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Previous Article | Next Article 
Antimicrobial Agents and Chemotherapy, March 2001, p. 664-672, Vol. 45, No. 3
0066-4804/01/$04.00+0 DOI: 10.1128/AAC.45.3.664-672.2001
Cyanovirin-N, a Potent Human Immunodeficiency Virus-Inactivating
Protein, Blocks both CD4-Dependent and CD4-Independent Binding of
Soluble gp120 (sgp120) to Target Cells, Inhibits sCD4-Induced
Binding of sgp120 to Cell-Associated CXCR4, and Dissociates Bound
sgp120 from Target Cells
Toshiyuki
Mori and
Michael R.
Boyd*
Laboratory of Natural Products, Division of
Basic Sciences, National Cancer Institute-Frederick, Cancer
Research and Development Center, Frederick, Maryland 21702
Received 26 April 2000/Returned for modification 28 July
2000/Accepted 7 November 2000
 |
ABSTRACT |
Cyanovirin-N (CV-N), an 11-kDa protein originally isolated from the
cyanobacterium Nostoc ellipsosporum, potently inactivates diverse strains of human immunodeficiency virus type 1 (HIV-1), HIV-2,
simian immunodeficiency virus, and feline immunodeficiency virus. It
has been well established that the HIV surface envelope glycoprotein
gp120 is a molecular target of CV-N. We recently reported that CV-N
impaired the binding of virion-associated gp120 to cell-associated CD4
and that CV-N preferentially inhibited binding of the
glycosylation-dependent neutralizing monoclonal antibody 2G12 to gp120.
However, CV-N did not interfere with the interactions of soluble CD4
(sCD4) with either soluble gp120 (sgp120) or virion-associated gp120.
In the present study, we have evaluated the effects of CV-N on the
binding of sgp120 to cell-associated CD4 to clarify the experimental
basis of the previous binding results, and we further address the
detailed mechanism of action of CV-N. Here we present evidence that (i)
CV-N impairs both CD4-dependent and CD4-independent binding of sgp120
to the target cells, (ii) CV-N blocks the sCD4-induced binding of
sgp120 with cell-associated coreceptor CXCR4, and (iii) CV-N
dissociates bound sgp120 from target cells. The results illustrate that
the measured effects of CV-N on gp120-CD4 binding interactions depend
upon the type of CD4 (soluble or cell associated), but not upon the
type of gp120 (soluble or virion associated), employed in the
experimental protocol. In addition, this study reinforces that CV-N
acts uniquely to prevent essential interactions between the envelope
glycoprotein and target cell receptors and further supports the
potential broad utility of CV-N as a microbicide to prevent the
transmission of HIV and AIDS.
| |
INTRODUCTION |
Cyanovirin-N (CV-N) is a potent
human immunodeficiency virus (HIV)-inactivating, 11-kDa protein
originally isolated from an aqueous extract of the cyanobacterium
Nostoc ellipsosporum (6, 14). Recombinant CV-N
that is indistinguishable from natural CV-N has subsequently been
produced in Escherichia coli (27). In contrast
to soluble CD4 (sCD4) and most known neutralizing antibodies against
the HIV envelope glycoprotein gp120, CV-N exerts broad virucidal
activity, at low nanomolar concentrations, against both primary
isolates and laboratory-adapted strains of primate immunodeficiency
retroviruses. These include both T-lymphocyte-tropic, macrophage-tropic
and dual-tropic primary clinical isolates of HIV type 1 (HIV-1), as
well as laboratory-adapted strains of HIV-1, HIV-2, simian
immunodeficiency virus, and feline immunodeficiency virus (6,
10). High concentrations (e.g., 9,000 nM) of CV-N are not lethal
to cell cultures. CV-N is extremely resistant to physicochemical
degradation and can withstand treatment with denaturants, detergents,
organic solvents, multiple freeze-thaw cycles, and heat (up to 100°C)
with no apparent loss of antiviral activity (6). Both the
nuclear magnetic resonance solution structure and the corresponding
X-ray crystallographic analysis of recombinant CV-N have been
published, revealing a largely 
-sheet protein with twofold
pseudosymmetry (5, 38). These unique characteristics of
CV-N have encouraged ongoing development of this protein as an anti-HIV
microbicide, particularly to prevent sexual transmission of HIV
(6, 13). CV-N may also have therapeutic applications. For
example, to explore one such approach, we have successfully demonstrated the feasibility of using CV-N as a gp120-targeting entity
coupled to a cytotoxin (Pseudomonas exotoxin) to produce a
conjugate molecule capable of selectively killing HIV-infected gp120-expressing cells (26).
Previous results have indicated that CV-N binds with extremely high
avidity to the viral envelope glycoprotein gp120, an interaction essential to its anti-HIV activity (6, 25). Other
experiments indicated that CV-N did not visibly disrupt the virion
ultrastructure (20). Mapping studies with sCD4 and a
series of monoclonal antibodies (MAbs) to defined epitopes on the
envelope glycoprotein indicated that the CV-N-binding site(s) on gp120
differed from the primary CD4-binding site, sCD4-induced epitopes, V3
loop, or other domains on gp120 recognized by these reagents (6,
13). However, CV-N apparently bound to gp120 in a manner that
occluded or altered the binding site(s) of MAb 2G12 (13),
which recognizes a conformational glycosylation-dependent epitope
(18, 33, 37). Reciprocal cross-blocking studies showed
further that MAb 2G12 pretreatment did not prevent subsequent CV-N
binding to sgp120 (13). Thus, CV-N and MAb 2G12 bind to
gp120 similarly but not identically.
