding drugs are shown to
inhibit receptor-mediated N-to-A conversion through a combination of
enthalpic and entropic effects.
| |
INTRODUCTION |
Poliovirus is a nonenveloped virus
of the family Picornaviridae. Picornaviruses share an
icosahedral capsid architecture consisting of 60 copies of four
proteins, VP1, VP2, VP3, and VP4. The surface of the virion is
dominated by prominent star-shaped mesas at the fivefold axes and
three-bladed propeller-like features at the threefold axes. These
surface features are separated by deep canyons encircling the fivefold
axes. These canyons are involved in many essential aspects of capsid
function. Structural studies have shown that the receptor footprints
for major group rhinoviruses (19) and poliovirus (2,
10, 27) map to the canyon. At the base of the canyon underneath
the receptor footprint, there is an entry to a long, narrow hydrophobic
pocket within the 
-barrel core of VP1. For most entero- and
rhinoviruses, crystallographic studies have revealed that this pocket
is occupied by an unidentified fatty acid-like moiety, or pocket factor
(6, 12, 17, 18, 23), which can be displaced by a family of
capsid-binding antiviral drugs (9, 22). Interestingly, the
pocket factor and the antiviral drugs can exert large-scale, global
effects on the capsid's conformational dynamics, which play a critical
role in the viral life cycle.
When poliovirus attaches to its receptor, the particle converts
irreversibly from the N (native or 160S) to the A (infectious [4]
intermediate, or 135S) conformation. In the course of this uncoating
transition, normally internal components, including VP4 and the
N-terminal extension of VP1, are externalized. Externalization of these
components has been shown to facilitate the attachment of the A
particle to liposomes in vitro (7), suggesting a mechanism for the entry of virus or viral RNA to the cell (1, 2). Transient and reversible exposure of portions of VP4 and the N terminus
of VP1 also occurs naturally at physiological temperatures (14). This "breathing" process suggests that the
particle is primed to undergo the N-to-A transition but cannot complete
the transition in the absence of a trigger, i.e., the receptor. We have
previously proposed that the receptor acts like an enzyme, accelerating
the rate of the N-to-A transition at physiological temperature by
lowering the activation energy (Ea) for the
transition. Later in the cell entry process, the A particle undergoes
further changes, which result in the release of the viral RNA and
formation of an empty particle that sediments at 80S. The trigger RNA
release is unknown. The N-to-A transition also can be induced by
exposure of the virus to detergent-solubilized receptor (8,
11) or to the soluble ectodomain of the receptor at
physiological temperature (see below), and both the N-to-A and
A-to-empty transitions can also be induced in vitro by warming in
hypotonic buffers containing millimolar levels of divalent cations
(4, 25, 26). Regardless of the mechanism used to induce
the transition, capsid-binding antiviral drugs inhibit the N-to-A
transition (3, 8, 25).
Genetic data suggest that the pocket factor normally serves to regulate
the stability of the virion (6), including regulating the
N-to-A transition (16). Direct experimental studies
demonstrate that the capsid-binding drugs inhibit both receptor- and
heat-induced N-to-A transition. In the absence of receptor, the
Ea for the N-to-A transition is very large (145 kcal/mol) and is unaffected by the presence of antiviral drugs
(25). Thus, the drugs must inhibit the N-to-A transition
via entropic stabilization of the native virion. This experimental
observation is consistent with computational modeling studies that
suggest that drug binding in the closely related rhinovirus 14 is
accompanied by an increase in the compressibility of the capsid
(20, 21, 24). Others have shown that binding of antivirals
to the rhinovirus VP1 pocket decreases the ability of the virus to
undergo breathing at room temperature (13).
In this work, we extend these studies by characterizing the effect of
soluble poliovirus receptor (sPvr) on the kinetics of the N-to-A
conversion. The results confirm the prediction that the receptor acts
much like an enzyme, demonstrating that the receptor lowers the
activation energy by approximately 50 kcal/mol. The results also
demonstrate that in the presence of receptor, drugs inhibit the
conversion by a combination of enthalpic and entropic effects.
