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Journal of Virology, May 2000, p. 4562-4569, Vol. 74, No. 10
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Multiple Antiviral Activities of Cyanovirin-N: Blocking of Human
Immunodeficiency Virus Type 1 gp120 Interaction with CD4 and Coreceptor
and Inhibition of Diverse Enveloped Viruses
Barna
Dey,1
Danica L.
Lerner,2
Paolo
Lusso,3
Michael R.
Boyd,4
John H.
Elder,2 and
Edward A.
Berger1,*
Laboratory of Viral Diseases, National Institute of Allergy
and Infectious Diseases, National Institutes of Health, Bethesda,
Maryland 20892-04451; Department of
Molecular Biology, The Scripps Research Institute, La Jolla, California
920372; Unit of Human Virology,
Department of Biological and Technological Research, San Raffaele
Scientific Institute, 20132 Milan, Italy3;
and Laboratory of Drug Discovery Research and Development,
Developmental Therapeutics Program, Division of Cancer Treatment
and Diagnosis, National Cancer Institute, Frederick Cancer Research
and Development Center, Frederick, Maryland
217024
Received 14 September 1999/Accepted 16 February 2000
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ABSTRACT |
Cyanovirin-N (CV-N) is a cyanobacterial protein with potent
neutralizing activity against human immunodeficiency virus (HIV). CV-N
has been shown to bind HIV type 1 (HIV-1) gp120 with high affinity;
moreover, it blocks the envelope glycoprotein-mediated membrane fusion reaction associated with HIV-1 entry. However, the
inhibitory mechanism(s) remains unclear. In this study, we show that
CV-N blocked binding of gp120 to cell-associated CD4. Consistent with
this, pretreatment of gp120 with CV-N inhibited soluble CD4
(sCD4)-dependent binding of gp120 to cell-associated CCR5. To
investigate possible effects of CV-N at post-CD4 binding steps,
we used an assay that measures sCD4 activation of the HIV-1 envelope
glycoprotein for fusion with CCR5-expressing cells.
CV-N displayed equivalently potent inhibitory effects when added before or after sCD4 activation, suggesting that CV-N also has blocking action
at the level of gp120 interaction with coreceptor. This effect was
shown not to be due to CV-N-induced coreceptor down-modulation after
the CD4 binding step. The multiple activities against the HIV-1
envelope glycoprotein prompted us to examine other
enveloped viruses. CV-N potently blocked infection by feline
immunodeficiency virus, which utilizes the chemokine receptor CXCR4 as
an entry receptor but is CD4 independent. CV-N also inhibited fusion
and/or infection by human herpesvirus 6 and measles virus but not by vaccinia virus. Thus, CV-N has broad-spectrum antiviral activity, both
for multiple steps in the HIV entry mechanism and for diverse enveloped
viruses. This broad specificity has implications for potential clinical
utility of CV-N.
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INTRODUCTION |
Cyanovirin-N (CV-N) is a protein
from the cyanobacterium Nostoc ellipsosporum, first isolated
in an effort to discover agents from natural extracts that block
infection by human immunodeficiency virus (HIV) (5). The
protein displays potent activity against diverse isolates of HIV type 1 (HIV-1), as well as HIV-2 and simian immunodeficiency virus (5,
12), but does not inhibit human herpesvirus 1 (HHV-1),
cytomegalovirus, and adenovirus type 5 (5). In tissue
culture cells, CV-N is nontoxic at concentrations much higher than
those required for anti-HIV activity. Recombinant CV-N has been
produced in Escherichia coli, and the recombinant protein is
indistinguishable from its native counterpart (19). High-resolution structures have been obtained by both solution nuclear
magnetic resonance spectroscopy (4) and X-ray
crystallography (34). The biological and biochemical
features of CV-N have led to the suggestion that it may have clinical
utility against HIV, particularly as a topical agent to prevent sexual
transmission (5, 12).
The mechanism(s) underlying the HIV-1-inhibitory activity of CV-N
remain unclear. CV-N binds with high affinity to gp120, the external
subunit of the HIV envelope glycoprotein (Env)
(5); evidence suggests the anti-HIV-1 effects of CV-N
are mediated through this interaction (5, 12). Moreover,
CV-N inhibits the Env-mediated membrane fusion reaction associated with
HIV entry into target cells (12). The molecular basis for
this block to fusion and entry are poorly understood. There are reports
in the literature arguing both for (12) and against
(18) the notion that CV-N blocks binding of gp120 to CD4;
moreover, it has been proposed that CV-N acts primarily at a post-CD4
step in the entry process, although this has not been directly examined (18).
In this study, we focus on the effects of CV-N at specific molecular
stages of the HIV-1 Env-mediated fusion pathway. Fusion is a multistep
process involving binding of gp120 to CD4, conformational changes in
gp120 induced by CD4 binding, interaction of CD4-activated gp120 with a
target cell coreceptor (a suitable chemokine receptor [CCR5,
CXCR4, etc.]), and finally fusion between the viral and target
cell membrane, mediated by the transmembrane gp41 subunit of Env
(reviewed in references 3 and
33). Here, we show directly that CV-N blocks binding
of HIV-gp120 to CD4; we also provide evidence for inhibition of the
interaction of CD4-activated Env with coreceptor. Additionally, we show
that CV-N potently inhibits other enveloped viruses that do not use the
same target cell receptors for entry. The antiviral activity of CV-N is
thus complex, displaying much broader specificity than previously
indicated. The implications of these findings for potential clinical
uses of CV-N are discussed.