Previous reports have raised some apparent ambiguities about the
experimental effects of CV-N on the binding of gp120 to CD4. Enzyme-linked immunosorbent assay studies showed that prebinding of
virus-free, soluble gp120 (sgp120) to cell-free sCD4 did not block the
subsequent binding of CV-N with the sgp120; furthermore, pretreatment
of sgp120 with CV-N did not inhibit binding of the sgp120 to sCD4
(6). Other studies indicated that CV-N treatment of
virion-associated gp120 likewise did not block subsequent binding of
the gp120 to sCD4 (13, 20). Moreover, binding of CV-N to virion-associated gp120 did not detectably affect subsequent
sCD4-induced conformational changes in the envelope glycoprotein
(13). These results initially suggested that CV-N acts
primarily at a post-CD4 step but prior to completion of fusion and
viral entry (6, 20). However, other experiments described
by Esser et al. indicated that CV-N inhibited CD4-dependent binding of
HIV-1 virions to target cells (13), reflecting CV-N
impairment of virion-associated gp120 binding to cell-associated CD4.
Most recently, Dey et al. (10) have presented evidence
that CV-N prevents binding of sgp120 to cell-associated CD4, as well as
subsequent interaction of sCD4-activated Env with the coreceptor CCR5.
To resolve the aforementioned apparent ambiguities and to further
advance the understanding of the effects of CV-N on the interaction
between gp120 and its cellular receptors, we present herein further
investigations of the effects of CV-N on (i) CD4-dependent and
CD4-independent binding of sgp120 to the target cells and (ii) the
interaction of sCD4-activated gp120 with the coreceptor CXCR4 (post-CD4
binding steps), using coimmunoprecipitation and flow cytometry
analyses. In addition, we have observed a remarkable ability of CV-N to
dissociate sgp120 from the target cells. These data clarify that the
experimental effects of CV-N on gp120-CD4 binding interactions depend
upon the type of CD4 (soluble or membrane associated), but not upon the
type of gp120 (soluble or virion associated), employed in the
experimental protocol.
| |
MATERIALS AND METHODS |
Cell lines.
The CEM-SS cell line was obtained from the
American Type Culture Collection, Manassas, Va. The A2.01 and A3.01
cell lines were provided by M. Esser (Science Applications
International Corporation, NCI-Frederick). All cell lines were
mycoplasma negative (PCR Mycoplasma Detection Kit, American Type
Culture Collection) and were cultured in complete medium (RPMI 1640 with 10% heat-inactivated fetal bovine serum, 2 mM
L-glutamine, and 10 µg of gentamicin per ml).
Proteins and antibodies.
Purified CV-N, recombinantly
expressed in E. coli, was prepared as described elsewhere
(27). Full-length recombinant sgp120 glycoprotein of
HIV-1IIIB produced in baculovirus was obtained from
Intracel (Issaquah, Wash.). Recombinant sCD4 (amino acids 1 to 369)
(1) was obtained through the AIDS Research and Reference Reagent Program, Division of AIDS, National Institute of Allergy and
Infectious Diseases, National Institutes of Health (contributor; R. Sweet). Fluorescein isothiocyanate (FITC)-conjugated mouse anti-gp120
MAb, raised against the recombinant gp120, and phycoerythrin (PE)-conjugated anti-OKT4 MAb were obtained from Intracel and Ortho
Diagnostics (Raritan, N.J.), respectively. Unconjugated and peridinin
chlorophyll protein (PerCP)-conjugated anti-Leu3a MAbs were obtained
from Becton Dickinson Immunocytometry Systems (San Jose, Calif.). The
following anti-gp120 MAbs were obtained through the AIDS Research and
Reference Reagent Program: HIV-1 gp120 MAb 2G12 (7, 33),
immunoglobulin G1 (IgG1) b12 (3, 8, 9, 30), and 4.8D
(23, 31) from (H. Katinger, D. Burton and C. Barbas, and
J. Robinson, respectively).
Coimmunoprecipitation assay.
A coimmunoprecipitation assay
was performed using modifications to a previously reported assay format
(19). CEM-SS cells were washed three times with ice-cold
phosphate-buffered saline (PBS) to remove any contaminating proteins by
centrifugation at 400 × g for 5 min. The washed cells
were suspended in complete medium (2.5 × 107
cells/0.5 ml/condition). A 1.2 µM concentration of sgp120 was preincubated with PBS (mock treatment) or different concentration of
CV-N (0.12 to 60 µM) in a total volume of 35 µl of PBS for 1 h at
room temperature. Free CV-N was removed by ultrafiltration, using a
centrifugal filtration device with a 50-kDa-cutoff membrane (Microcon
50, Amicon, Beverly, Mass.). Cells were then incubated with the protein
mixture at 37°C for 2 h in a CO2 incubator with shaking every 20 to 30 min. The cells were washed twice with ice-cold PBS and lysed in buffer containing 1% Brij 97, 150 mM NaCl, 20 mM
Tris-HCl (pH 8.0), 5 mM iodoacetamide, 1 mM phenylmethylsulfonyl fluoride, and 4 µM leupeptin. After 20 min on ice, nuclei were pelleted by centrifugation at 13,000 × g for 5 min.
