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Previous Article | Next Article 
Journal of Virology, September 2000, p. 8582-8588, Vol. 74, No. 18
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Early Steps of Polyomavirus Entry into
Cells
Joanna M.
Gilbert* and
Thomas L.
Benjamin
Department of Pathology, Harvard Medical
School, Boston, Massachusetts 02115
Received 24 May 2000/Accepted 26 June 2000
 |
ABSTRACT |
The mechanism by which murine polyomavirus penetrates cells and
arrives at the nucleus, the site of viral replication, is not well
understood. Simian virus 40 and JC virus, two closely related members
of the polyomavirus subfamily, use caveola- and clathrin-mediated
uptake pathways for entry, respectively. The data presented here
indicate that compounds that block endocytosis of both caveola- and
clathrin-derived vesicles have no effect on polyomavirus infectivity.
Polyomavirus does not appear to colocalize with either clathrin light
chain or caveolin-1 by immunofluorescence microscopy. Additionally,
expression of a dominant-negative form of dynamin I has no effect on
polyomavirus uptake and infectivity. Therefore, polyomavirus uptake
occurs through a class of uncoated vesicles in a clathrin-,
caveolin-1-, and dynamin I-independent manner.
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INTRODUCTION |
Polyomavirus is a nonenveloped DNA
tumor virus that efficiently transforms cells in culture and induces
tumors in a wide variety of tissues in the mouse (11). A
great deal is known about the molecular biology of virus replication
and cell transformation (7), but the events leading to virus
internalization, routing to the nucleus, and virus disassembly remain
poorly understood. In its natural host, polyomavirus infects more than
30 distinct cells types (11). This wide host range depends,
in part, on the ability of the virus to bind nonselectively to cell
surface glycoproteins with terminal 
-2,3-linked sialic acid, which
are broadly and abundantly expressed in the mouse (5, 6).
The virus is composed of 360 copies of the major capsid protein VP1, which binds to cell surface sialyloligosaccharides. Discrimination between different sialic acid residues determines the ability of
different polyomavirus strains to successfully spread in the animal
(5). To date, specific, cell surface sialic acid-containing protein receptors have not been identified (5).
Early electron microscopic (EM) entry studies on polyomavirus and the
related virus simian virus 40 (SV40) demonstrated that shortly after
uptake, the majority of the virus was seen as single particles in
small, monopinocytic vesicles (~50 to 80 nm in diameter) that lack an
apparent protein coat (19, 23, 25). Virus was also seen as
multiple particles in larger vesicles variously described as phagocytic
vesicles, endocytotic vesicles, and, after longer incubation, tubular
membrane-bounded structures (13, 19, 20, 23, 25, 26). The
exact nature of the vesicles was not determined, but immunolocalization
indicated that the tubular membrane-bounded compartments containing
SV40 were endoplasmic reticulum (ER) derived (20).
More recent studies on the entry pathway of SV40 have shown that the
virus first binds to major histocompatibility complex class I molecules
and is then localized to specialized cell surface domains called
caveolae (37). SV40 is then taken up into caveola-derived vesicles as the first step in entry (2). Caveolae constitute specialized membrane domains composed of unique lipids, mainly sphingolipids and cholesterol, and of caveolins, the major protein component which binds to cholesterol. Caveolae form a large, dynamic membranous system that is important not only for transcytosis and
potocytosis but also for signal transduction (reviewed in references
3 and 36). Once SV40 is taken up
into cells, the SV40-containing vesicles may enter ER-derived tubules,
as described by Kartenbeck et al. (20), as part of the
potocytotic pathway between the ER and the plasma membrane via caveolae
(3). Whether polyomavirus is taken up into caveola-derived
vesicles and targeted to the ER in a fashion similar to that of SV40
has not been determined.
Interestingly, a recent study on another polyomavirus, the human JC
virus, demonstrated that entry of this virus into human glial cells is
disrupted by treatment with chlorpromazine (32). This
indicates that JC virus requires a functional clathrin-coated pit
endocytic pathway for successful uptake. With the obvious differences
between the internalization pathways of these two related viruses, SV40
and JC virus, it is not apparent what pathway polyomavirus uses to
enter cells. We have employed a combination of pharmacological and
biochemical approaches to begin to dissect the early steps in the entry
of polyomavirus into cells.
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MATERIALS AND METHODS |
Cells and viruses.