Curiously, the Ea for receptor-mediated
conversion of a virus-drug complex with one of the drugs tested was
higher than that for the virus-drug complex in the absence of receptor. Together, the results allow us to propose a kinetic model for the
receptor-mediated N-to-A transition.
| |
MATERIALS AND METHODS |
Growth, propagation, and purification of virus.
The Mahoney
strain of type 1 poliovirus (P1/M) was grown in HeLa cells grown in
suspension and purified by differential centrifugation and CsCl density
gradient fractionation as described previously (28).
[3H]leucine-labeled P1/M was prepared as described
previously (14). Purified virus was dialyzed into
phosphate-buffered saline (PBS) and concentrated to 5 mg/ml or greater
in a microconcentrator (Microcon).
sPvr.
Purified, mammalian cell-expressed sPvr (comprising
residues 1 to 337 of the receptor's ectodomain and a C-terminal
His6 tag) was produced and purified as described previously
(15). Purified receptor was dialyzed into conversion
buffer prior to use and stored at 4°C at a working concentration of
1.25 µM.
Differential scanning calorimetry of sPvr.
One-half
milliliter of 1.25 µM sPvr in conversion buffer (10 mM HEPES, 2 mM
CaCl2, 0.1% Triton X-100, 0.1% dimethyl sulfoxide [DMSO] [pH 7.5]) was injected into a MicroCal VP-DSC
microcalorimeter. Temperature scans were done at 0.5°C/min from 25 to
80°C. Prior to loading of the sPvr sample, two conversion buffer
blank scans from 25 to 80°C were executed to stabilize the instrument
and provide a baseline.
Determination of rate constants for the N-to-A transition.
Concentrated virus stocks (11 µg) were incubated overnight at 4°C
in 20-µl volumes of conversion buffer containing either no drug, 40 µM R77975, or 40 µM R78206 (8). The mixtures were
equilibrated at room temperature for 15 min, and then the 20-µl
incubations were transferred to 1.5-µl Eppendorf tubes containing 980 µl of conversion buffer + 0.25 µM sPvr (see below) containing either no drug, 40 µM R77975, or 40 µM R78206 respectively. The
tubes and their contents had been preequilibrated to a desired temperature in a Fisher Scientific model 9100 Isotemp refrigerated circulator. The temperatures of the samples were monitored by inserting
a thermocouple probe into another 1.5-ml Eppendorf tube containing
conversion buffer only in the water bath. In general, the temperature
did not fluctuate by more than 0.1°C during any experiment.
At specific time intervals, 80-µl aliquots of the reaction mixture
were transferred to low-binding 500-µl tubes (Marsh Products) containing 50 µl of PBS+ buffer (PBS, 1% Triton X-100, 0.1% sodium dodecyl sulfate, 0.5 mg of bovine serum albumin/ml) at 4°C. The extent of conversion to the A particle was assayed by
immunoprecipitation using an A-particle-specific monoclonal antibody as
described previously (25).
The first-order rate constant for the receptor-mediated N-to-A
conversion of virus and virus-drug complexes at each temperature
was
estimated from the slope of the log of percent remaining native
virus
versus time. Data for each temperature point were collected
in
triplicate, and standard deviations were determined for the
time
points. The average value for each time point was plotted,
and a
straight line was fit to the points by linear regression.
The slopes
were calculated using Microsoft
Excel.
Sedimentation analysis of products of the poliovirus
transitions.
About 20,000 cpm of [3H]Leu-labeled
virus or virus-drug complex in the presence of 0.25 µM sPvr was
incubated at the highest temperature and longest time required to
achieve the rate constants in Table 1:
for virus in 0.1% DMSO, 37°C and 200 for virus and R78206, 45°C
for 100 s; and for virus and R77975, 43°C for 110 s. The
135S marker was generated by incubating native virus to 50°C for 2 min (4); the 80S marker was generated by incubating native
virus to 60°C for 10 min. All incubations were rapidly quenched by
addition of an equal volume of ice-cold PBS+ buffer and immediate
transfer to ice. The samples were then overlaid onto 12-ml 15 to 30%
sucrose gradients. The gradients were developed at 39,000 rpm for
2.3 h at 4°C and then fractionated from the top.