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MATERIALS AND METHODS |
Cells.
Human HeLa and murine NIH 3T3 cells were obtained
from the American Type Culture Collection. PM1 human T lymphocytes
(17) were obtained from M. Norcross, Food and Drug
Administration, Bethesda, Md. HEK293-CCR5 transfectant cells
(9) were obtained from P. Murphy, National Institute of
Allergy and Infectious Diseases (NIAID), National Institutes of Health
(NIH). All of the above cell lines were grown in Dulbecco's modified
Eagle's medium supplemented with 10% fetal bovine serum (FBS), 2 mM
L-glutamine, and 50 µg of gentamicin/ml. HEK293-CCR5
cells were maintained in the presence of Geneticin (2 mg/ml; Gibco BRL,
Bethesda, Md.). The feline T-cell line MCH5-4 (16) and the
brain-derived glial cell line G355-5 were kindly provided by Don Blair,
Frederick Cancer Research and Development Center, NIH. Both cell lines
were cultured in RPMI 1640 supplemented with 10% heat-inactivated FBS,
minimal essential medium (MEM)-vitamins, nonessential amino acids,
sodium pyruvate, 200 µM L-glutamine, 5.5 × 10
5 M 
-mercaptoethanol, and 50 µg of gentamicin/ml.
The MCH5-4 cells were supplemented with recombinant human interleukin 2 (50 U/ml; a generous gift of Hoffmann-La Roche, Nutley, N.J.) and
concanavalin A (2.5 µg/ml; Boehringer Mannheim, Indianapolis, Ind.).
Viruses.
All vaccinia virus recombinants were derived from
the WR wild-type strain. Expression of foreign genes was driven by
vaccinia virus promoters unless otherwise specified. The recombinant
virus vCB-3 (8) encodes full-length human CD4; vCB-32
encodes SF162 Env (7); vT7-HMV encodes measles
virus (MV) hemagglutinin and vT7-FMV encodes MV fusion
protein, both linked to the bacteriophage T7 promoter (21);
vTF7-3 (13) and vP11T7gene1 (1) both encode
bacteriophage T7 RNA polymerase, and vCB21R-LacZ contains the E. coli lacZ gene linked to the bacteriophage T7 promoter (2). Two infectious molecular clones of feline
immunodeficiency virus (FIV), namely, FIV-34TF10, originally isolated
from a cat in Petaluma, Calif. (27), and FIV-PPR, an isolate
obtained from a San Diego cat (22), were used in this study.
HHV-6 GS is a prototype strain of subgroup A, initially isolated from
the peripheral blood of immunocompromised patients with
lymphoproliferative disorders (24).
Proteins and antibodies.
Purified recombinant CV-N
(expressed in E. coli) (19) was used in this
study. Purified gp120 protein (expressed in a stable, hygromycin-resistant Drosophila Schneider 2 cell line and
affinity purified over an F105 column from the JR-FL strain of HIV-1)
(32) was a gift from R. Wyatt, Dana Farber Cancer Institute,
Boston, Mass.; the purified protein is active both for binding to CD4 and for CD4-induced binding to CCR5. Purified two-domain soluble CD4
protein (sCD4; amino acids 1 to 183) was donated by S. Johnson, Pharmacia Upjohn, Kalamazoo, Mich. Rabbit polyclonal serum 2143, raised
against recombinant Env IIIB gp140, was gift of P. Earl, NIAID. T4-4
rabbit polyclonal sera (catalog no. 806) raised against recombinant
human sCD4 was obtained from the NIAID AIDS Research and Reference
Reagent Program. Several murine monoclonal antibodies (MAbs) were used.
Phycoerythrin (PE)-conjugated anti-human CCR5 MAb 2D7 (isotype
immunoglobulin G2a [IgG2a], 
) and PE-conjugated anti-human CXCR4
MAb 12G5 (isotype IgG2a, ) were purchased from Pharmingen
International, San Diego, Calif. MAbs against HHV-6 glycoproteins gp102 and gp116 were obtained from Virotech
International, Inc., Rockville, Md.
Binding of gp120 to cell-associated CD4.
NIH 3T3 cells were
infected with recombinant vaccinia virus vCB-3 (encoding full-length
human CD4) at a multiplicity of infection of 10, using MEM plus
Earle's balanced salts supplemented with 2.5% FBS (EMEM-2.5); control
cells were infected with wild-type vaccinia virus WR. After overnight
incubation at 31°C to allow surface expression of CD4, the cells were
washed once with EMEM-2.5 and resuspended at the concentration of
4 × 106/ml. JR-FL gp120 (40 ng) was preincubated with
different concentrations of CV-N in total 100 µl of EMEM-2.5 for 15 min at room temperature. The protein mix was then added to the cells
(2 × 106 in a total volume of 500 µl) and incubated
at 37°C for 1 h with constant rotation. The cells were then
washed once with prechilled EMEM-2.5 and once with prechilled
phosphate-buffered saline, pH 7.4 (PBS). The cell pellet was
resuspended in lysis buffer containing 10 mM Tris-HCl (pH 8.0), 0.1%
Triton X-100, 10 mM MgSO4, 2 mM CaCl2, and
freshly added 1% aprotinin, 1 mM [4-(2-aminoethyl)-benzenesulfonyl fluoride hydrochloride], 1 mM dithiothreitol, and 50 U of micrococcal nuclease/ml. Lysis was achieved by three repeats of freezing and thawing cycles. The lysate was further incubated with 25% volume of
5× sodium dodecyl sulfate sample buffer for 30 min at room temperature
with intermittent vortexing. A fraction of the total cell lysate was
then directly analyzed by polyacrylamide gel electrophoresis on a 10%
gel, followed by Western transfer, probing for gp120 by using 1:7,000
dilution of the 2143 antiserum, and finally chemiluminescent detection
of gp120 with horseradish peroxidase-conjugated goat anti-rabbit IgG
(Boehringer Mannheim) and SuperSignal chemiluminescent substrates
(Pierce Chemical Co., Rockford, Ill.). To further show specificity of
gp120 binding, one aliquot of gp120 was preincubated with excess sCD4
(1 µM) before addition to the CD4-expressing cells.
