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Previous Article | Next Article 
J Virol, January 1998, p. 535-541, Vol. 72, No. 1
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
71-Kilodalton Heat Shock Cognate Protein Acts as a
Cellular Receptor for Syncytium Formation Induced by Human T-Cell
Lymphotropic Virus Type 1
Yasuko
Sagara,
Chuzo
Ishida,
Yukiko
Inoue,
Hiroshi
Shiraki,* and
Yoshiaki
Maeda
Fukuoka Red Cross Blood Center, Fukuoka 818, Japan
Received 4 June 1997/Accepted 24 September 1997
 |
ABSTRACT |
We previously reported that the region corresponding to amino acids
197 to 216 of the gp46 surface glycoprotein (gp46-197) served as a
binding domain for the interaction between gp46 and trypsin-sensitive
membrane components of the target cell, leading to syncytium formation
induced by human T-cell lymphotropic virus type 1 (HTLV-1)-bearing
cells. Our new evidence shows that the 71-kDa heat shock cognate
protein (HSC70) acts as a cellular receptor for syncytium formation.
Using affinity chromatography with the peptide gp46-197, followed by
sodium dodecyl sulfate-polyacrylamide gel electrophoresis, we isolated
three components (bands A, B, and C) from MOLT-4 cell lysate which
exhibited specific interactions with gp46 and inhibitory activities for
syncytium formation induced by HTLV-1-bearing cells. Band A and B
components were identified as HSC70 and 
-actin, respectively,
through amino acid sequencing by tandem mass spectrometry and
immunostaining with specific monoclonal antibodies. Band C is likely to
be a nonprotein component, because full activity for syncytium
formation was seen after extensive trypsin digestion. Anti-HSC70
monoclonal antibody clearly blocked syncytium formation in a coculture
of HTLV-1-bearing cells and indicator cells, whereas no inhibition was
seen with anti--actin monoclonal antibody. Furthermore, flow
cytometric analysis indicated that anti-HSC70 antibody reacted with
MOLT-4 cells. Thus, we propose that HSC70 expressed on the target cell
surface acts as a cellular acceptor to gp46 exposed on the
HTLV-1-infected cell for syncytium formation, thereby leading to
cell-to-cell transmission of HTLV-1.
| |
INTRODUCTION |
Human T-cell lymphotropic virus type
1 (HTLV-1) is the causative agent of adult T-cell leukemia/lymphoma
(ATLL) (17, 32, 33, 47) and HTLV-1-associated
myelopathy/tropical spastic paraparesis (2, 14, 22, 30). In
addition, HTLV-1 has previously been implicated in causing other
diseases, including polymyositis (21) and uveitis
(28). Although HTLV-1 has previously been associated with
human malignancies which exhibit the CD4+ T-lymphocyte cell
surface phenotype (3, 15, 32), many human and mammalian
cells, including sarcoma cell lines (5, 19, 29, 48) and
epithelial and endothelial cells (18, 20), can be infected
by a cocultivation technique. The infectivity of cell-free HTLV-1 is
very low (4, 5, 29). These observations suggest that close
cell-to-cell interaction between HTLV-1-bearing cells and target cells
is important for transmission of the virus (46). Like many
other retroviruses, the cell-to-cell interaction between HTLV-1-bearing
cells and target cells also induces syncytium formation (19,
29). It is thought that these two phenomena are at least partly
based on the same mechanism and that the viral envelope glycoproteins
expressed on HTLV-1-bearing cells are primarily responsible for these
phenomena (6, 8, 31).