Kinetic analysis.
The Ea as for
receptor-mediated N-to-A conversion of virus and virus-drug complexes
were determined from the slopes of the Arrhenius plots, in which the
natural log of the first-order rate constant was plotted versus
1/RT. Since the temperature data were collected in
triplicate, the average values and standard deviations were plotted,
and lines were fit to the data by linear regression. The slopes were
calculated using Microsoft Excel.
| |
RESULTS AND DISCUSSION |
sPvr-mediated N-to-A transitions are first order.
To examine
the effect of sPvr on the rate constant of the N-to-A transition, virus
and virus-drug complexes were incubated at various temperatures in the
presence of 0.25 µM sPvr. At the concentrations of sPvr and virus
used in the conversions, the receptor-to-binding site ratio is
~450:1. The kinetics and thermodynamics of poliovirus-sPvr
interactions are complex. Surface plasmon resonance studies have
identified two binding modes with KDs of 0.67 and 0.11 µM at 20°C (15). The relative abundance of
high-affinity sites increases from 12% at 5°C to 46% at 20°C
(15). Interference due to the N-to-A transition precludes
determining the affinities and relative abundance of the two binding
modes at physiological temperatures. Extrapolation of the available
data suggests that the levels of receptor used in this study should be
sufficient to guarantee high occupancy of the available sites but are
probably insufficient to guarantee full occupancy (60 sites/virion).
Indeed, preliminary titrations with sPvr suggested that further
increases in the rate of conversion of virus could be achieved at
higher concentrations (data not shown). However, limitations in the
availability of sPvr preclude working at concentrations sufficient to
guarantee full occupancy and maximal rates, and with minor caveats as
noted, the implications of the results presented below are expected to be independent of changes in occupancy.
Since the working temperature range of the experiments went beyond
physiological temperatures, we first determined the heat
stability of
sPvr by differential scanning calorimetry (Fig.
1).
The rate of the scan (0.5 C/min) was
chosen such that the time
the sample spends at elevated temperature was
similar to the total
time course of the N-to-A conversion of
virus-R78206 complex at
high temperature. At this scan rate, the heat
denaturation of
sPvr begins at 43°C and peaks at 57°C. However, the
rate of thermal
denaturation is negligible at temperatures below
45°C. This observation
together with the linearity of the kinetics of
the N-to-A conversion
suggests that thermal inactivation of the
receptor is insignificant
over the entire range of temperatures used in
this study and can
be ignored.
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FIG. 1.
Differential scanning calorimetry profile of sPvR. For
details, see Materials and Methods. The bold line corresponds to sPvR
in the sample chamber; the lighter line corresponds to conversion
buffer only in the sample chamber.
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|
In the presence of receptor, the N-to-A transition obeys first-order
kinetics (Fig.
2A). When the antiviral
compounds
R77975 and
R78206 (
8) were added to the
conversion reactions at
40 µM in 0.1% DMSO, the reactions still
obeyed first-order kinetics,
but the rate constants were lower than for
the sample with virus
alone, as expected (Fig.
2B and C).
R77975 and
R78206 have
MICs of 3.061 µM and 8 nM, respectively (
8).
The observed reduction
in rate constants with respect to virus in the
absence of drug
is consistent with this ordering, because
R78206
reduces the
rate significantly more than
R77975. In all cases, the rate
at any given temperature is significantly higher than the rate
in the
absence of receptor, confirming that the receptor facilitates
the
conversion.
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FIG. 2.
Rate constant determination for receptor-mediated
transitions. The published experimental procedure
(22) was modified to include sPvR at 0.25 µM. The plots
show the natural logarithm of the concentration of unconverted
160S particle versus time. Each point is the average of three separate
experiments; bars indicate the standard deviation of the average of the
measurements. The data for the low-temperature reactions for all graphs
were truncated for the sake of clarity of the higher-temperature data.
