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Journal of Virology, February 2000, p. 1457-1467, Vol. 74, No. 3
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Adenovirus Types 11p and 35p Show High Binding
Efficiencies for Committed Hematopoietic Cell Lines and Are Infective
to These Cell Lines
Anna
Segerman,*
Ya-Fang
Mei, and
Göran
Wadell
Department of Virology, Umeå University, 901 85 Umeå, Sweden
Received 14 July 1999/Accepted 27 October 1999
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ABSTRACT |
Hematopoietic cells are attractive targets for gene therapy.
However, no satisfactory vectors are currently available. A major problem with the most commonly used adenovirus vectors, based on
adenovirus type 2 (Ad2) or Ad5, is their low binding efficiency for
hematopoietic cells. In this study we identify two adenovirus serotypes
with high affinity for hematopoietic cells. The binding efficiency of
prototype serotypes Ad4p, Ad11p, and Ad35p for different committed
hematopoietic cell lines representing T cells (Jurkat), B cells (DG75),
monocytes (U937-2), myeloblasts (K562), and granulocytes (HL-60) was
evaluated and compared to that of Ad5v, the commonly used adenovirus
vector, using flow cytometry. In contrast to Ad5v, which bound to less
than 10% of the cells in all experiments, Ad11p and Ad35p showed high
binding efficiency for all of the different hematopoietic cell lines.
Ad4p bound to the lymphocytic cell lines to some extent but less well
to the myelomonocytic cell lines. The abilities of the different
serotypes to infect, replicate, and form complete infectious particles
in the hematopoietic cell lines were also investigated by
immunostaining, 35S labeling of viral proteins, and
titrations of cell lysates. Ad11p and Ad35p infected the highest
proportion of cells, and Ad11p infected all of the cell lines
investigated. The Ad11p hexon was expressed equally well in K562 and
A549 cells. Jurkat cells also showed high levels of expression of Ad11p
hexons, but the production of infectious particles was low. The binding
properties of virions were correlated to their ability to infect and be expressed.
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INTRODUCTION |
The interest in adenoviruses is
partly due to the perspective of using them as vectors for gene
therapy. The hematopoietic system is a particularly suitable target for
gene therapy, as techniques for bone marrow and blood cell
transplantation are well established and the transductions can be
performed ex vivo. However, there are currently no suitable adenovirus
vectors available for this application.
Most adenovirus vector gene transfer systems are derived from
adenovirus serotypes 2 and 5 (Ad2 and Ad5) since they are the best
studied and nucleotide sequences are available for both (8, 43). However, vectors based on Ad2 or Ad5 are known to transduce resting hematopoietic cells with very low efficiency (5).
Adenovirus entry into host cells involves interactions with two
separate receptors. The fiber knob binds with high affinity to a
specific cellular attachment receptor (32); subsequent
interactions between the penton base RGD motif and 
v
integrins (second-step receptors) lead to endocytosis of the virus
(41) in clathrin-coated vesicles (11). The
coxsackievirus and adenovirus receptor (CAR) serves as the attachment
receptor for at least the subgenus C adenoviruses Ad2 and Ad5 (4,
38). Furthermore, soluble CAR protein has been shown to bind to
adenovirus serotypes from all subgenera except subgenus B
(33).
The adenovirus family consists of 49 known serotypes, which have been
divided into six subgenera (A to F) with distinctly different organ
tropisms. Although other factors may influence infectivity and
replication, the high-affinity attachment of virions to host cell fiber
receptors represents a key determinant in cell and tissue tropism. The
purpose of this study was to find adenovirus serotypes with tropism for
hematopoietic cells. The binding properties of Ad4p (prototype), Ad5v
(vector strain), and the subgenus B:2 viruses, Ad11p and Ad35p, to
committed hematopoietic cells were evaluated by flow cytometry. Ad4p
and Ad5v are epitheliotropic viruses causing airway infections, and
Ad11p and Ad35p have been described as causing infections of the
kidneys and urinary tract (20, 31). Many isolates from
patients with acute hemorrhagic cystitis after bone marrow or renal
transplants have been identified as Ad11p (25, 34). The
ability of these viruses to replicate and form new infectious particles
in hematopoietic cells was also investigated by immunostaining for
viral structural proteins, 35S labeling of proteins after
adenovirus infection, and titrations in A549 cells of lysates collected
at different time points after infection.
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MATERIALS AND METHODS |
Cell lines and culture conditions.