The lysates were immunoprecipitated with anti-OKT4 MAb and 50 µl of
protein G-Sepharose beads (diluted 1:2 in PBS) at 4°C overnight. The
beads were washed five times with lysis buffer and boiled for 5 min with 25 µl of 2× sodium dodecyl sulfate sample buffer. Samples (from
2.5 × 107 cells per lane) were run on a 10% Tris-glycine
gel with sodium dodecyl sulfate-polyacrylamide gel electrophoresis and
were electrophoretically transferred to nitrocellulose membranes.
Membranes were blocked with Tris-buffered saline (pH 7.4) containing
0.1% Tween 20 and 5% skim milk and were incubated with anti-gp120
polyclonal rabbit serum (Intracel) or anti-OKT4 MAb. After three washes
with buffer (Tris-buffered saline containing 0.1% Tween 20), the
membranes were incubated with anti-rabbit or anti-mouse
antibody-conjugated horseradish peroxidase in blocking buffer for 30 min. After being washed, the blots were incubated with SuperSignal
substrate (Pierce Chemical Co., Rockford, Ill.) for 1 min and exposed
to film.
For the experiments represented in Fig. 5A, CEM-SS cells (2.5 × 107 cells/condition) were incubated with untreated sgp120
(final concentration, 84 nM) in a total of 500 µl of complete medium at 37°C for 1.5 h in a CO2 incubator. After being
washed twice, the treated cells were subsequently incubated with CV-N
(final concentration 840 nM) or PBS (mock treatment) in a total of 500 µl of complete medium at 37°C for 1.5 h in a CO2
incubator and washed twice with ice-cold PBS. The lysis,
coprecipitation, and detection were performed as described above.
Flow cytometric assay of binding of sgp120 and cell-associated
CD4.
For the experiments represented in Fig. 2 and 3, an
immunofluorescence flow cytometry-based, sgp120-binding assay was
performed, using modifications to a previously reported assay format
(13, 34). The CEM-SS cell line expressing CD4, CXCR4, and
CCR5 or A3.01 cells expressing CD4 and CXCR4 (2 × 105
cells per condition) were preincubated at 4°C for 30 min with either blocking buffer (PBS with 1% bovine serum albumin, 1% fetal bovine serum, and 0.02% sodium azide) or 33 nM unlabeled anti-Leu3a MAb in blocking buffer and then washed twice with blocking buffer. A
sample containing 167 nM sgp120 was preincubated with PBS (mock treatment) or different concentration of CV-N (66.8 to 534.4 nM) in a
total volume of 50 µl of PBS for 30 min at room temperature. Free
CV-N was removed as described above. Cells were then incubated with the
protein mixture in a total volume of 50 µl of washing buffer (PBS
with 1% fetal bovine serum and 0.02% sodium azide) at 37°C for 30 min and washed twice with blocking buffer. Immunofluorescent staining
was performed (4°C for 30 min) using FITC-conjugated anti-gp120 MAb,
PE-conjugated anti-OKT4 MAb, and PerCP-conjugated anti-Leu3a MAb. A
competitive enzyme-linked immunosorbent assay study confirmed that CV-N
did not occlude the epitope recognized by the anti-gp120 MAb (data not
shown). Following antibody staining, cells were washed twice with
washing buffer prior to analysis on a FACScan flow cytometer, using
CellQuest software (Becton Dickinson Immunocytometry Systems). Cells
were gated by forward and 90° light scatter, and at least 10,000 events were acquired for each sample.
To evaluate whether or not CV-N could dissociate the binding between
sgp120 and cell-expressed CD4, CEM-SS cells (2 × 105
per condition) were preincubated with sgp120 (final concentration, 167 nM) in a total volume of 50 µl of washing buffer at 37°C for 30 min; the pretreated cells were washed twice with blocking buffer. Subsequently, the cells were incubated in 668 nM CV-N, 2G12 MAb, or
IgG1 b12 MAb in a total volume of 50 µl of washing buffer at 37°C
for different durations and washed twice with blocking buffer. Immunofluorescent staining and analysis by flow cytometry were performed as described above.
Flow cytometric assay of sCD4-induced binding of sgp120 and
cell-associated CXCR4.
For the experiments represented in Fig. 4,
A2.01 cells (2 × 105 per condition), expressing CXCR4
but not CD4, were preincubated at 4°C for 30 min with blocking
buffer. For Fig. 4B, C, and D, 278 nM sgp120 was preincubated with PBS
(mock treatment), 1112 nM, CV-N, and 1,112 nM sCD4 respectively, in a
total volume of 60 µl of PBS for 30 min at room temperature. For Fig.
4E, 278 nM sgp120 was first preincubated with 1,112 nM CV-N for 30 min at room temperature and then activated by incubation with 1,112 nM sCD4
for 30 min at room temperature. For Fig. 4F, 278 nM sgp120 was first
activated by 1,112 nM sCD4 and then incubated with 1,112 nM CV-N. Free
CV-N was removed as described above. Cells were then incubated with the
protein mixture in a total volume of 50 µl of washing buffer at
37°C for 30 min and washed twice with blocking buffer.