Anti-CD4 antibody binding to cell-associated CD4.
NIH 3T3
cells infected with WR or vCB-3 were resuspended at 5 × 106 cells/ml in EMEM-2.5. Aliquots (100 µl) of cells were
treated with 2 µl of T4-4 antiserum in the presence or absence of 100 nM CV-N and incubated 1 h at room temperature with constant
rotation. Cell lysates were prepared as described above. Samples were
resolved by polyacrylamide gel electrophoresis, and the anti-CD4 IgG
heavy chain was detected by Western blotting with horseradish
peroxidase-conjugated goat anti-rabbit IgG and SuperSignal
chemiluminiscent substrates.
Binding of gp120 to coreceptor.
JR-FL gp120 (40 ng) was
preincubated with different concentrations of CV-N for 15 min at room
temperature and then activated by incubation with 600 nM of sCD4 in a
total 100-µl volume of EMEM-2.5, first on ice for 30 min and then at
room temperature for 30 min. The protein mix was added to 500 µl of
HEK293-CCR5 cells (2 × 106 cells) and rotated for
1.25 h at room temperature. The cells were washed once with
pre-chilled EMEM-2.5 and once with prechilled PBS. Preparation of cell
lysate and detection of gp120 with 2143 antiserum by Western blotting
are as described above.
Flow cytometric analysis.
Effects of CV-N on surface
expression of HIV coreceptors were determined by flow cytometric
analysis of HEK293-CCR5 transfectant cells and HeLa cells (endogenously
expressing CXCR4). The cells (106) were first suspended in
100 µl of PBS without or with 250 nM of CV-N and incubated for 1 h at 37°C. Excess CV-N was removed by pelleting the cells and
discarding the supernatant. The cell pellets were resuspended in 80 µl of PBS plus 20 µl of the indicated PE-conjugated MAb and
incubated for 20 min at room temperature. After two washes in PBS, the
cells were resuspended in 500 µl of PBS, followed by flow cytometric
analysis using a FACScan analyzer (Becton Dickinson). Dead cells were
excluded by appropriate gating. Approximately 6,000 events were
accumulated for each sample.
HIV Env-mediated cell fusion.
The effect of CV-N on HIV-1
Env-mediated cell fusion was analyzed with either the previously
described standard reporter gene activation assay (20) or a
modification of that assay involving sCD4 activation of Env for fusion
with CD4-negative cells expressing a suitable coreceptor
(25). Effector cells were prepared by infecting HeLa cells
in suspension with the recombinant vaccinia virus vCB-32 (encoding the
HIV-1 Env SF162) and vP11T7gene1 (encoding the bacteriophage T7 RNA
polymerase gene driven by a vaccinia virus promoter). For the standard
assay (Fig. 4A), target cells were prepared by infecting HEK293-CCR5
cells with two recombinant vaccinia viruses, vCB21R-LacZ (encoding
lacZ linked to the T7 promoter) and vCB-3 (encoding human
CD4). For the sCD4-activated assay (Fig. 4B and C), target cells were
infected with vCB21R-LacZ alone. Following overnight incubation at
31°C to allow protein expression, effector and target cells were each
washed and resuspended. For Fig. 4A, effector cells (100 µl, 2 × 106 cells/ml) were added to duplicate wells of 96-well
plates and preincubated for 15 min at room temperature with 10 µl of
PBS containing different concentrations of CV-N. Target cells (100 µl, 2 × 106 cells/ml) were then mixed with these
effector cells. For Fig. 4B, effector cells were first incubated with
CV-N for 15 min at room temperature, and then 200 nM (final
concentration) sCD4 was added to these cells before mixing with the
target cells. For Fig. 4C, effector cells were first incubated for 30 min at 37°C with 200 nM (final concentration) sCD4, followed by
incubation with 200 nM CV-N and then mixing with target cells. The cell
mixtures were incubated for 2.5 h at 37°C to allow fusion. The
cells were then lysed with Nonidet P-40, and -galactosidase
(-Gal) activity was measured at 570 nm in the presence of
chlorophenol-red--D-galactopyranoside.
MV glycoprotein-mediated cell fusion.
NIH 3T3
cells were infected in suspension with the recombinant vaccinia viruses
encoding the MV hemagglutinin and fusion glycoproteins and
also with vTF7-3. PM1 cells (endogenously expressing CD46) were
infected with vCB21R-LacZ. Following overnight incubation at 31°C to
allow protein expression, effector and target cells were washed and
resuspended. Effector cells (100 µl, 106 cells/ml) were
added to duplicate wells of 96-well plates and preincubated for 30 min
at 37°C with 50 µl of PBS containing different concentrations of
CV-N. Target cells (50 µl, 2 × 106 cells/ml) were
then mixed with these effector cells, and the plates were incubated for
2.5 h at 37°C. The cell lysates were assayed for -Gal
activity as described above.