Plots were generated using Microsoft Excel.
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|
To ensure that the precipitated counts were due to A particles and not
80S particles, aliquots from the highest temperature
and longest
incubation time for each data set were analyzed on
15 to 30% sucrose
gradients. The dominant products were A particles,
and 80S particles
were not observed even under the most extreme
conditions (Fig.
3).
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FIG. 3.
(A) Sucrose gradient analysis of virus products from
conversions. 3H-labeled P1/M (1.8 µg; ~20,000 cpm) and
0.25 µM sPvr were incubated under the most extreme conditions for
each compound tested: 0.1% DMSO, 200 s and 37°C (squares);
R77975, 110 s and 43°C (open circles); and R78206, 110 s
and 45°C (triangles). (B) Positions of 80S, 135S, and 160S markers on
equivalent gradients. The gradients were fractionated from the top.
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sPvr reduces the activation energy for the N-to-A transition.
The Arrhenius equation states that for a first-order reaction obeying
simple transition state kinetics, the rate constant for a reaction is
exponentially dependent on the temperature: k = A exp (Ea/RT), where k
is the rate constant, Ea is the activation energy, R is the gas constant (1.98 cal/mol deg), and
T is the temperature in kelvins. The preexponential factor
A is described by the relation A = (kbT/h) exp
(
S
/R), where
kb is Boltzmann's constant, h is
Planck's constant, and S is the entropy
difference between the ground state and the activated complex. Thus, a
plot of the natural logarithm of the first-order rate constant versus
1/RT should yield a line with a slope that is equivalent
to Ea and a y intercept that is
proportional to S.
In the presence of receptor, the virus and virus-drug complexes produce
linear Arrhenius plots, indicating that the first-order
rate constants
are dependent on a single exponential function
as required by simple
transition state theory (Fig.
4). The
linearity
of the Arrhenius plots is maintained over a significant range
of temperatures, suggesting that facilitation of the conversion
occurs
via a single mechanism over a wide range of temperatures.
Similar
behavior has been previously reported for the N-to-A transition
of
virus and virus-drug complexes in the absence of receptor
(
25).
The addition of sPvr reduces the
Ea of the N-to-A transition by
50 kcal/mol (95 kcal/mol for virus plus sPvr, versus 145 kcal/mol
for virus alone)
(Fig.
4 and Table
2). Increased occupancy
of
the receptor might be expected to induce a further decrease in
Ea. Thus, as predicted, the receptor is behaving
like a classic
transition state theory catalyst, accelerating the rate
of the
transition by lowering the activation barrier.
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FIG. 4.
Arrhenius plots for conversion in the presence and
absence of sPvR. The averaged values of the natural logarithm of
k from Table 1 were plotted as a function of
1/RT, so that the slope of each line is equivalent to
Ea. Solid lines correspond to data collected in
the presence of sPvR; dashed lines represent data collected in the
absence of sPvR. No drug (0.1% DMSO), R77975, and R78206 are denoted
by  ,  , and  , respectively. Temperature increases from left to
right on the chart.
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In contrast to previous studies that showed that the capsid-binding
drugs do not alter the
Ea for the thermally
mediated N-to-A
transition, both
R77975 and
R78206 significantly
elevate
the
Ea for the receptor-mediated N-to-A
transition (Fig.
4 and
Table
2). The relatively small increase in
Ea for the
R77975 complex could be attributed to
a reduction in the affinity of
the receptor for the virus-drug complex.
However, the
Ea for the
virus-R78206 complex in
the presence of receptor (290 kcal/mol)
is significantly higher than
the
Ea for the virus-R78206 complex
in the
absence of receptor, and the increase must therefore reflect
an
enthalpic contribution of drug binding to the reduction in
the rate.
Significantly, the rate of the N-to-A conversion of
the virus-R78206
complex in the presence of receptor is still
much higher than that
observed for the complex in absence of receptor.
The energy that is
driving this process forward in the presence
of receptor must therefore
also have a significant entropic component,
corresponding either to a
decrease in the entropy of the virus-R78206-receptor
complex or an
increase in the entropy of the transition
state.