Primary baby mouse kidney (BMK) cells
were prepared and used 3 to 4 days after culturing. NIH 3T3 cells were
purchased from the American Type Culture Collection. Cells were
maintained in Dulbecco's modified Eagle's medium (DMEM; Sigma
Chemical Company, St. Louis, Mo.) containing 4.5 g of glucose per
liter, 10% heat-inactivated calf serum (CS; Life Technologies,
Gaithersburg, Md.), 100 IU of penicillin per ml, and 100 IU of
streptomycin (Life Technologies) per ml in a 5% CO2
humidified incubator at 37°C. Plasmids containing the cDNA for either
hemagglutinin (HA)-tagged wild-type dynamin I, or HA-tagged
dominant-negative dynamin I (K44A), under the control of a
tetracycline-responsive element, were a gift of S. Schmid (Scripps
Research Institute, La Jolla, Calif.). The pTEToff vector was purchased
from Clontech (Palo Alto, Calif.). A tetracycline-responsive, stable
NIH 3T3 cell line was established with this vector in accordance with
the manufacturer's instructions. Cells were then transfected with
either the wild-type or mutant plasmid and cotransfected with a plasmid
encoding resistance to puromycin (pBABE). Puromycin-resistant clones
were selected and examined for dynamin expression 48 h after
removal of tetracycline from the medium by indirect immunofluorescence assay (IFA) against the HA antigen as described below.
The RA strain of polyomavirus (small-plaque strain) used in this study
was propagated on BMK cells. For infectivity studies, a crude viral
lysate prepared by freeze-thawing and centrifugation of cellular debris
was used. For preparation of purified virus, CsCl equilibrium
centrifugation, done as previously described (9, 27), was
employed. Protein concentration was determined by the MicroBCA assay
(Pierce Chemical Company, Rockford, Ill.) and by measuring the ratio of
optical densities at 280 and 260 nm. Virus was titer was determined by
plaque assay.
Purified polyomavirus was labeled using a FluoReporter Oregon Green 488 Protein Labeling Kit (Molecular Probes, Eugene, Oreg.) in accordance
with the manufacturer's instructions. Oregon Green-labeled polyomavirus (OG-Py) was labeled with 208 fluorophores per virion as
calculated in accordance with the manufacturer's instruction. The
virus titer was examined by plaque assay and HA assay and was similar
to that of the parental virus.
Antibodies and reagents.
Fluorescein isothiocyanate
(FITC)-conjugated cholera toxin B subunit (FITC-Ctx), filipin,
tetracycline, puromycin, and 4',6'-diamidino-2-phenylindole (DAPI) were
purchased from Sigma. Oregon Green-conjugated transferrin (OG-Tfrn) was
purchased from Molecular Probes. Nystatin and chlorpromazine were
purchased from Calbiochem (San Diego, Calif.). The rabbit polyclonal
antibody to caveolin-1 was purchased from Transduction Laboratories
(Lexington, Ky.). The mouse monoclonal antibody to the HA antigen
(12CA5) was purchased from BAbCo (Berkeley, Calif.). The mouse
monoclonal antibody against the light chain of clathrin was a gift of
T. Kirchhausen (Harvard Medical School). Rabbit polyclonal antibodies
to polyomavirus large T antigen (PyLTAg) and VP1 were generated within
the laboratory. Oregon Green-conjugated goat anti-rabbit or anti-mouse
immunoglobulin G and rhodamine-conjugated goat anti-rabbit or
anti-mouse immunoglobulin G were purchased from Molecular Probes.
Indirect IFA.
After the desired incubation time, cells were
fixed in 3.5% paraformaldehyde (PFA; Electron Microscopy Sciences, Ft.
Washington, Pa.). Samples were permeabilized by treatment with either
0.1% Triton X-100 (Sigma) in phosphate-buffered saline containing 1% CS for examination of either caveolin-1 or clathrin or by incubation in
ethanol-acetic acid (2:1) for examination of PyLTAg. Samples were
incubated with the primary antibody in phosphate-buffered saline with
1% CS for 1 h at room temperature. Samples were incubated with
either Oregon Green- or rhodamine-labeled secondary antibodies and DAPI
and incubated for 1 h at room temperature. The washed coverslips
were mounted with Moviol, sealed with nail polish, and examined by
fluorescence microscopy using a Leica MSP60 DMLB microscope with a
100× Plan oil objective coupled to a Sony DCK-5000 camera. Images were
then imported and prepared in Adobe Photoshop 5.5.