HHV-6-mediated cell fusion and infection.
Adaptation of the
cell fusion assay for HHV-6 has been reported elsewhere
(26). Briefly, peripheral blood mononuclear cells (PBMCs),
isolated from healthy donors, were activated with phytohemagglutinin M
and 48 h later were infected with HHV-6 strain GS at a
multiplicity of infection of 0.5. After the appearance of large,
refractile cells (3 to 7 days postinfection), the cells were infected
with vCB21R-LacZ. HeLa cells, which are permissive for HHV-6-mediated cell fusion (26), were infected with vTF7-3. PBMCs (100 µl, 106 cells/ml) were added to duplicate wells of
96-well plates and preincubated for 30 min at 37°C with 50 µl of
PBS containing different concentrations of CV-N. HeLa cells (50 µl,
2 × 106 cells/ml) were then mixed with these effector
cells. The cell mixtures were incubated for 2.5 h at 37°C to
allow fusion. The cell lysates were assayed for -Gal activity as
described above.
For infectivity assays, activated PBMCs (106) were
suspended in 350 µl of RPMI 1640 plus 10% FBS, in duplicate, and
mixed with 50 µl of PBS containing different concentrations of CV-N
at room temperature. Viral stocks (100-µl aliquots of HHV-6 strain
GS) were added at a multiplicity of infection of 0.1 and incubated for
1.5 h at 37°C. The cells were washed once, resuspended in 450 µl of RPMI 1640 plus 10% FBS, and incubated with 50 µl of different dilutions of CV-N in PBS for 3 days at 37°C. The cells were
then washed with PBS, resuspended in 50 µl of PBS, and dried onto
microscopic slides. For immunodetection, the cells were fixed in
acetone for 5 min at 
20°C, followed by incubation for 20 min at
room temperature with a mixture of MAbs to HHV-6 gp102 (final concentration of 125 µg/ml) and HHV-6 gp116 (final concentration of
25 µg/ml) diluted in PBS. The cells were washed in PBS, followed by
incubation with fluorescein isothiocyanate-conjugated goat anti-mouse
IgG (10 µg/ml, final concentration; Boehringer Mannheim). The cells
were washed as before, mounted with 50% glycerol in PBS, and
photomicrographed using Bio-Rad MRC 1024 confocal laser scanning microscope.
Vaccinia virus-mediated low-pH fusion.
Based on the reported
observation that brief exposure of vaccinia virus-infected cells to pH
5.5 results in cell-cell fusion (10, 14), we used a newly
developed low-pH-induced vaccinia virus-based reporter gene assay (H. Greenstone and E. Berger, unpublished data). Briefly, HeLa cells
infected with vCB21R-LacZ were mixed with HeLa cells infected with
vTF7-3. The cell mixtures were incubated with different concentrations
of CV-N for 15 min at room temperature, exposed briefly to pH 5.5, washed with neutral pH buffer, resuspended in EMEM-2.5 (neutral pH),
and then incubated at 37°C for 2.5 h in presence of the same
concentrations of CV-N. The cells were lysed with Nonidet P-40, and the
-Gal activity was measured as described above.
FIV infection.
MCH5-4 cells (106) were
preincubated, in duplicate, for 30 min with 1 and 10 nM (final
concentrations) CV-N in Hanks' balanced salt solution prior to the
addition of FIV-PPR. The virus was removed after 1 h, and the
cells were cultured for 5 days in presence of appropriate
concentrations of CV-N. The negative control cells were incubated with
the CV-N diluent. Viral load was quantitated using a reverse
transcriptase assay as previously described (16). For
pretreatment experiments, FIV-34TF10 and G355-5 cells were separately
preincubated with 10 nM CV-N for 30 min. Then either CV-N-treated virus
was added to G355-5 cells (106) or untreated virus was
added to the CV-N-treated G355-5 cells. After 1 h, the cells were
washed and then maintained in media without CV-N for 5 days. All
samples were performed in duplicate and assayed for virus as above.
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RESULTS |
CV-N blocks the gp120-CD4 binding interaction.
The first
interaction of HIV-1 with specific target cell receptors involves the
gp120 subunit of Env binding to cellular CD4. In an effort to
understand the mechanism of CV-N inhibition of HIV-1 Env-mediated
fusion and infection, we tested the effect of CV-N on binding of
soluble gp120 to cell-associated CD4 (Fig. 1A). The gp120 protein used in this
experiment was from the JR-FL isolate (primary R5, macrophagetropic,
non-syncytium inducing). NIH 3T3 cells expressing vaccinia
virus-encoded CD4 were incubated with JR-FL gp120, centrifuged, and
washed; cell-associated gp120 was detected by Western immunoblot
analysis. Since no CCR5 coreceptor is present on the target cell in
this system, analysis of the gp120-CD4 interaction is simplified. As
shown in Fig. 1A, JR-FL gp120 bound to CD4-expressing cells (lane 3).
The specificity of binding was verified by the low background binding
observed with CD4-negative cells (lane 8) and by the inhibition caused by excess sCD4 (lane 9). When gp120 was preincubated with CV-N, binding
to CD4 was potently inhibited in a dose-dependent fashion (lanes 4 to
6).
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FIG. 1.