Kinetic model for the receptor-mediated N-to-A conversion.
The
results presented above raise two apparent paradoxes. (i) Drug binding
has a significant effect on the Ea of the
receptor-mediated, but not the thermally mediated, N-to-A conversion.
(ii) The Ea for the N-to-A transition of the
virus-R78206 complex is actually much higher in the presence of
receptor. In the uncatalyzed (thermally mediated) conversion, there is
a single transition state, N, whose activation energy is independent
of bound drug (25) (Fig. 5A). To rationalize the
receptor-catalyzed data, we propose a more complex kinetic model (Fig.
5B), wherein receptor binding introduces additional intermediates and
alters the rate-determining step of the reaction. The model contains
three assumptions: (i) There is an activated intermediate (N*R) in
the receptor-mediated reaction pathway that includes virus, receptor,
and perhaps ligand; (ii) the transition between the initial
virus-receptor complex (NR) and the activated virus-receptor complex
(N*R; denoted by the transition state NR in Fig. 5B) is rate
limiting (at least for the drug complexes); and (iii) the drugs
significantly increase the enthalpy of activation (and thus
Ea) for this step in the reaction pathway. The
simplest model for how drugs might increase Ea
for this step is one in which the formation of activated virus-receptor complex requires a conformational adjustment that can only occur if the
drug (or pocket factor) is expelled from the pocket. The absence of the
drug (or pocket factor) would be expected to substantially reduce the
stability of the virus (16). Expulsion of the drug would
require energy, and the energy requirement would be lowest for pocket
factor, intermediate for R77975 (which is a relatively poor drug), and
highest for R78206 (which is a nanomolar inhibitor of poliovirus
replication). A recent study demonstrates that drug binding interferes
with receptor binding at low temperature (4°C) but not at room
temperature or physiological temperature, suggesting that formation of
a tight-binding complex between virus and receptor requires
enthalpically regulated conformational adjustments of the virus or
receptor (5). These conformational adjustments required
for tight binding may be related to the proposed activation of the
receptor.
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FIG. 5.
Model of the reaction pathway for the N-to-A transition.
(A) Reaction pathway for the uncatalyzed (thermally mediated)
conversion. The pathway proceeds through a single transition state,
N, whose Ea is independent of drug binding
(25). (B) Reaction pathway for the receptor-mediated
conversion. Binding of the receptor to N produces an initial virus
receptor complex, NR. The receptor-mediated reaction goes through an
intermediate, the activated virus receptor complex N*R. R77975 and
R78206 raise the Ea of the transition state for
this step, NR, such that it becomes rate limiting. The horizontal
dashed line represents the energy barrier for the uncatalyzed reaction,
which is 145 kcal/mol.
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Low resolution cryoelectron microscopy structures of the virus-receptor
complexes have been reported recently. These structures
revealed no
significant structural alterations at the resolution
of the reported
structures (~22 Å), although one of the studies
raised the
possibility that pocket factor may have been expelled
in the complex.
Because the complexes used in the structural studies
were formed at
high virus and receptor concentrations in the cold,
it is not yet clear
whether the structures represent the initial
complex or the
tight-binding complex. Further studies characterizing
the structure of
the virus-receptor complexes at higher resolution
as a function of
temperature, or the structure of virus-drug-receptor
complexes at low
temperature, may resolve these
questions.
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ACKNOWLEDGMENTS |
This work was supported by NIH grants to J.M.H. (AI20566) and to
V.R.R. (AI20017).
We acknowledge Steve Miller, Dave Filman, and other members of the
Hogle lab for valuable discussion.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biological Chemistry, and Molecular Pharmacology, Harvard Medical
School, Boston, MA 02115. Phone: (617) 432-3919. Fax: (617) 432-4360. E-mail: hogle{at}hogles.med.harvard.edu.
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Journal of Virology, June 2001, p. 4984-4989, Vol. 75, No. 11
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.11.4984-4989.2001
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Abstract
Introduction