Infectivity assay.
For analysis of polyomavirus infectivity,
cells were plated on 12-mm glass coverslips and grown to approximately
80% confluency at 37°C in a CO2 incubator. Cells were
pretreated with various compounds, described below, as indicated.
Stocks of polyomavirus (RA strain) whose titers had been determined by
plaque assay were diluted in DMEM without bicarbonate
(HCO3
) containing 2% CS and buffered with 10 mM HEPES (pH 5.4) or another appropriate buffer as indicated below.
Cells and virus were incubated from 60 min to 3 h for BMK and NIH
3T3 cells, respectively, at 37°C in a CO2 incubator, and
then virus was removed by aspiration. Extracellular virus was
neutralized by the addition of anti-VP1 antibody A3 in DMEM with 2%
CS, with or without the indicated compounds, and incubated for an
additional 30 min at 37°C. Virus was allowed to replicate for 24 h at 37°C. Successful entry was assessed by nuclear expression of
PyLTAg by IFA as described above. Data are presented as the percentage
of the total nuclei counted that were PyLTAg positive. Duplicate
samples were tested, and 500 nuclei were counted per sample.
To disrupt caveola-mediated uptake, cells were treated with the
indicated concentrations of either nystatin or filipin for 1 h to
3 h at 37°C in a CO2 incubator prior to infection.
To neutralize the endosomal pH, cells were pretreated with increasing
concentrations of NH4Cl (1 to 25 mM) for 30 min at 37°C.
Effective neutralization was determined by treatment of samples with
acridine orange and fluorescence microscopic examination (4)
prior to infection with virus. Cells were also pretreated with
increasing amounts of chlorpromazine for 60 min at 37°C in a
CO2 incubator. Virus was diluted in medium with or without
chlorpromazine and incubated with cells for 60 min to 3 h at
37°C prior to neutralization of extracellular virus. To disrupt
clathrin-mediated uptake by incubation in hypertonic medium, cells were
incubated with medium alone or 0.45 M sucrose in DMEM for 10 min at
37°C in a CO2 incubator. Virus was diluted into either
medium alone or sucrose-containing medium and allowed to infect cells
at 37°C for 60 min to 3 h. Disruption of clathrin-mediated
endocytosis by cytosol acidification was achieved by the protocol
described by Sandvig et al. (34). Cells were pretreated with
or without 50 mM NH4Cl for 30 min at 37°C and then
incubated in amiloride-K+-containing buffer or buffer
without amiloride for 30 min at 37°C in a CO2 incubator.
Virus was diluted into either buffer alone or amiloride buffer and then
incubated for 60 min to 3 h at 37°C, and then extracellular
virus was neutralized.
Uptake assays.
To analyze the uptake of FITC-Ctx, cells on
coverslips pretreated as described above for the infectivity studies
were chilled on ice for 10 min and then incubated with 4 µg of toxin
per ml on ice for 30 min. The cells were washed three times with cold medium and then incubated at 37°C in a CO2 incubator for
30 min. At the assay endpoint, samples were fixed in 3.5% PFA and then processed for IFA against caveolin-1 as described above. To analyze uptake of OG-Tfrn, cells that had been plated and grown to 80% confluency on 12-mm glass coverslips were preincubated in DMEM containing 1% defatted bovine serum albumin (DMEM-BSA; Sigma) for
1 h at 37°C in a CO2 incubator to deplete cells of
extracellular transferrin. The agents filipin, nystatin,
NH4Cl, and chlorpromazine were included in the DMEM-BSA as
indicated. For cytosol acidification, the protocol was initiated on
cells after transferrin depletion. Incubation with sucrose or NaCl was
performed in DMEM-BSA for 10 min after the initial 1-h incubation for
transferrin depletion. Cells were chilled on ice for 10 min, and then
40 µg of OG-Tfrn per ml in DMEM-BSA, in the presence or absence of
the indicated compounds, was added, and the mixture was incubated on
ice for 30 min. Cells were washed three times with cold medium and then incubated at 37°C in a CO2 incubator in DMEM-BSA, with or
with compounds, for 30 min. The coverslips were then fixed in 3.5% PFA
and analyzed for uptake and clathrin light-chain protein by IFA as
described above.
Entry assay.