The receptor for HTLV-1 has previously been mapped to the long arm of
human chromosome 17 (37, 38), and the gene product of
approximately 30 to 31 kDa was identified as a cell surface receptor
for HTLV-1 (13). Several other candidate antigens have previously been suggested to be involved in HTLV-1 cell surface adhesion and syncytium formation; they include HLA A2 (7), interleukin-2 receptor (25), CD2 (9), membrane
glycoprotein C33 (11), and an 80-kDa membrane glycoprotein
(1). However, the identity of the HTLV-1 receptor has not
been determined. Previously, we reported that the peptide, referred to
as gp46-197, corresponding to amino acids 197 to 216 of the gp46
surface glycoprotein inhibited syncytium formation induced by
HTLV-1-bearing cells (34) and that this region served as a
binding domain for the interaction between gp46 and the trypsin
digestion-sensitive components in the MOLT-4 cell membrane, leading to
viral entry into the target cell (35). To identify cell
surface molecules involved in HTLV-1-induced syncytium formation, we
isolated three cellular components which are capable of inhibiting
syncytium formation induced by HTLV-1 by using affinity chromatography
with peptide gp46-197, followed by sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). In the
present study, we show that the 71-kDa heat shock cognate (HSC)
protein, HSC70, expressed on the target cell surface acts as a cellular
receptor for syncytium formation induced by HTLV-1.
| |
MATERIALS AND METHODS |
Cells and compounds.
The HTLV-1-bearing T-cell line used was
human T-cell line KT252, established from a patient with
ATLL in Kyushu University Hospital. The HTLV-1-negative cell line used
was the human T-cell line MOLT-4 (39). These cell lines were
cultured in RPMI 1640 medium supplemented with 10% fetal calf serum.
The mouse fibroblast cell line L-M(TK
) (Dainippon
Pharmaceutical Co., Osaka, Japan) was maintained in the Dulbecco
modification of Eagle's medium supplemented with 10% fetal calf
serum. Peptides were synthesized with a peptide synthesizer (model
431A; Applied Biosystems, Foster City, Calif.) by the
tert-butoxycarbonyl method, as described previously
(26). The purity of each peptide was examined by
reverse-phase high-performance liquid chromatography (Waters 626 pump
equipped with a 996 photodiode array detector; Millipore, Milford,
Mass.) with an octadecyl (C18) silicated column. Peptides
were isolated as single peaks. Mature gp46 and gp21 proteins (a
generous gift from H. Miyakoshi, Diagnostics Research Laboratory,
Fujirebio, Tokyo, Japan) were purified from culture fluids of
HTLV-1-producing TCL-Kan cells by immunoaffinity chromatography and gel
chromatography (27).
Syncytium formation assay.
The syncytium formation assay
consisted of a coculture of 2.5 × 104 HTLV-1-bearing
KT252 cells and 105 indicator MOLT-4 cells.
MOLT-4 cells were suspended in RPMI 1640 medium supplemented 10% fetal
calf serum and 0.5% normal human serum (hereafter referred to as RPMI
medium) at 5 × 106 cells per ml. Aliquots (20 µl
per well) were added to 155 µl of RPMI medium containing test samples
or medium alone in each well of a U-bottom 96-well plate (cell wells
25850; Corning Glass Works, Corning, N.Y.). Then 25 µl of
KT252 cell suspension (106 cells per ml of RPMI
medium) was added to each well. After incubation at 37°C for 18 h in a 5% CO2 incubator, the coculture medium was gently
mixed with a pipette and aliquots (40 µl of 200 µl of coculture medium) were transferred to 35-mm-diameter tissue culture dishes with a
2-mm grid (Nunc Inc., Naperville, Ill.). Syncytia containing more than
five nuclei were counted under an inverted microscope. In this assay
system, the HTLV-1-bearing cell line KT252 routinely formed
500 to 800 syncytia per 105 indicator MOLT-4 cells. All
experiments were performed in triplicate wells.
Isolation of cellular components.