Immunofluorescent staining was performed (4°C for 30 min) using
FITC-conjugated anti-gp120 MAb. Following antibody staining, cells were
analyzed as described above.
| |
RESULTS |
CV-N impairs sgp120 binding to CD4-expressing cells.
To
further understand the mechanism of CV-N inhibition of HIV-1
envelope-mediated binding and infection, we examined the effects of
CV-N on sgp120 binding to CD4-expressing cells. The sgp120 of
HIV-1IIIB (T-cell-line-tropic, X4, syncytium-inducing
phenotype) (see references 4 and 24 for reviews) was
utilized. CEM-SS cells expressing CD4, CXCR4, and CCR5 were incubated
with sgp120, centrifuged, and washed; cell-associated sgp120 was
detected by coimmunoprecipitation assay. It is well established that
sgp120 of HIV-1IIIB interacts with CXCR4 but not CCR5
coreceptor (11, 17). As shown in Fig.
1A, cell-associated, CD4-bound sgp120 was
coprecipitated (lane 1). When coprecipitated sgp120 was detected by
anti-gp120 polyclonal serum, additional background bands were commonly
seen after immunoprecipitation with anti-OKT4 MAb. Pretreatment of
sgp120 with CV-N clearly blocked binding of the sgp120 to
cell-associated CD4 in a concentration-dependent manner (Fig. 1A, lanes
2 to 8). When the pretreatment molar ratio of sgp120 to CV-N was 1 to
2.5, sgp120 binding to cell-associated CD4 was completely inhibited, indicating that more than one molecule of CV-N per sgp120 molecule was
necessary to fully block CD4-dependent sgp120 binding to target cells.
CD4 was consistently precipitated regardless of treatment with sgp120
and CV-N (Fig. 1B).
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FIG. 1.
Effect of CV-N on binding of sgp120 to cell-associated
CD4. Binding of CV-N-treated sgp120 to cell-associated CD4 was
determined by coimmunoprecipitation using anti-OKT4 MAb (see Materials
and Methods). (A) Detection of sgp120 by anti-gp120 polyclonal serum.
(B) Detection of CD4 by anti-OKT4 MAb. Lanes 1, mock-treated sgp120;
lanes 2 to 8, sgp120 preincubated with different concentration of CV-N;
lanes 9, no sgp120 and no CV-N. The indicated molar ratio represents
that of sgp120 to CV-N when those proteins were preincubataed. Numbers
at the right indicate positions of molecular mass markers.
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To confirm these results, we utilized a flow cytometry-based,
sgp120-binding assay using CEM-SS cells. The CEM-SS cell line expresses
CD4, as demonstrated by the staining of both anti-Leu3a (Fig.
2B) and anti-OKT4 (Fig.
2C) MAbs. After incubation of CEM-SS cells with sgp120, the cells were
stained by anti-gp120 MAb-FITC (Fig. 2 A), with a concomitant decrease
in the availability of the Leu3a epitope (gp120-binding site [2])
(Fig. 2B) but with little change in OKT4 (non-gp120-binding epitope)
staining (Fig. 2C), all consistent with CD4-dependent sgp120 binding to
the target cells. Preincubation of CEM-SS cells with unlabeled
anti-Leu3a MAb inhibited acquisition of approximately 74% of the
anti-gp120 MAb-FITC signal (Fig. 2A), indicating that approximately
74% of sgp120 binding detected by acquisition of sgp120 staining was CD4 dependent while the remaining 26% of the binding was CD4
independent. This observation was consistent with the evidence
previously reported by Hoffman et al., in which sgp120 of
HIV-1IIIB could interact with CXCR4 independently of CD4
but this binding was markedly enhanced by the previous interaction of
envelope with sCD4 (17). Pretreatment of sgp120 with CV-N
(molar ratio of sgp120 to CV-N, 1:2.4) substantially inhibited overall
sgp120 binding as assessed by acquisition of anti-gp120 MAb-FITC
signal (Fig. 2A). Importantly, there was little or no significant
decrease in the anti-Leu3a MAb signal when CV-N-treated sgp120 was
added to the cells (Fig. 2B), indicating that CV-N completely blocked
CD4-dependent sgp120 binding. Binding of CV-N-treated sgp120 to
anti-Leu3a-pretreated cells was much lower than binding of native
sgp120 to anti-Leu3a MAb-pretreated cells (Fig. 2B). The additive
inhibitory effect suggests that CV-N treatment of sgp120 inhibited
CD4-independent binding of sgp120 to cells, as well as CD4-dependent
binding. Using the A3.01 cell line expressing CD4 and CXCR4, but not
CCR5, we obtained essentially the same results described above (data not shown).
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FIG. 2.
Binding of sgp120 to CEM-SS cells demonstrated by flow
cytometry. CEM-SS (CD4-, CXCR4-, and CCR5-positive) cells were either
mock treated or treated with unlabeled anti-Leu3a MAb for 30 min at
4°C and washed twice before addition of sgp120 that was either mock
treated or treated with CV-N (molar ratio of sgp120 to CV-N, 1 to 2.4).