To assess entry of labeled polyomavirus into
cells, OG-Py in DMEM-2% CS without HCO3 was
added to prechilled cells. Virus was allowed to bind for 60 min at
4°C. Unbound virus was removed by aspiration, and cells were washed
with cold DMEM-2% CS with HCO3 and then
incubated at 37°C in a CO2 incubator. Samples were then fixed in 3.5% PFA and processed for IFA as described above at the
indicated times.
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RESULTS |
Role of caveolae in polyomavirus internalization.
In order to
dissect the primary steps in the pathway of polyomavirus entry into
cells, we first examined the nature of the vesicles in which
polyomavirus particles are taken up. Since the closely related virus
SV40 employs caveolae for entry into cells, we wanted to determine
whether caveolae play a role in polyomavirus entry as well. The
sterol-binding compounds nystatin and filipin disrupt caveola function
by selectively removing cholesterol from the membrane, resulting in
caveolin-1 dissociation from caveolae (33). Nystatin
treatment blocks SV40 infectivity (1), presumably by
disrupting caveola function and preventing virus uptake. The effect of
nystatin on the caveolin-1 in BMK and NIH 3T3 cells was first assessed
by indirect IFA. Cells treated with nystatin showed that caveolin-1
withdrew from the cell surface, as indicated by the loss of the sharp
staining at the edges of the cells (Fig. 1a and b, A versus
C). The caveolin-1 appeared to relocalize
to an intracellular site, possibly the ER (8, 35) or the
trans-Golgi network (21, 28, 35), as indicated by the
stronger intracellular staining seen in NIH 3T3 cells (Fig. 1a, A
versus C) and the more punctate staining seen in the BMK cells (Fig.
1b, A versus C). The effect on endocytosis of this relocalization of
caveolin-1 upon treatment with nystatin was examined by measuring
internalization of either OG-Tfrn to determine clathrin-coated pit
uptake or FITC-Ctx to determine caveola uptake. Cholera toxin B is
targeted to caveolae by its receptor, the ganglioside GM1
(31), and its uptake is blocked by these cholesterol-binding
compounds (30). Both NIH 3T3 and BMK cells treated with
nystatin could readily take up OG-Tfrn, indicating that this compound
had no effect on clathrin-mediated endocytosis (Fig. 1a and b, F).
Mock-treated NIH 3T3 and BMK cells took up FITC-Ctx, but cells treated
with nystatin did not contain large amounts of intracellular FITC-Ctx,
demonstrating the specificity of nystatin's effect on
caveolin-mediated uptake (Fig. 1a and b, B versus D).
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FIG. 1.
(a) Uptake of cholera toxin and transferrin into control
and nystatin-treated NIH 3T3 cells. NIH 3T3 cells were either mock
treated (A and B) or pretreated with nystatin (C to F) and then
incubated with either FITC-Ctx (A to D) or OG-Tfrn (E and F). Uptake of
FITC-Ctx is shown in panels B and D, and the corresponding
-caveolin-1 uptake is shown in panels A and C. Uptake of OG-Tfrn is
shown in panel F, and the corresponding -clathrin light-chain uptake
is shown in panel E. (b) Uptake of cholera toxin and transferrin into
control and nystatin-treated BMK cells. BMK cells were either mock
treated (A and B) or pretreated with nystatin (C to F) and then
incubated with either FITC-Ctx (A to D) or OG-Tfrn (E and F). Uptake of
FITC-Ctx is shown in panels B and D, and the corresponding
-caveolin-1 uptake is shown in panels A and C. Uptake of OG-Tfrn is
shown in panel F, and the corresponding -clathrin light-chain uptake
is shown in panel E.
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In a similar manner, BMK and NIH 3T3 cells were either mock treated or
treated with increasing concentrations of either nystatin or filipin
and incubated for 1 h at 37°C in a CO2 incubator.
Cells were then infected with polyomavirus in the presence or absence of the cholesterol-binding agents, as appropriate. After incubation at
37°C, extracellular virus was neutralized with antibody and further
incubated for 24 h at 37°C. Previous neutralization experiments with rabbit polyclonal antibody A3 indicated that approximately 90%
and of the virus has been endocytosed from the surface of BMK cells
within 30 min and 90% of the virus is off the surface of NIH 3T3 cells
within 3 h (data not shown). Therefore, BMK cells were neutralized
after a 30-min incubation with virus and NIH 3T3 cells were neutralized
after a 3-h incubation with virus. The effectiveness of polyomavirus
entry was assessed by an indirect IFA for nuclear PyLTAg. Neither
compound, even at the highest concentrations used (100 µg/ml for
nystatin and 10 µg/ml for filipin), had any effect on the ability of
polyomavirus to infect cells (Table 1).