Sepharose 4B coupled with
peptide was prepared by incubation of 3 mg of synthetic peptide and
0.6 g (dry weight) of cyanogen bromide-activated Sepharose 4B
(Pharmacia AB, Uppsala, Sweden) according to the manufacturer's
instructions. MOLT-4 cells (5 × 108) were disrupted
with 2 ml of 20 mM Tris-HCl buffer (pH 7.4) containing 2 µg (each) of
protease inhibitors (leupeptin, pepstatin, and aprotinin; Wako Pure
Chemicals, Osaka, Japan) per ml, 2 mM phenylmethylsulfonyl fluoride, 50 mM sucrose monocaprate (SM-1000; Dojin Kagaku, Kumamoto, Japan), 1 mM
dithiothreitol, 1 mM EDTA, and 150 mM KCl (hereafter referred to as
disruption buffer), and the supernatant was collected by centrifugation
at 11,000 × g for 20 min. After insoluble materials had been removed through a Sepharose 4B column (3 ml), the run-through fractions were applied to an affinity column (3 ml) coupled with gp46-197 and were washed extensively in succession with cell disrupting buffer, 10 mM phosphate buffer (PB) (pH 7.4) containing 10 mM sucrose
monocaprate, and PB containing 10 mg of the peptide (p19-100) corresponding to amino acids 100 to 130 of HTLV-1 p19 protein per ml as
a peptide-matched negative control. Subsequently, the materials that
bound the affinity column were eluted with PB containing 10 mg of
peptide gp46-197 per ml (hereafter referred to as gp46-197 eluate).
SDS-PAGE analysis.
The gp46-197 eluate was mixed with 30 µl of 250 mM Tris-HCl buffer (pH 6.7) containing 4% SDS, 0.05%
bromophenol blue, 50% glycerol, and 10% 2-mercaptoethanol and then
incubated for 2 min at 100°C. The reaction mixture was applied to a
12.5% polyacrylamide gel. After being run, the gel was cut into 2-mm
strips and homogenized in 400 µl of 10 mM phosphate-buffered saline
(PBS) (pH 7.2). After overnight incubation at 4°C, the supernatant (2 µl/well) was used to determine the activity for syncytium formation.
Molecular mass calibration curves were prepared with standard proteins,
including myosin heavy chain (200 kDa), phosphorylase B (97 kDa),
bovine serum albumin (BSA) (68 kDa), ovalbumin (43 kDa), carbonic
anhydrase (29 kDa), and -lactoglobulin (18 kDa).
Binding experiment with a plastic plate.
The wells of a
96-well microtiter plate (Nunc-Immuno Module Maxisorp; Nunc) were
coated with 1 µg of protein or peptide dissolved in 10 mM
NaHCO3 buffer (pH 9.55) and left overnight at 4°C.
Unreacted sites on the solid phase were blocked with 3% BSA (fraction
V; Sigma) in PBS for 3 h at room temperature. After six washings with PBS containing 0.05% Tween 20, samples (1 µl per well) were added to 100 µl of RPMI 1640 medium containing 20 mM HEPES (Sigma, St. Louis, Mo.) (pH 7.2) in each well and incubated for 3 h at 37°C. The supernatant was used to determine the activity for
syncytium formation.
Tandem mass spectrometry.
Acetamidation and
lysyl-endopeptidase digestion were carried out essentially as
previously described (23). After electrophoresis of the
gp46-197 eluate on a 12.5% polyacrylamide gel, the part of the gel
corresponding to protein bands was washed with distilled water,
homogenized in 400 µl of 20 mM Tris-HCl (pH 8.0) containing 1% SDS,
and allowed to stand overnight at 4°C. The supernatant was added to a
fivefold amount of ice-cold acetone, and the preparation was incubated
at 
80°C for 2 h. After centrifugation, the pellet was
dissolved in medium (pH 7.7) containing 8 M urea, 0.4 M
NH4HCO3, and 4 mM dithiothreitol, incubated at
50°C for 15 min, and then acetamidized with 12.5 mM iode acetamide
for 15 min at room temperature. Acetamidated protein was digested
overnight with 0.6 mU of lysyl-endopeptidase (Wako Pure Chemicals) at
37°C and stored at 20°C. The sample was applied to an LCQ mass
spectrometer (Finnigan MAT Instruments Inc., San Jose, Calif.),
equipped with a Monitor C18 column (2 by 150 mm; Column
Bioengineering, Ontario, Calif.) and eluted with a linear gradient for
40 min at a flow rate of 0.2 ml/min with buffer A containing 0.1%
acetic acid, 0.02% trifluoroacetic acid and buffer B containing 0.1%
acetic acid, 0.02% trifluoroacetic acid, and 90% acetonitrile. The
mass spectrum of peptide was assigned through database searches by
using the peptide sequence tag.