The sgp120 was added to CEM-SS cells, and the binding was determined
from the sgp120 signal using flow cytometry, where anti-gp120 MAb-FITC
acquisition indicates overall sgp120 binding, and by anti-Leu3a
MAb-PerCP staining, where loss of availability of the Leu3a epitope is
an indirect indication of CD4-dependent sgp120 binding. (A) sgp120
signal. CEM-SS cells are sgp120 negative (black trace). Addition of
untreated sgp120 results in acquisition of anti-gp120 MAb-FITC
staining (compare black and blue traces). CV-N treatment of sgp120 inhibits overall sgp120 binding (compare
blue and red traces). Approximately 74% of overall sgp120 binding is
CD4 dependent (compare green and blue traces). MFI values for untreated
sgp120: binding to untreated cells, 100.3, binding to unlabeled
anti-Leu3a MAb-pretreated cells 30.1. CV-N inhibits CD4-dependent and
CD4-independent binding of sgp120; note the increased inhibition of
sgp120 binding for CV-N-treated sgp120 on unlabeled anti-Leu3a
MAb-pretreated cells (compare green and orange traces). (B) Leu3a
signal (gp120-binding epitope on CD4). CEM-SS cells express the Leu3a
epitope on CD4 (black trace), and saturating unlabeled anti-Leu3a MAb
pretreatment blocks binding of anti-Leu3a MAb-PerCP (compare green and
black traces). Binding of sgp120 blocks the Leu3a epitope (compare
black and blue traces). Cells incubated with CV-N-treated sgp120 have
availability of Leu3a epitopes comparable to that of those incubated
with untreated sgp120 (compare red and black traces). (C) OKT4 signal
(non-gp120-binding epitope on CD4). Neither sgp120 nor CV-N interferes
with the level of CD4 or the availability of the OKT4 epitope. At least
10,000 events were acquired for each sample.
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The aforementioned results perhaps are better appreciated in Fig.
3, which graphically summarizes data for
sgp120 binding based on measurements of mean fluorescence intensity
(MFI) of staining for positive cells in the experiments described above in the absence or presence of unlabeled anti-Leu3a MAb pretreatment of
CEM-SS cells. When the molar ratio of sgp120 to CV-N was 1 to 
2.4,
CV-N inhibited acquisition of anti-gp120 MAb-FITC signal, reflective
of CV-N blocking both the overall sgp120 binding and CD4-independent
sgp120 binding (sgp120 binding in the presence of unlabeled anti-Leu3a
MAb) to the target cells (Fig. 3A). CD4-dependent sgp120 binding was
calculated by subtracting the MFI for CD4-independent sgp120 binding
from that for overall sgp120 binding. As shown in Fig. 3B, CV-N
inhibited CD4-dependent sgp120 binding, as well as CD4-independent
binding of sgp120 to the target cells. This was paralleled by an
increase in the availability of the Leu3a epitope, reflecting a
decrease in the blockade of the epitope associated with CD4-dependent
binding of sgp120 to target cells (Fig. 3C). Treatment of sgp120 with
CV-N thus blocks CD4-dependent binding of sgp120 to target cells.
Binding of neither native sgp120 nor CV-N-treated sgp120 interfered
with detection of the OKT4 epitope on CEM-SS cells (no
concentration-dependent inhibition) (Fig. 3D), revealing that bound
sgp120 was not masking this epitope or inducing CD4 degradation or
endocytosis. Thus, at a molar ratio of sgp120 to CV-N of 1 to 2.4 or
more, CD4-dependent sgp120 binding to the target cells was completely
inhibited by CV-N, confirming the results in Fig. 1; likewise, CV-N
nearly completely blocked CD4-independent sgp120 binding to the target
cells.
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FIG. 3.
CV-N concentration-dependent effects on sgp120 binding.
CEM-SS cells were either mock treated with PBS or treated with
unlabeled anti-Leu3a MAb for 30 min at 4°C and washed twice before
addition of sgp120 that was either mock-treated or treated with CV-N at
various concentrations. The indicated ratio represents the molar ratio
of sgp120 to CV-N when those proteins were preincubated. Each data
point represents at least 10,000 acquired events. (A) Percentage of
overall and CD4-independent sgp120 binding. The MFI value for untreated
cells with sgp120 (100.3) was considered 100%, that for untreated
cells without sgp120 (5.0) was considered 0%. (B) Percentage of
CD4-dependent sgp120 binding, calculated by subtracting the MFI for
CD4-independent sgp120 binding (sgp120 binding in the presence of
unlabeled anti-Leu3a MAb) from that for overall sgp120 binding, with
100% binding equal to sgp120 binding in the absence of CV-N. (C)
Percentage of Leu3a epitope availability. The MFI value for untreated
cells with anti-Leu3a MAb-perCP (137.4) was considered 100%, that for
untreated cells without anti-Leu3a MAb-PerCP (5.2) was considered 0%.
(D) percentage of OKT4 epitope availability. The MFI value for
untreated cells with anti-OKT4 MAb-PE (630.3) was considered 100%,
that for untreated cells without anti-OKT4 MAb-PE (3.7) was considered
0%. In panels A, C, and D, closed circles and open circles represent
untreated samples and unlabeled anti-Leu3a MAb-pretreated samples,
respectively.
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CV-N blocks direct sgp120 binding, as well as sCD4-induced binding
of sgp120, to the cell-associated CXCR4 coreceptor.