Additionally, infecting the cells at a low multiplicity of infection to
lessen the risk of entry through a lower-specificity pathway
demonstrated that these compounds had no effect on polyomavirus uptake
(data not shown). Therefore, unlike SV40, polyomavirus does not require
functional caveolae to enter either BMK or NIH 3T3 cells.
Role of clathrin-coated pits in internalization of
polyomavirus.
To determine whether an acidic compartment is
required for polyomavirus infectivity, BMK and NIH 3T3 cells were
pretreated with increasing concentrations of NH4Cl to
neutralize the endosomal pH. Cells were infected in the presence of
these compounds for 1 to 3 h at 37°C. Any remaining
extracellular virus was neutralized, and the cells were further
incubated at 37°C for 24 h. Samples were assayed for productive
polyomavirus entry by examination of nuclear PyLTAg expression (Table
2). From these data, it is apparent that
polyomavirus does not require an acidic compartment, as
NH4Cl treatment had no effect on polyomavirus infectivity. These concentrations of NH4Cl are known to inhibit the
infectivity of low-pH-dependent viruses (24).
The major endocytic vesicle pathway in most cells is the
clathrin-coated pit route. Although previous EM studies on polyomavirus entry have never observed virus particles in coated pits, a recent study indicates that the closely related JC virus uses clathrin to
penetrate its host cells (32). To examine whether
clathrin-coated pit-mediated endocytosis plays a role in the entry of
polymavirus into cells, several approaches were taken. Unlike treatment
of cells with the cholesterol-binding agents, treatments that block uptake via clathrin have pleiotropic effects. To avoid
misinterpretation, we have used multiple approaches to disturb
clathrin-mediated endocytosis to determine whether clathrin is required
for polyomavirus entry. Firstly, BMK and NIH 3T3 cells were untreated
or treated with chlorpromazine, a cationic amphiphilic agent that
causes dissociation of both clathrin and the adapter proteins from the plasma membrane by preventing clathrin recycling (40), and
examined for the ability to take up OG-Tfrn. BMK cells tolerated the
drug only up to 5 µg/ml without lifting off the dish. Both untreated BMK and NIH 3T3 cells could take up OG-Tfrn (Fig. 2A and
B), and chlorpromazine treatment had no
effect on the uptake of FITC-Ctx (data not shown). In the cells that
were treated with chlorpromazine, the OG-Tfrn had a different, punctate
appearance (Fig. 2a and b, D) with less signal overall. Similarly,
clathrin light chain appears punctate in the treated samples compared
with the untreated samples (Fig. 2a and b, C versus A). This is similar
to what was reported by Pho et al. (32) and indicates that
chlorpromazine has interrupted normal uptake of transferrin.
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FIG. 2.
(a) Uptake of transferrin into control and treated NIH
3T3 cells. NIH 3T3 cells were either mock treated (A and B) or
pretreated with either chlorpromazine (C and D), hypertonic medium (E
and F), or acidified cytosol (G and H) and then incubated with OG-Tfrn.
OG-Tfrn uptake is shown in panels B, D, F, and H, and the corresponding
-clathrin light-chain uptake is shown in panels A, C, E, and G. (b)
Uptake of transferrin into control and treated BMK cells. BMK cells
were either mock treated (A and B) or pretreated with either
chlorpromazine (C and D), hypertonic medium (E and F), or acidified
cytosol (G and H) and then incubated with OG-Tfrn. OG-Tfrn uptake is
shown in panels B, D, F, and H, and the corresponding -clathrin
light-chain uptake is shown in panels A, C, E, and G.
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To examine whether chlorpromazine can disrupt the ability of BMK and
NIH 3T3 cells to allow polyomavirus entry, cells were pretreated with
increasing concentrations of the compound prior to infection. Treatment
with up to 10 µg/ml had no effect on the entry of polyomavirus into
NIH 3T3 cells, but this highest concentration appeared to be toxic to
BMK cells (Table 3). The next highest concentration of chlorpromazine, 5 µg/ml, had no effect on
polyomavirus infectivity in BMK cells (Table 3), as measured by PyLTAg
staining, indicating that disruption of clathrin-mediated endocytosis
has no affect on polyomavirus entry.
Another approach to disruption of the clathrin endocytic pathway is
incubation of cells in hypertonic medium. This results in the
dissociation of clathrin from the plasma membrane (14, 18).