Immunochemical analysis.
gp46-197 eluates were analyzed by
SDS-PAGE (12.5% polyacrylamide gel). After blotting to a
polyvinylidene difluoride membrane (Millipore, Bedford, Mass.), the
sheet was incubated for 2 h in the presence of 5 µg of rat
anti-HSC70 monoclonal antibody (immunoglobulin G [IgG] fraction)
(SPA-815; StressGen, Victoria, Canada) or 100 µg of mouse
anti--actin monoclonal antibody (ascites fluid) (clone AC-15; Sigma)
per ml. In experiments for syncytium formation with monoclonal
antibody, serial dilutions of anti-HSC70 antibody (IgG fraction) and
anti--actin antibody (ascites fluid) were placed on 96-well
microtiter plates before the addition of infected cells and target
cells. For control experiments, we used monoclonal antibody BE11 (IgG
fraction or ascites fluid), which recognizes VP2 of human parvovirus
B19 (36).
Trypsin digestion.
Trypsin digestion was performed by
incubation for 1 h at 37°C in serum-free RPMI 1640 medium
containing 0.5 µg of trypsin (Sigma), and the reaction was stopped by
the addition of 1 µg of trypsin inhibitor (Wako Pure Chemicals). The
reaction mixture was used to determine the activity for syncytium
formation.
Flow cytometric analysis.
Cells (106 per tube)
were washed once with PBS containing 1% BSA, incubated with monoclonal
antibody on ice for 1 h, and then incubated with fluorescein
isothiocyanate-conjugated goat anti-rat IgG or anti-mouse IgG (MBL,
Nagoya, Japan). After being washed, cells were suspended in 1%
BSA-PBS and analyzed on a Cytoron Absolute (Ortho Diagnostic System,
Tokyo, Japan). Rat monoclonal antibody LAT 27, which recognizes the
region corresponding to amino acids 192 to 196 of gp46 (41),
was used as a control antibody.
| |
RESULTS |
Cellular components for syncytium formation.
To isolate
cellular components that interact with gp46 for syncytium formation
induced by HTLV-1, we disrupted MOLT-4 cells (5 × 108), which were used as target cells in syncytium
formation assays, with 2 ml of cell disruption buffer (pH 7.4). After
centrifugation, the supernatant (2.5 ml) was applied to a Sepharose 4B
column (3 ml) coupled with peptide gp46-197. For more specific elution of the materials that bound the affinity column, PB containing 10 mg of
peptide gp46-197 was used. The affinity column was washed extensively
in succession with cell disrupting buffer, PB containing 10 mM sucrose
monocaprate, and PB containing 10 mg of peptide p19-100 per ml as a
peptide-matched negative control. During these steps, we observed no
inhibitory activity for the syncytium formation of eluates.
Subsequently, the gp46-197 eluate was subjected to SDS-PAGE on a 12.5%
polyacrylamide gel. As shown in Fig. 1,
we observed three bands (bands A, B, and C) at positions corresponding to molecular masses of approximately 73, 43, and 34 kDa and inhibitory activities for syncytium formation in extracts from the gel
corresponding to each band. These observations suggest that components
in these bands are important for syncytium formation induced by HTLV-1.
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FIG. 1.
SDS-PAGE analysis of the gp46-197 eluate. (a) Protein
staining with 0.1% Coomassie brilliant blue. Arrows indicate the
positions of molecular size marker proteins. (b) Inhibitory activity
for syncytium formation in extracts from the gel. In the control
experiment, the rate of formation was 806 syncytia per 105
indicator cells. Data are estimates in comparison with the syncytium
count in a coculture without gel eluate and averages of triplicate
determinations. Standard errors are also shown.
|
|
Characteristics of cellular components.