Binding of the
HIV-1 envelope protein to CD4 induces structural alterations in the
gp120 subunit that enables it to interact with an appropriate
coreceptor (15, 19, 32, 36). Since CV-N did not detectably
affect the binding of sCD4 to sgp120 or virions, or subsequent
sCD4-induced conformational changes in the envelope glycoprotein
(6, 13, 20), we investigated the effects of CV-N on the
interaction of sCD4-activated sgp120 with the target cells coreceptor,
CXCR4. We tested binding of HIV-1IIIB sgp120 to A2.01
cells, expressing CXCR4 but not CD4, in a flow cytometric binding study
(Fig. 4). In agreement with previous
observations (11, 17), the sgp120 itself very modestly bound to the CXCR4-positive, CD4-negative cells (Fig. 4B) (MFI value of
16.9, compared with blank MFI value of 8.0), but sgp120 preincubated
with sCD4 was well bound to the CXCR4-expressing cells (Fig. 4C) (MFI
value of 29.4) as a result of sCD4-induced conformational change of
sgp120. Preincubation of sgp120 with CV-N apparently inhibited
its modest binding to the cells (Fig. 4D) (MFI value of 7.7). The
sCD4-induced binding of sgp120 to the CXCR4-expressing cells was
also completely blocked by the CV-N treatment of sgp120 before and
after sCD4 activation (Fig. 4E and F) (MFI values of 8.6 and 7.8, respectively), indicating that CV-N possesses blocking activity at the
level of sCD4-activated sgp120 interaction with coreceptor, in addition
to the sgp120 interaction with cell-associated CD4.
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FIG. 4.
Inhibition of sgp120 and sCD4-induced sgp120 binding to
the target cell coreceptor CXCR4 by CV-N. Binding of CV-N-treated
sgp120 to A2.01 cells (CD4 negative, CXCR4 positive) upon
activation by sCD4 was determined by a flow cytometry-based
sgp120-binding assay (see Materials and Methods). Incubation of the
cells with sgp120 results in acquisition of anti-gp120 MAb-FITC
staining. (A) Background (A2.01 cells without sgp120, CV-N, and
sCD4). MFI value, 8.0. (B) Effects when sgp120 was used as positive
control. MFI value, 16.9. (C and D) Effects when sgp120 was
preincubated with sCD4(C) and CV-N (D). MFI values, 29.4 (C) and 7.7 (D). (E) Effects when sgp120 was first preincubated with CV-N and then
activated by incubation with sCD4. MFI values, 8.6. (F) sgp120 was
first activated by sCD4 and then incubated with CV-N. MFI value, 7.8. The molar ratios of sgp120 to CV-N and sCD4 are 1 to 4 and 4, respectively, in the final mixtures. At least 10,000 events were
acquired for each sample.
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CV-N dissociates the interaction between sgp120 and cell-associated
CD4.
Finally, we investigated whether CV-N could dissociate sgp120
from the target cells. Following incubation of CEM-SS cells with
untreated sgp120, the cells were centrifuged, washed, and subsequently
incubated with CV-N and washed again; CD4-bound sgp120 was detected by
coimmunoprecipitation analysis as before. As shown in Fig.
5A, CV-N dissociated the interaction
between sgp120 and cell-associated CD4 nearly completely. To further
characterize this unique dissociative activity of CV-N, we utilized a
flow cytometric analysis (Fig. 5B). CEM-SS cells were either mock
treated or treated with unlabeled anti-Leu3a MAb for 30 min at 4°C
and washed twice before addition of sgp120. After incubation for 30 min
at 37°C and washing twice, sgp120-treated cells were either mock treated or treated with CV-N (molar ratio of sgp120 to CV-N, 1 to
4). As shown in Fig. 5B, addition of sgp120 resulted in acquisition of
anti-gp120 MAb-FITC staining (compare black and blue traces). CV-N
treatment of sgp120 bound cells caused a substantial overall dissociation of sgp120 from cells (compare blue and red traces). The
increased dissociation of sgp120 from unlabeled anti-Leu3a MAb-pretreated cells by posttreatment with CV-N (compare green and orange traces) indicated that CV-N detached the gp120,
whether CD4-dependently or CD4-independently bound, from the
cells. This unique activity of CV-N was manifest very rapidly (less
than 2.5 min) after incubation of sgp120-bound cells with CV-N (data
not shown). Moreover, neither 2G12 MAb nor IgG1 b12 MAb, which binds to
the CD4-binding site on gp120, showed any such dissociative activity
(data not shown).
View larger version (59K):
[in this window]
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|
FIG. 5.
CV-N induces sgp120 dissociation from cell-associated
CD4. (A) Effects when CEM-SS cells pretreated with sgp120 were either
mock-treated with PBS (lane 1) or treated with CV-N (lane 2) for
1.5 h at 37°C in a CO2 incubator and washed twice
before coimmunoprecipitation using anti-OKT4 MAb as described in
Materials and Methods (molar ratio of sgp120 to CV-N, 1 to 100).