BMK and NIH 3T3 cells were pretreated with medium alone or 0.45 M
sucrose in medium for 10 min, and then the ability of these cells to
endocytose OG-Tfrn was examined. Both NIH 3T3 and BMK cells were
blocked from uptake of OG-Tfrn compared with the untreated controls
(Fig. 2a and b, F versus B). Therefore, similar to what was seen with
chlorpromazine treatment, incubation of cells with hypertonic medium
blocked OG-Tfrn uptake. The sucrose hypertonicity treatment had no
apparent effect on the ability of polyomavirus to infect either NIH 3T3
or BMK cells (Table 4).
We next examined whether acidification of the cytosol can affect
polyomavirus infectivity. Cytosol acidification is thought to inhibit
clathrin-coated pit uptake (14, 17) while concomitantly upregulating other clathrin-independent endocytic pathways
(22). Both NIH 3T3 and BMK cells had a decrease in uptake of
OG-Tfrn, indicating a diminution in clathrin-mediated uptake (Fig. 2a
and b, H versus B). Neither NIH 3T3 nor BMK cells were blocked for polyomavirus infectivity (Table 4). Interestingly, both NIH 3T3 and BMK
cells showed modest increases in infectivity upon treatment that
acidified the cytosol (Table 4). This further confirms that clathrin-mediated endocytosis plays no role in polyomavirus entry. Additionally, it indicates that the vesicles that take up polyomavirus can be upregulated in response to cytosol acidification in these cells.
To visually examine the uptake of polyomavirus into cells using
fluorescence microscopy and whether polyomavirus colocalizes with
either clathrin or caveolin-1, purified, high-titer polyomavirus was
labeled with the fluorophore Oregon Green. The labeled virus (OG-Py)
retained a plaque titer equivalent to that of the unlabeled virus.
Examination of OG-Py by sodium dodecyl sulfate-polyacrylamide gel
electrophoresis and fluorescence analysis indicated that 67% (approximately 140 fluorophores per virus) of the label was
incorporated into the outer layer protein VP1, with the core proteins
VP2 and VP3 containing only 8% of the label. The remainder of the
Oregon green fluorophore appears to have labeled the histones
(approximately 50 fluorophores per virus; data not shown). The number
of fluorophores on VP1 should allow detection of single viral particles
by fluorescence microscopy, whereas the number of fluorophores on
histones would be just barely at the level of detection (Molecular
Probes, personal communication). OG-Py was bound to BMK cells in the
cold and was then taken up into cells after warming at 37°C. At the
indicated time points, cells on coverslips were fixed and the samples
were processed for IFA against either clathrin light chain or
caveolin-1. There was little or no obvious colocalization between OG-Py
and caveolin-1 or clathrin light chain (Fig.
3) at any of the time points examined.
Since antibody neutralization studies indicated that after 30 min at
37°C, greater than 90% of the virus was endocytosed (data not
shown), if the virus was taken up in either clathrin-coated pits or
caveolae, we would expect to see colocalization after the 30-min
incubation. Later time points did not shown any colocalization (data
not shown). These data further confirm the pharmacological data that
polyomavirus uses neither clathrin-mediated nor caveola-mediated vesicles for entry.
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FIG. 3.
OG-Py uptake into BMK cells. OG-Py was bound to cells at
4°C for 30 min. Unbound virus was removed by washing, and cells were
incubated at 37°C for the indicated times and then fixed and
processed for IFA against either -caveolin 1 (A to C) or
-clathrin light chain (D to F).
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Role of dynamin I in polyomavirus internalization.