To clarify the binding
specificity of each band, we performed absorption experiments on
96-well microtiter plates coated with mature gp46 and synthetic peptide
gp46-197. In these experiments, extracts corresponding to each band on
the SDS-PAGE gel were added to each well of the microtiter plate coated
with the protein or synthetic peptide. After the incubation of plates,
supernatants were used to determine the inhibitory activities for
syncytium formation (Fig. 2a). The
inhibitory activities of band A and C components were completely
eliminated by preincubation with gp46, whereas no decrease was seen
with gp21 or BSA as a negative control. Furthermore, the inhibitory
activity of the band B component was clearly reduced by preincubation
with gp46 for extracts with gp21 and BSA. These inhibitions were
equivalent to the findings for components preincubated with peptide
gp46-197, while no reduction was seen with p19-100 or gp21-400, which
corresponds to the functional domain (amino acids 400 to 429) of the
gp21 transmembrane protein (34) and served as a negative
control. These results indicate that these three components interact
specifically with the gp46 surface glycoprotein. We reported previously
that the gp46 surface glycoprotein interacted with trypsin
digestion-sensitive cellular component for syncytium formation
(35). Therefore, these three components were treated with
trypsin. The results of trypsin digestion on the inhibitory activity of
each component for syncytium formation is shown in Fig. 2b. The
inhibitory activities of band A and B components were remarkably
reduced by trypsin digestion, whereas no reduction was seen for the
band C component. These observations indicate that bands A and B carry
protein components with inhibitory activities for syncytium formation.
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FIG. 2.
Characteristics of the band A, B, and C components. All
data are the means of triplicate experiments. (a) Specificity of
binding to HTLV-1 proteins and peptides. The supernatant was used to
determine the inhibitory activity for syncytium formation. In control
experiments, the rate of formation was 822 syncytia per 105
indicator cells. (b) Effect of trypsin digestion on the inhibitory
activity for syncytium formation. The reaction mixture was used to
determine the activity for syncytium formation. In control experiments,
the rate of formation was 1,075 syncytia per 105 indicator
cells.
|
|
Identification of cellular components.
To identify the
molecules in bands A and B, amino acid sequencing of the proteins was
done by electron spray tandem mass spectrometry. The peptide extracts
produced by lysyl-endopeptidase digestion of the extracts from bands A
and B were applied to an LCQ mass spectrometer, equipped with a Monitor
C18 column, and eluted with a linear gradient for 40 min at
a flow rate of 0.2 ml/min with buffer A containing 0.1% acetic acid
and 0.02% trifluoroacetic acid and buffer B containing 0.1% acetic
acid and 0.02% trifluoroacetic acid, and 90% acetonitrile. As shown
in Fig. 3, the peptide ion spectrum of
the band A component showed multiple high-intensity peaks. The mass
spectrum of all 10 peptide peaks derived from this component was
assigned to a 71-kDa HSC protein (HSC70) through database searches by
using the peptide sequence tag. Immunostaining with antibody against
HSC70 supported this result. As shown in Fig.
4, the band A component in the gp46-197
eluate reacted with rat monoclonal antibody that recognizes HSC70 (IgG
fraction) (SPA-815; StressGen). The mass spectrum of peptides derived
from the band B component also showed multiple high-intensity peaks, of
which all peaks but one were assigned to -actin through database
searches (Fig. 5). The component in band
B reacted with mouse anti--actin monoclonal antibody (clone AC-15;
Sigma) that recognizes the N-terminal part of -actin (Fig. 4c). With
respect to the component in band C, the ion signal could not be
obtained by tandem mass spectrometry under our experimental conditions.
This supported the previous result of trypsin digestion of the band C
component.
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FIG. 3.
Sequencing of a peptide produced by lysyl-endopeptidase
digestion of the band A component. (a) Peptide ion spectrum. Peptide
peaks are numbered according to their identifications by tandem mass
spectrometry. (b) Deduced amino acid sequence of the peptide, as
determined by the partial sequences obtained by tandem mass
spectrometry.
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FIG. 4.