Anti-gp120 polyclonal serum and anti-OKT4 MAb were used for the
detection of sgp120 and CD4, respectively. Numbers at right indicate
positions of molecular mass markers. (B) Effect of CV-N on sgp120
dissociation from cell-associated CD4. A flow cytometric analysis was
utilized as described in Materials and Methods. The MFI values of
untreated cells (black trace), sgp120-bound untreated cells (blue
trace), CV-N-treated-sgp120-bound untreated cells (red trace),
sgp120-bound unlabeled anti-Leu3a MAb-pretreated cells (green trace),
and CV-N-treated sgp120-bound unlabeled anti-Leu3a MAb-pretreated cells
(orange trace) are 4.5, 80.7, 17.1, 32.0, and 12.2, respectively. Each
data point represents at least 10,000 acquired events.
|
|
| |
DISCUSSION |
Previous studies assessing the mechanism of action of CV-N
on gp120-mediated binding to CD4 have yielded some contrasting results.
Experiments with cell-free CD4 (sCD4) indicated that CV-N failed to
block sCD4 binding to virus-free gp120 (sgp120) as well as
virion-associated gp120 (6, 13, 20). However, flow
cytometry experiments reported by Esser et al. (13)
indicated that CV-N blocked cell-associated CD4-dependent binding of
virion-associated gp120. Other results obtained by Dey et al.
(10) indicated that CV-N blocked binding of sgp120 to
cell-associated CD4. However, they did not undertake detailed
quantitative analyses.
In the present study, we sought to further resolve the aforementioned
ambiguities by utilizing complementary coimmunoprecipitation analyses
and flow cytometry-based sgp120-target cell-binding assays. The present
results directly indicate that CV-N blocks both CD4-dependent and
CD4-independent binding of sgp120 to target cells in a
concentration-dependent manner and that more than one CV-N molecule
binding to each sgp120 molecule is required to inhibit both types of
sgp120 binding (Fig. 1 to 3). These results are interesting in light of
a theoretical surface analysis of the solution structure of CV-N in
which two potential binding sites for protein-protein interactions were proposed (5). However, data generated using sgp120 should
be interpreted with some caution because several reports have shown that the binding of sgp120 to cells is not fully representative of the
binding of virion-associated gp120 (22, 34). Nevertheless, studies with sgp120 allow quantitative analyses of gp120-receptor complex interactions, something that is not yet possible with whole-virus assays.
The present data thus clarify that the experimental effects of CV-N on
gp120-CD4 binding interactions depend upon the type of CD4 (soluble or
membrane associated) but not upon the type of gp120 (soluble or virion
associated) employed in the study protocol. Since the steric context
may be quite different for virion-associated gp120 binding to sCD4
compared to binding to membrane-bound CD4 (28), CV-N may
sterically hinder gp120 binding to cell-associated CD4 but still allow
binding to sCD4. However, additional experiments will be required to
determine the molecular basis for the different effects seen with sCD4
versus cell-surface CD4.
Furthermore, we observed that CV-N can dissociate both CD4-dependently
and CD4-independently bound sgp120 from target cells (Fig. 5). We are
not aware of any antibody capable of dissociating sgp120 from
cell-associated CD4. Since MAb 2G12 is known neither to block sgp120
binding to CD4-expressing target cells (34) nor to
dissociate bound sgp120 from CD4-expressing cells (data not shown), the
modes and/or site(s) of binding of CV-N and MAb 2G12 must differ
substantially. These results further indicate that CV-N uniquely acts
to prevent essential interactions between gp 120 and target cell
receptors, consistent with the extensive inhibitory activity profile of
CV-N against numerous isolates of HIV-1, as well as other lentiviruses.
However, Esser et al. (13) reported that CV-N did not
impair sCD4-triggered conformational changes in virion-associated gp120
required for coreceptor binding (18, 37), and it was
reported that sCD4 bound on sgp120 was not dissociated from the sgp120
by either pre- or posttreatment of sgp120 with CV-N (6).
These results together indicated that CV-N did not dissociate sCD4
bound to the envelope glycoprotein. Again, the apparent discrepancies
can be explained by the type of CD4 (soluble or membrane associated)
employed. To further ascertain the implications and relevance of
gp120-CD4 dissociative activity of CV-N, additional experiments would
be needed to determine whether the infectivity of viruses initially
bound to but not yet fused with or entered into cells (e.g., at 4°C)
could still be inhibited by the subsequent addition of CV-N, which
presumably could displace the virus from the cells. The apparent
dissociation observed in the present study occurred after incubation of
sgp120 with the cells for 30 min at 37°C, which is long enough to
form gp120-CD4-coreceptor tricomplexes. Thus, the results seen in Fig.
5 could be alternatively explained by an enhanced rate of
internalization or degradation. However, we have previously shown that
a substantial delay of addition of CV-N after exposure of cells to
virus could still result in maximum antiviral activity (maximum
activity still after a 30-min delay and very high antiviral activity
even after a 60-min delay) (6). This may indicate that
virions were dissociated by CV-N from CD4-positive cells.