Effect of CV-N on binding of gp120 and anti-CD4
antibodies to cell-associated CD4. (A) Binding of mock-treated (lane 3)
or CV-N-treated (lanes 4 to 6) JR-FL gp120 to CD4-expressing
(vCB-3-infected) cells was determined by Western blotting of whole cell
lysates using polyclonal anti-gp120 antibody for detection. For lane 9, gp120 was preincubated with excess of sCD4. As negative control,
CD4-negative (WR-infected) cells were incubated without (lane 7) or
with (lane 8) gp120. The indicated CV-N concentrations represent those
in the final incubation mixtures. Purified JR-FL gp120 (lane 1) was run
as positive standard for immunodetection. mCD4, membrane-associated
CD4. (B) Effect of CV-N on binding of anti-CD4 polyclonal antiserum to
CD4-expressing (lanes 2 to 4) or CD4-negative cells (lanes 5 and 6) was
determined by Western blotting of whole cell lysates using horseradish
peroxidase-conjugated goat anti-rabbit IgG. The indicated CV-N
concentrations represent those in the final incubation mixture. In lane
1, diluted antiserum was run as a positive standard. Migration of IgG
heavy chain (hc) is indicated.
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As an additional test of the specificity of CV-N inhibition of the
gp120-CD4 interaction, we examined whether CV-N could block
specific
binding of unrelated proteins to CD4. As shown in Fig.
1B, polyclonal
anti-CD4 antibodies bound to the same CD4-expressing
cells used in Fig.
1A but not to the CD4-negative cells (compare
lanes 3 and 6). CV-N had
no inhibitory effect on this specific
antibody binding (lane 4). Thus,
the effects of CV-N on protein
binding to CD4 showed specificity for
gp120. Moreover, these results
demonstrate that CV-N does not cause
down-modulation of surface
CD4; this conclusion was also verified by
flow cytometry experiments
indicating no effect of CV-N on binding of
several anti-CD4 MAbs
(BL4 and 13B8.2 [Immunotech Coulter] and Leu3A
[Becton Dickinson])
to CD4 endogenously expressed on SupT1 cells (not
shown).
CV-N blocks sCD4-induced binding of gp120 to the CCR5
coreceptor.
To elucidate whether CV-N can inhibit gp120 binding at
other target cell sites involved in HIV-1 fusion and infection, we tested binding of gp120 from the JR-FL R5 isolate to HEK293-CCR5 cells
that express CCR5 but not CD4. It has been shown previously that gp120
binds to CCR5 only upon activation by CD4 (28, 32). Therefore, purified gp120 was preincubated with sCD4 and then added to
HEK293-CCR5 cells. Following incubation for 1 h at 37°C, the
cells were centrifuged and washed; cell-associated gp120 was detected
by Western immunodetection analysis. The sCD4-activated gp120 bound to
the CCR5-expressing cells (Fig. 2, lane
3). The specificity of binding was confirmed by its strict dependence on sCD4 activation of gp120 (compare lanes 2 and 3). Preincubation of
gp120 with 20 or 100 nM CV-N prior to sCD4 activation strongly blocked
its binding to CCR5-expressing cells (lanes 4 and 5). We investigated
the possible effect of CV-N on surface expression of the two major HIV
coreceptors, CCR5 and CXCR4. As shown in Fig.
3A, flow cytometric analysis using the
2D7 anti-CCR5 MAb with HEK293-CCR5 cells showed no effect of 250 nM
CV-N on CCR5 surface expression. Parallel experiments using the
anti-CXCR4 MAb 12G5 demonstrated that CV-N had no effect on endogenous
CXCR4 expression on HeLa cells (Fig. 3B). Taken together, the results in this and the previous section indicate that the CV-N blocking effects are manifested at distinct interactions between gp120 and its
essential target cell receptors.
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FIG. 2.
Effect of CV-N on CD4-dependent gp120 binding to target
cell coreceptor. Binding of mock-treated (lanes 2 and 3) or
CV-N-treated (lanes 4 and 5) JR-FL gp120 to CCR5-expressing cells, upon
activation by sCD4, was determined by Western blotting of whole cell
lysates using polyclonal anti-gp120 antibody for detection. Lane 1 shows purified gp120 used as positive control for immunodetection. The
indicated CV-N concentrations represent those in the final incubation
mixtures. The faint band above gp120 in lanes 2 to 5 is a cellular
protein that nonspecifically reacts with the antiserum.
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FIG. 3.
Effect of CV-N on cell surface expression of HIV
coreceptors. Cells were incubated with PBS alone or PBS plus 250 nM
CV-N prior to staining with the indicated MAbs, followed by flow
cytometric analysis. (A) For detection of CCR5, HEK293-CCR5 cells were
stained with the specific MAb (2D7, PE conjugated); as a negative
control, the same cells were stained with an irrelevant isotype-matched
MAb (12G5, PE conjugated). (B) For detection of CXCR4, HeLa cells were
stained with the specific MAb (12G5, PE conjugated); control cells were
stained with the isotype-matched 2D7 MAb, conjugated to PE.
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CV-N blocks Env interaction with coreceptor before or after sCD4
activation.