Immunostaining of band A and B components with
monoclonal antibodies to HSC70 and -actin. (a) Protein staining with
0.1% Coomassie brilliant blue. (b) Rat anti-HSC70 monoclonal antibody
(IgG fraction) (SPA-815; StressGen). (c) Mouse anti--actin
monoclonal antibody (ascites fluid) (clone AC-15; Sigma). The gp46-197
eluates were analyzed by SDS-PAGE (12.5% polyacrylamide gel). After
blotting to a polyvinylidene difluoride membrane, the sheet was
incubated for 2 h in the presence of 5 µg of anti-HSC70 antibody
or 100 µg of anti--actin antibody per ml.
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FIG. 5.
Sequencing of a peptide produced by lysyl-endopeptidase
digestion of the band B component. (a) Peptide ion spectrum. Peptide
peaks are numbered according to their identifications by tandem mass
spectrometry. (b) Deduced amino acid sequence of the peptide, as
determined by the partial sequences obtained by tandem mass
spectrometry.
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|
We obtained evidence that HSC70 and -actin are trypsin
digestion-sensitive components of the target cell, playing an important role for syncytium formation induced by HTLV-1-bearing cells. Our next
concern was whether these components are expressed on the cell surface.
Therefore, we examined the effect of monoclonal antibody to HSC70 or
-actin on syncytium formation. As shown in Fig.
6, syncytium formation was clearly
blocked by the addition of monoclonal antibody to HSC70; 83%
inhibition was seen at an antibody concentration of 1 µg per
105 MOLT-4 cells. In contrast, no blocking was seen with
anti--actin or BE11 as a protein-matched negative control.
Furthermore, flow cytometric analysis in the presence of monoclonal
antibody at a concentration of 1 µg per 105 cells
indicated that anti-HSC70 antibody reacted with MOLT-4 cells (Fig. 6b).
Seventy-three percent of MOLT-4 cells scored positive for anti-HSC70
antibody binding. On the other hand, only 15% of L-M(TK)
cells, previously reported to be resistant for infection by HTLV-1
(37), scored positive. These data suggest that HSC70 expression on the surfaces of HTLV-1-permissive MOLT-4 cells is greater
than that on nonpermissive or HTLV-1-resistant L-M(TK)
cells.
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FIG. 6.
Effects of monoclonal antibodies to HSC70 and -actin.
(a) Effect on syncytium formation. Serial dilutions of test antibodies
were placed on 96-well microtiter plates before the addition of
infected cells and target cells. For control experiments, we used
monoclonal antibody BE11 (IgG fraction or ascites fluid). In control
experiments, the rate of formation was 857 syncytia per 105
indicator cells. Data are estimates in comparison with the syncytium
count in a coculture without antibody and averages of triplicate
determinations. Standard errors are also shown.  , anti-HSC70;  ,
BE11 IgG fraction;  , anti--actin;  , BE11 ascites fluid. (b)
Flow cytometric analysis. Flow cytometric analysis was performed in the
presence of monoclonal antibody at a concentration of 1 µg per
105 cells. Rat monoclonal antibody LAT 27, which recognizes
amino acids 192 to 196 of gp46 (41), was used as a control
antibody.
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|
| |
DISCUSSION |
This work shows that the 71-kDa HSC protein expressed on the
target cell surface acts as a cellular receptor for syncytium formation
induced by HTLV-1-bearing cells. The receptor for HTLV-1 has previously
been mapped to the long arm of human chromosome 17 by infecting
mouse-human somatic cell hybrids with pseudotyped vesicular stomatitis
virus (HTLV-1) (13, 37, 38). However, recent work cells into
question the previous assignment of the HTLV-1 receptor to human
chromosome 17. By using an improved transient-transfection system,
Sutton et al. (40) showed that L-M(TK) cells,
previously considered to be nonpermissive for HTLV-1 infection, were
infected with pseudotyped human immunodeficiency virus (HTLV-1).
This suggest that the receptor for HTLV-1 has a considerably wider
cellular distribution than previously thought. The gene for HSC70
has previously been mapped to chromosome 11 (42), and its
gene expression was relatively low in L-M(TK) cells
(24). Those findings support the results in our study.