We tested whether CV-N could block the sCD4-induced sgp120 binding to
CXCR4-expressing cells. The results showed that sCD4-activated sgp120
treated with CV-N either before or after sCD4 activation failed to bind
to CXCR4-expressing cells (Fig. 4), indicating a direct effect on
activated sgp120 binding to the coreceptor. Therefore, it is suggested
that, regardless of an sCD4-activated conformational change of gp120,
CV-N binding to sgp120 leads to steric blockage and/or conformational
changes of sgp120, resulting in the inaccessibility of the coreceptor
to its binding site on the glycoprotein. Since none of the anti-gp120
MAbs directed to the third hypervariable domain of gp120 (the V3 loop),
the major determinant of CXCR4 interaction with gp120 (16,
17) blocked subsequent CV-N binding to sgp120, or vice versa
(6), it seems unlikely that CV-N directly binds to the
coreceptor binding site(s) on gp120, but rather that it induces
conformational changes of sgp120, leading to CXCR4 inaccessibility to
its binding site. This interpretation also suggested that CV-N's
inhibition of Env-coreceptor interactions would not be limited to
CXCR4. This view was confirmed by recent results of Dey et al.
(10), using a different experimental protocol than that
employed here, indicating that CV-N blocked interaction of
sCD4-activated Env with CCR5.
The inhibitory effect of CV-N on the interaction between sCD4-activated
sgp120 and CXCR4 may help explain the potent inhibitory effects of CV-N
on feline immunodeficiency virus (10), a virus which
infects feline cells in a CD4-independent (29), but
strictly CXCR4-dependent (35), manner. This model would
also predict that CD4-independent strains of HIV and simian
immunodeficiency virus (12, 21), in which the chemokine
receptor-binding domain of gp120 is already sufficiently exposed to
obviate the need for initial gp120-CD4-binding induced conformational
changes, should be susceptible to inhibition by CV-N.
Mapping studies with sCD4 and a series of MAbs to defined epitopes on
the envelope glycoprotein indicated that the CV-N-binding site(s) on
gp120 differed from the primary CD4-binding site, sCD4-induced epitopes, V3 loop, or other domains on gp120 recognized by these reagents (6, 13). However, Esser et al. (13)
described reciprocal cross-blocking studies in which CV-N pretreatment
prevented subsequent MAb 2G12 binding to gp120 but MAb 2G12
pretreatment did not prevent subsequent CV-N binding to gp120.
Moreover, our recent studies indicated that rather than CV-N binding to
essentially the same site(s) on gp120 as MAb 2G12 with even higher
affinity, CV-N binds to unique sites on gp120 in a manner that alters
the affinity of, or renders inaccessible, the 2G12 epitope for the antibody (T. Mori, unpublished data).
The 2G12 MAb is known to be directed against a conserved conformational
epitope that is highly dependent on glycosylation (33).
From several indirect lines of evidence, it is apparent that CV-N may
interact with carbohydrate moieties on gp120; however, a nonspecific
carbohydrate interaction model would not easily explain the
distinctions between the potent effects of CV-N seen against HIV-1,
HIV-2, simian immunodeficiency virus, and feline immunodeficiency virus
versus the reportedly negligible effects of CV-N on certain other
enveloped viruses having glycosylated envelope proteins, such as human
cytomegalovirus and human herpesvirus 1 (6), murine
leukemia virus (M. T. Esser, personal communication), and vaccinia
virus (10). Interestingly, Dey et al. (10)
have observed potent inhibitory effects of CV-N against certain other enveloped, but nonretroviral, viruses, specifically human herpesvirus 6 and measles virus. The possibility that CV-N's antiviral effects are
mediated through specific carbohydrate interactions available only on
susceptible viruses remains to be explored.
Overall, the present studies demonstrate that CV-N binds to sgp120 in a
manner that alters and/or masks the 2G12 epitope, prevents both
CD4-dependent and CD4-independent gp120 binding to target cells, and
blocks sCD4-induced gp120 binding to cell-associated coreceptor CXCR4.
Furthermore, CV-N induces sgp120 dissociation from target cells. These
data indicate that the mechanism(s) of action of CV-N involves
interference with essential interactions between the viral envelope
glycoprotein and target cell receptors. CV-N should be a valuable
reagent to further examine the early steps of virion binding and
fusion. Furthermore, since CV-N has shown minimal or no toxicity to
cultured cells (6, 13), benign behavior in a rabbit
vaginal toxicity model (National Institute of Allergy and Infectious
Diseases, unpublished data), and potent activity against multiple
pathogens, including macrophage-tropic HIV-1, CV-N appears promising as
a candidate microbicide to prevent the sexual transmission of HIV and AIDS.
| |
ACKNOWLEDGMENTS |
We thank C. K. Lapham for technical input on
coimmunoprecipitation assays, M. T. Esser for providing A2.01 and
A3.01 cells for flow cytometry studies, M. L. Hursey for flow cytometry
support, and M. T. Esser, J. B. McMahon, and B. R. O'Keefe for critical review of the manuscript prior to submission.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Laboratory of
Natural Products, Division of Basic Sciences, National Cancer
Institute-Frederick, Cancer Research and Development Center, Bldg.
1052, Rm. 121, Frederick, MD 21702-1201. Phone: (301) 846 5391. Fax:
(301) 846 6177. E-mail: boyd{at}dtpax2.ncifcrf.gov.
Paper 67 in the NCI Laboratory of Drug Discovery Research and
Development series "HIV-Inhibitory Natural Products."
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Antimicrobial Agents and Chemotherapy, March 2001, p. 664-672, Vol. 45, No. 3
0066-4804/01/$04.00+0 DOI: 10.1128/AAC.45.3.664-672.2001
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Abstract
Introduction