The experiments described above do not distinguish
whether the CV-N blocking of gp120-coreceptor binding is a direct
effect or simply the consequence of CV-N blocking of sCD4 binding to gp120 and resulting activation for coreceptor binding. To address this
issue, we used an experimental variation of the standard cell fusion
system that enables analysis of discrete steps in the sequential
cascade by which Env associates with CD4 followed by coreceptor
(25). In this system, sCD4 activates Env-expressing cells to
fuse with cells bearing coreceptor but lacking CD4. We used this
sCD4-activated fusion system to characterize further the mechanisms by
which CV-N can block Env functional interaction with target cell
receptors (Fig. 4). The effector cells
used in these experiments expressed the R5 HIV-1 Env from the SF162
strain; the target cells expressed CCR5 plus CD4 (standard fusion
system [Fig. 4A]) or CCR5 alone (sCD4-activated system [Fig. 4B and
C]). The results using the sCD4-activated system indicate similar
fusion inhibition patterns irrespective of whether CV-N was present
during the preincubation with sCD4 (Fig. 4B) or after the sCD4
activation (Fig. 4C). These findings suggest that CV-N can block not
only the binding of gp120 to CD4 but also the CD4-induced binding of gp120 to coreceptor. Figure 4 also shows that the potency of CV-N in
both modes in the sCD4-activated system was somewhat greater than that
obtained in the standard system (Fig. 4A), consistent with similar
potency difference obtained with fusion-blocking antibodies
(25).
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FIG. 4.
Inhibition of SF162 Env function by CV-N when added
before or after sCD4 activation. HIV Env-mediated cell fusion was
assayed. (A) CV-N was tested in a standard fusion assay using target
cells expressing CD4 and CCR5. CV-N was added to effector cells before
addition of target cells. (B and C) CV-N was tested in sCD4-activated
fusion assay using target cells expressing CCR5 but not CD4. CV-N was
added to effector cells before (B) or after (C) addition of sCD4 (200 nM). The indicated CV-N concentrations represent those in the final
fusion mixtures. The background -Gal activity value (0.53), obtained
with CD4-negative target cells in the absence of CD4, was subtracted
from each value to give the data shown. Error bars indicate standard
deviation of the mean values obtained from duplicate samples. OD,
optical density.
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CV-N does not block vaccinia virus.
We performed a control
experiment to rule out the possibility that the apparent CV-N
inhibition of HIV-1 Env-mediated fusion is simply an artifact
reflecting impairment of the vaccinia virus-based reporter gene
read-out. We adapted the cell fusion assay to measure fusion mediated
by vaccinia virus, an activity known to be induced by low-pH treatment
of infected cells (10, 14). Figure
5 shows that CV-N had no inhibitory
effect on vaccinia virus-mediated cell fusion, thereby indicating that
the vaccinia virus-based reporter gene activation system was unaffected
by CV-N. Moreover, the failure of CV-N to block vaccinia virus-mediated
fusion provides added specificity to the previously described anti-HIV
effects. However, the experiments in the following sections reveal that the blocking effects of CV-N are not restricted to HIV.
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FIG. 5.
Effect of CV-N on vaccinia virus-mediated low-pH-induced
cell fusion assay. The vaccinia virus-based low-pH-induced cell fusion
assay was used. The background -Gal activity value (27),
obtained at neutral pH in the absence of CV-N, was subtracted from each
value to give the data shown. The value of -Gal activity (660)
obtained at pH 5.5 in absence of CV-N was defined as 100%. The
indicated CV-N concentrations represent those in the final incubation
mixtures. Error bars indicate standard deviation of the mean values
obtained from duplicate samples.
|
|
CV-N blocks infectivity of FIV, a CD4-independent, nonprimate
immunodeficiency virus.
Since CV-N inhibits HIV at more than one
step in the receptor interaction cascade, we questioned whether the
effects of this agent might extend beyond HIV-1 (and its close
relatives HIV-2 and simian immunodeficiency virus). We investigated
the effect of CV-N on FIV, a nonprimate immunodeficiency virus that
infects feline cells independent of CD4 (23) but strictly
dependent on CXCR4 (6, 23, 30, 31). As shown in Fig.
6A, CV-N at concentrations as low as 10 nM strongly blocked FIV infection of CXCR4-expressing MCH5-5 cells. In
view of the previous experiment (Fig. 3B) showing that CXCR4
surface expression is unaffected by CV-N, we conclude that the
CV-N effects on FIV are not due to down-modulation of this coreceptor.
Figure 6B demonstrates that the CV-N effects were much more pronounced
with pretreatment of the FIV virions compared to pretreatment of the
host cells, even though in both cases the CV-N was maintained in the
virus-cell mixture during the 1-h preincubation. This result suggests
that the inhibition resulted predominantly from the CV-N-virion
interaction; similar conclusions have been reached for CV-N inhibition
of HIV-1 (5, 12). In the FIV pretreatment experiments,
modest inhibitory effects were consistently observed upon
pretreatment of the host cells (Fig. 6B).
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|
FIG. 6.
CV-N's effect on FIV infection. The viral load of
FIV-infected cells cultured for 5 days was determined by a reverse
transcriptase assay. All samples were done in duplicate. (A)
Dose-dependent inhibition of FIV-PPR on the feline T-cell line MCH5-4.
The infected cells were cultured in the presence of the indicated
concentrations of CV-N. (B) Separate preincubation of either FIV-34TF10
or G355-5 feline glial cells with 10 nM CV-N. Infected cells were
cultured in absence of CV-N. Error bars indicate standard deviation of
the mean values obtained from duplicate samples.
|
|
Antiviral activity of CV-N extends beyond immunodeficiency
viruses.