Dynamin is a
molecule that is required for the formation and budding of
clathrin-coated and caveola-derived vesicles (15, 16, 29,
38). It has been shown to be required for the uptake of several
viruses that enter cells via clathrin-coated pits, Semliki Forest
virus, human rhinovirus type 14 (12), and adenovirus (39), but not required for the uptake of poliovirus
(12). A dominant-negative mutant form of dynamin I that
cannot bind or hydrolyze GTP (K44A) (10) has been shown to
block uptake of ligands using either clathrin-coated pits or caveolae
(10, 29). To examine whether dynamin plays a role in the
entry pathway of polyomavirus, stable NIH 3T3 cells expressing an
HA-tagged form of either dominant-negative K44A mutant dynamin or its
wild-type counterpart under the control of the Tet promoter were
established. At 48 h after removal of tetracycline, the ability of
NIH 3T3 cells expressing either wild-type or mutant dynamin I to take up either OG-Tfrn or FITC-Ctx was examined. Cells expressing the wild-type form of dynamin were able to take up both FITC-Ctx and OG-Tfrn (Fig. 4B and D). The cells that
were expressing the K44A mutant dynamin had significantly reduced
levels of uptake of both FITC-Ctx and OG-Tfrn (Fig. 4F and H). This
indicated that the K44A mutant dynamin was functioning in the
appropriate dominant-negative fashion, blocking uptake from both the
clathrin- and caveola-mediated pathways. When the ability of these
cells to be infected with polyomavirus was examined (Table
5), there was clearly little or no
difference between cells expressing the wild-type and mutant forms of
dynamin, as measured by PyLTAg staining. Even infecting cells with a
lower multiplicity of infection, in an effort to minimize uptake by any
possible less-specific entry pathway, did not alter the ability of
cells expressing the K44A mutant dynamin to be productively infected by
polyomavirus. This indicates that, similar to poliovirus
(12), polyomavirus uses some type of not well-characterized
vesicles to enter cells, the uptake of which is not disrupted by the
effect of a dominant-negative dynamin I.
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FIG. 4.
Uptake of cholera toxin and transferrin into wild-type
(WT) and K44A mutant dynamin I-expressing NIH 3T3 cells. NIH 3T3 cells
expressing either wild-type (A, B, E, and F) or K44A mutant (C, D, G,
and H) dynamin I were incubated with either FITC-Ctx (A to D) or
OG-Tfrn (E to H). Uptake of FITC-Ctx is shown in panels B and D, and
the corresponding -caveolin 1 uptake is shown in panels A and C. Uptake of OG-Tfrn is shown in panels F and H, and the corresponding
-clathrin light-chain uptake is shown in panels E and G.
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DISCUSSION |
The mechanism by which polyomavirus penetrates cells is not
clearly understood. Since the polyomaviruses, as a subfamily, are
closely related on a structural level and replicate within the nucleus,
it has usually been inferred that these viruses enter cells in a
similar fashion. Early EM studies with SV40 and polyomavirus indicated
that virus was taken up in small vesicles and possibly targeted to the
ER (13, 19, 20, 23, 25, 26). More recent studies imply that
caveola-derived vesicles are the vesicles required for SV40 uptake
(2). Surprisingly, studies on the human JC virus indicate
that this polyomavirus uses the clathrin-mediated endocytic pathway for
uptake into glial cells (32). From the data presented in
this paper, it now appears that murine polyomavirus uses yet another
type of vesicle pathway to enter cells. In both primary BMK cells and
NIH 3T3 cells, pharmacological experiments demonstrated that neither
clathrin-coated pits nor caveolae are required for polyomavirus
infectivity, implying that some other vesicle pathway is used for
uptake. Fluorescently labeled polyomavirus did not colocalize with
either caveolin-1 or clathrin light chain, giving further credence to
the idea that this virus does not use either type of coated vesicle for
entry into cells. This was validated by the demonstration that a
dominant-negative form of dynamin I, a K44A mutant form which is
required for the endocytosis of clathrin and caveola-derived vesicles,
had no effect on the ability of polyomavirus entry into cells. These
data, combined with studies concerning the entry of SV40 (2,
37) and human JC virus (32) into cells, indicate that
polyomaviruses, as a family, use a divergent set of endocytic vesicles
to accomplish the same goal of penetrating cells and reaching the
nucleus, the site of viral replication. How polyomavirus is routed to
the nucleus after entry remains an important subject of investigation.
| |
ACKNOWLEDGMENTS |
We thank T. Kirchhausen for the antibody against clathrin light
chain, R. Dowgiert for preparation of the primary BMK cells, and T. Lis
for help in the preparation of Fig. 3.
This work was supported by National Institutes of Health grants R35
CA44343 and PO1 CA50661. J. M. Gilbert is supported by training
grant 5T32CA72320 from the National Institutes of Health and by the
Bunting Fellowship Program at the Radcliffe Institute for Advanced
Study at Harvard University.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Harvard Medical
School Department of Pathology, 200 Longwood Ave., Armenise-233,
Boston, MA 02115. Phone: (617) 432-1998. Fax: (617) 277-5291. E-mail: jgilbert{at}hms.harvard.edu.
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Abstract
Introduction