Syncytium formation between retrovirus-infected cells and target cells
is widely used to monitor virus-receptor interactions. The process
consists of several steps, including correct binding to the cellular
receptors of viral proteins, membrane fusion, and nuclei migration in
the syncytial cytoplasm. Accordingly, many cellular components,
including adhesion molecules, contribute to syncytium formation induced
by HTLV-1; perturbation of any of these steps is likely to disturb
syncytium formation. In the present study, we showed that -actin
itself inhibited syncytium formation induced by HTLV-1, but this
inhibition did not occur at the cell surface. We cannot readily explain
the role of -actin in syncytium formation. It is possible that the
inhibitory effect of -actin or syncytium formation is due to the
apparent binding of -actin to the gp46 expressed on the surfaces of
HTLV-1-bearing cells. Alternatively, the -actin in target cells may
act as an important cytoplasmic component for syncytium formation
involvement in the migration or positioning of gp46. This is consistent
with the involvement of actin-containing microfilaments in the
migration and positioning of nuclei in syncytia induced by infection
with parainfluenza virus (44). Further studies are needed
for conclusive demonstrations of such cellular cofactors.
The nature of the band C component is unclear. Band C is likely to be a
nonprotein component, because full activity for syncytium formation was
seen after extensive trypsin digestion. Our experimental results showed
that the band C component which allowed binding with gp46 had a
molecular mass of approximately 34 kDa by SDS-PAGE. Recently, Gavalchin
et al. (12) identified a monoclonal antibody which blocked
HTLV-1 binding, syncytium formation, and HTLV-1 infection. This
antibody reacted with antigens of approximately 30 to 31 kDa, which
were found only in a hybrid cell line containing human chrosome 17q
(13). We cannot readily explain the relationship between the
band C component presented here and the antigens obtained with hybrid
cell lines, because it is not clear whether the antigens are proteins.
To further understand the molecular nature of the band C component,
additional studies are under way to determine its fine structure.
HTLV-1 infection directly causes ATLL. However, infection with this
virus indirectly contributes to many other disorders, including
HTLV-1-associated myelopathy/tropical spastic paraparesis, polymyositis, and uveitis. Although the role of HTLV-1-infected cells
in these disorders is unknown, it is likely that an autoimmune mechanism mediated by HTLV-1 infection has an important role
(45). HSP70 family proteins have important intracellular
functions, including protein trafficking, oligomer assembly, binding to
damaged or aberrant proteins, and prevention of toxic aggregate
formation (16). Furthermore, recent experimental results
suggest the following possibilities for HSP and HSC protein functions
in the development of autoimmune disease: (i) the HSP or HSC protein
itself could act as a ligand to T-cell receptor 
-type cells
(10); (ii) the HSP or HSC protein itself could function as a
presenting molecule complexed with an endogenously derived cellular
peptide (43). This putative HSP or HSC protein function
would be analogous to that of major histocompatibility complex class I
molecules, and the expression of the HSP or HSC protein would be on the
cell surface. Although the roles of the HSC protein itself or HSC
protein-peptide complexes in a cellular immune response are unclear, it
is highly likely that the direct interaction between HTLV-1 and
putative cellular receptor HSC70 elicits numerous cellular responses.
Thus, the characterization of HSC70 expressed on the cell surface will profoundly increase our understanding of the pathogenesis of
HTLV-1-mediated diseases and provide certain insights into the host
range and cellular tropism of HTLV-1 in vivo and in vitro.
| |
ACKNOWLEDGMENTS |
We thank M. Kanai, Finnigan MAT Instruments Inc., for technical
assistance in amino acid sequencing with a tandem mass spectrometer and
M. Ohara for helpful comments on the manuscript.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Fukuoka Red
Cross Blood Center, 232-11 Kamikoga, Chikushino, Fukuoka 818, Japan.
Phone: 92-921-1400. Fax: 92-921-0799.
| |
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J Virol, January 1998, p. 535-541, Vol. 72, No. 1
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