We further investigated the breadth of CV-N antiviral
activity by studying other nonretroviral enveloped viruses, the entry of which does not involve either CD4 or chemokine receptors. MV employs
CD46 as the receptor for entry and infection (11); this process is mediated by the specific interaction between the viral hemagglutinin and CD46 and displays no requirement for CD4. We previously used the reporter gene cell fusion assay to study the MV
hemagglutinin and fusion glycoproteins (21).
Figure 7A indicates that CV-N inhibited
MV fusion, with a potency equivalent or greater than that observed for
HIV-1 (Fig. 4A; also data in reference 12).
View larger version (22K):
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|
FIG. 7.
Inhibitory effects of CV-N on MV and HHV-6. For the
experiments shown in panels A and B, the vaccinia virus-based reporter
gene cell fusion assays were used. The indicated CV-N concentrations
represent those in the final fusion mixtures. (A) Effect of CV-N on MV
envelope glycoprotein-mediated fusion. The background
-Gal activity value (0.6), obtained with the effector cells
expressing the hemagglutinin protein alone, was subtracted from each
value obtained with effector cells expressing both hemagglutinin and
fusion glycoproteins. The -Gal activity (72.4) obtained
from MV envelope glycoproteins-mediated fusion in absence
of CV-N was defined as 100%. (B) Effect of CV-N on HHV-6-mediated cell
fusion. As a background control, the -Gal activities from effector
cells (PBMCs) and target cells (HeLa) incubated alone were combined,
and this value (2.48) was subtracted from each point to give data
shown. The -Gal activity (6.24) obtained from fusion in absence of
CV-N was defined as 100%. In panels A and B, -Gal values represent
the means of duplicate samples; error bars indicate standard deviation
of the mean values obtained from duplicate samples. (C) Effect of CV-N
on HHV-6 infection. Infection of PBMCs was performed in the absence
(top) or continuous presence (bottom) of 100 nM CV-N. After 3 days, the
cells were assayed by immunofluorescence microscopy for the presence of
the HHV-6 glycoproteins gp102 and gp116. The large,
brightly stained cells in the top panel are typical of HHV-6
infection.
|
|
Finally we analyzed the effects of CV-N on HHV-6. This virus has
recently been found to also use CD46 as its receptor for
entry, fusion,
and infection (
26). We found that CV-N potently
inhibited
fusion of HHV-6-infected cells with permissive target
cells (Fig.
7B),
as well as acute HHV-6 infection of PBMCs (Fig.
7C).
| |
DISCUSSION |
We demonstrate herein that the cyanobacterial protein CV-N blocks
multiple steps in the pathway of HIV-1 interaction with specific target
cell receptors, leading to membrane fusion and virus entry. Previous
efforts to assess these issues have yielded conflicting results.
Mariner et al. (18) reported an enzyme-linked immunosorbent
assay in which CV-N failed to block sCD4 binding to components in an
HIV-1 lysate captured with polyclonal anti-gp120; also, the same study
presented data indicating failure of CV-N to block HIV-1 binding to
various CD4-positive T-cell lines. However, it was not verified that
the binding activities measured in these experiments truly reflected
the specific gp120-CD4 interaction. The effects of CV-N on gp120
binding to CD4 were subsequently addressed by Esser et al.
(12). In experiments analyzing binding of different
anti-gp120 neutralizing MAbs to virions or to monomeric gp120, no CV-N
inhibitory effects were noted for MAb F105 or IgG1b12, both directed
against the CD4 binding site. We note that the relationship of this
result to the effects of CV-N on gp120-CD4 binding is indirect;
moreover, the interpretation is complicated by the extensive conformational changes believed to be required for the high-affinity gp120-CD4 interaction (15, 33). Esser et al. (12)
also presented flow cytometry experiments indicating that CV-N blocked
HIV-1 virion-mediated occlusion of the Leu3A neutralizing epitope on CD4; moreover, CV-N inhibited the Leu3A-sensitive (CD4-dependent) component of virion binding to CD4-positive cells. The dose responses of these effects paralleled those observed for CV-N inhibition of HIV-1
infectivity. The simplest interpretation was that CV-N interferes with
the gp120-CD4 interaction, though it was acknowledged that the presence
of coreceptor on the CD4-expressing cell represented a caveat to this
conclusion. Furthermore, this interpretation was difficult to reconcile
with another experiment in the same report showing that CV-N did not
impair sCD4-induced enhancement of exposure of certain gp120 epitopes.
In the present study, we sought to resolve this issue by simple direct
biochemical analyses. By using a Western blot assay verified to measure
specific gp120 binding to cell-associated CD4, we demonstrate directly
that CV-N specifically blocks the gp120-CD4 interaction in a potent,
dose-dependent fashion. These results were not complicated by possible
coreceptor interactions, since no coreceptor was present on the murine
cells used in this experiment.
CV-N has also been proposed to affect gp120 function after the CD4
binding step (18), although this has not been experimentally tested. In this report, we directly analyzed the effect of CV-N on the
binding of gp120 to coreceptor. In a simple biochemical assay, CV-N
strongly blocked binding of sCD4-activated gp120 to cell-associated
CCR5, an effect that was shown not to be due to coreceptor
down-modulation. To distinguish whether this inhibition simply
reflected CV-N blockade of CD4 binding to, and activation of, gp120,
versus CV-N action at a subsequent stage, we used a functional assay
measuring sCD4-activated, CCR5-dependent cell fusion. The ability of
CV-N to block sCD4-activated fusion when added after, as well as
before, sCD4 treatment suggests a direct effect on activated gp120
binding to coreceptor. However, we cannot exclude the possibility that
the sCD4 binding and activation steps are largely reversible and in
dynamic equilibrium; if so, CV-N added after sCD4 might bind to gp120
molecules as the sCD4 dissociates, thereby preventing sCD4 rebinding
and activation. Additional experiments are required to address these
complex kinetic issues. Acknowledging this caveat, our results suggest
that CV-N can exert inhibitory effects through at least two discrete
steps in the pathway of HIV-1 Env interaction with the specific target
cell receptors. Presumably both activities contribute to the potency of
CV-N against HIV-1 fusion/entry. We also note that the inhibitory
effects may not be limited to receptor interactions. Indeed, there are
indications that CV-N can interact with the gp41 subunit of Env
(B. R. O'Keefe, J. M. Muschik, M. J. Currens, and
M. R. Boyd, Abstr. Protein Society Meeting, Boston, Mass., p. 139, 1999); additional modes of inhibition can be envisioned (virion
aggregation, Env destabilization, etc.).
Our HIV-1 findings prompted us to broaden the analysis of CV-N to
additional enveloped viruses. An earlier report (5)
demonstrated that the anti-HIV-1 effects of CV-N did not extend to
several other viruses tested, specifically adenovirus type 5 (nonenveloped), human cytomegalovirus (enveloped), and HHV-1
(enveloped). We expanded these findings by showing that vaccinia
virus-mediated fusion was not susceptible to CV-N inhibition. However,
results were quite different for the other enveloped viruses tested.
FIV infectivity was potently blocked by CV-N; this virus uses the
chemokine receptor CXCR4 as a primary entry receptor (6, 23, 30,
31), thus providing another illustration of CV-N effects distinct
from CD4 binding. Similarly susceptible to CV-N inhibition in fusion
and/or infectivity analyses were MV and HHV-6, both of which use CD46 as an entry receptor.
We have also considered the possibility that target cell effects might
contribute to the antiviral activities of CV-N. The FIV experiments
indicated much more pronounced activity with pretreatment of virions
compared to host cells, although some inhibitory effects were
consistently observed in the latter case. In these experiments, CV-N
was present not only in the preincubation stage but also in the
subsequent interaction stage between virion and target cells; the
inherent difficulty of physically manipulating retrovirus particles
precluded the use of protocols involving extensive virion washing
before adding to target cells. In additional experiments (not shown),
we analyzed HIV-1 Env-mediated cell fusion, which permits direct
comparison of the effects of pretreatment and washing of target versus
effector cells. CV-N inhibited only modestly when either cell partner
was pretreated and washed prior to initiation of the fusion reaction
(in contrast to the strong inhibition observed when CV-N was maintained
throughout the fusion reaction); moreover, the inhibitory effects were
comparable with pretreatment of either the target or effector cells.
These results argue against predominant irreversible effects of CV-N on
components of either cell partner.
In view of the complexity of CV-N action, what might be the
explanation(s) for the inhibitory effects of CV-N against multiple viruses? Esser et al. (12) found that of all the anti-gp120 neutralizing MAbs tested, CV-N blocked the binding of only one, 2G12.
This MAb is known to be directed against a conserved conformational epitope that is highly dependent on glycosylation (29),
leading to the suggestion that CV-N and 2G12 might act similarly
(though not identically). Perhaps the broad effects of CV-N on diverse enveloped viruses simply reflect the protein's affinity for
carbohydrate moieties that are extensively represented on many viral
envelope glycoproteins. However, it must be noted that the
evidence for CV-N interaction with carbohydrate moieties on gp120 is
only indirect (12); additional studies are required to
determine if specific CV-N-carbohydrate interactions are essential for
the antiviral activities. We also note that the carbohydrate model does
not easily explain the distinctions between the potent effects seen with HIV, FIV, MV, and HHV-6, versus the negligible effects shown here
for vaccinia virus and previously reported for other enveloped viruses
(human cytomegalovirus and HHV-1); each of these viruses have
glycosylated envelope proteins.
The present results may have important implications for potential
clinical applications of CV-N. The protein is minimally toxic to tissue
culture cells (5, 12); moreover, antiviral concentrations in
blood have been achieved and sustained in vivo in rodents, with minimal
toxicity (National Cancer Institute, Developmental Therapeutics
Program, unpublished data). Initial studies (NIAID, unpublished data)
showing benign effects of CV-N in a rabbit vaginal toxicity model are
also encouraging. Additional studies are required to assess
whether the broad inhibitory activity of CV-N revealed in this report
bode well or poorly for the clinical utility of CV-N.
| |
ACKNOWLEDGMENTS |
We thank R. Wyatt for providing purified JR-FL gp120, P. Kennedy
for assistance in HHV-6 fusion assay, J. Yewdell for helping with
confocal microscopy, H. Greenstone for guidance on low-pH fusion, and
K. Salzwedel for helpful comments on the manuscript.
This work was supported in part by the NIH Intramural AIDS Targeted
Antiviral Program.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Laboratory of
Viral Diseases, National Institute of Allergy and Infectious Diseases, Building 4, room 237, National Institutes of Health, Bethesda, MD
20892. Phone: (301) 402-2481. Fax: (301) 480-1147. E-mail: edward_berger{at}nih.gov.
| |
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Journal of Virology, May 2000, p. 4562-4569, Vol. 74, No. 10
0022-538X/00/$04.00+0
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Abstract
Introduction