The cell lines used, all
of human origin, were as follows: Jurkat, an acute T-cell leukemia cell
line; DG75, established from a Burkitt's B-cell lymphoma; U937-2, from
a diffuse histiocytic lymphoma still expressing many monocyte-like
characteristics; K562, established from a chronic myelogenous leukemia
in terminal blast crisis; HL-60, from a promyelocytic leukemia with
phagocytotic activity; and A549, from a human oat cell carcinoma of the
lung. K562 was previously classified as an erythroleukemia line
(2), but more recent studies indicate that the cells are
multipotential blasts that spontaneously can differentiate into
progenitors of the erythrocytic, granulocytic, and monocytic series
(26). All hematopoietic cell lines were grown in RPMI 1640 containing 10% fetal calf serum (FCS), 20 mM HEPES, NaCO3
(0.75 g/liter), and 1× penicillin G (100 IU/ml)-streptomycin sulfate
(100 µg/ml) (PEST) at 37°C. They were split 1:5 to 1:10 when they
reached a concentration of about 1 million cells/ml, on average every
second to third day. A549 cells were grown in Dulbecco's modified
Eagle medium (DMEM) containing 5% FCS, 20 mM HEPES NaHCO3
(0.75 g/liter), and 1× PEST at 37°C; upon virus infection, the FCS
concentration was lowered to 0.5 to 1.0%.
Viruses.
The adenovirus serotypes used in this study, 4p
(RJ-67), 5v (pFG140), 11p (Slobitski), and 35p (S-761), were all typed
with respect to their restriction patterns (1). All
serotypes were raised in A549 cells and purified on CsCl gradients as
previously described (27).
Virus labeling.
The virions were desalted on a NAP-10 column
(Pharmacia Upjohn, Uppsala, Sweden) equilibrated in labeling buffer (50 mM NaHCO3, 2 mM MgCl2, 135 mM NaCl [pH 8.8]);
100 µl of N-hydroxysuccinimidobiotin (1 mg/ml; Sigma
Chemical Co., St. Louis, Mo.) in dimethyl sulfoxide was added to 1 ml
of the virions (1 to 4 mg/ml) (19). The solution was then
mixed on a rocker platform overnight at 4°C under dark conditions.
The buffer was then changed, and free biotin was removed by passing the
solution thorough a NAP-10 column equilibrated in phosphate-buffered
saline (PBS). The concentration of biotinylated virions was determined
by spectrophotometry at 260 and 330 nm. One unit of optical density at
A260 
A330 = 1012 particles/ml = 280 µg/ml of virions.
Glycerol was added to a final concentration of 10%, and the virions
were aliquoted in small volumes and kept at 70°C until used.
Binding experiments using a FACScan flow cytometer.
For each
binding experiment, 5 × 105 cells were used. The
cells were incubated with five different concentrations, 0.5, 1.0, 3.0, 6.0, and 10.0 pg/cell (corresponding to ca. 1,800, 3,600, 10,700, 21,400, and 35,700 particles/cell) of biotinylated Ad5v, Ad4p, Ad11p,
and Ad35p virions in a total volume of 100 µl of PBS supplemented
with 2% FCS and 0.01% NaN3 (PBS-FCS-NaN3) on a rocker platform at 4°C for 30 min. The cell samples were then washed in 150 µl of PBS-FCS-NaN3 buffer.
Streptavidin-fluorescein isothiocyanate (FITC; DAKO) in a dilution of
1:100 in PBS-FCS-NaN3 was then added, and the samples were
incubated for 30 min under the same conditions as before. The samples
were washed again and finally resuspended in 300 µl of
PBS-FCS-NaN3 buffer with an addition of propidium iodine (1 µg/ml) to exclude dead cells from the fluorescence-activated cell
sorting (FACS) analysis. Throughout the experiment, the samples were
kept on ice so that they never reached a temperature higher than 4°C,
making virus internalization very unlikely. The samples were evaluated
by a FACScan (Becton Dickinson) flow cytometer, and the measurements
consisted of 10,000 events per sample. The data were analyzed with the
LYSYS II software program (Becton Dickinson). Measurements of relative
mean fluorescence were corrected for autofluorescence of control cells.
Blocking experiments using a FACScan flow cytometer.
The
same cell lines as used in the binding experiments were incubated with
unlabeled Ad11p (5, 10, 20, and 40 pg/cell) for 30 min in 4°C before
addition of biotinylated Ad4p, Ad11p, and Ad35p. The amounts of
biotinylated viruses used per cell in all reactions were 1 pg of Ad11p
and Ad35p, 6 pg of Ad4p for DG75 cells, and 10 pg of Ad4p for Jurkat
cells. To reach an initial minimum binding of 25% of the cell
population, different concentrations of biotinylated Ad4p were used.
Immunostaining procedures.
Jurkat, DG75, U937-2, K562, and
HL-60 cells (3 × 105 of each cell line) were cultured
in a 24-well plate (2 cm2/well) in RPMI 1640 containing 2%
FCS. After inoculation with Ad4p, Ad5v, Ad11p, and Ad35p (each at 2 pg/cell), the cell cultures were incubated for 1 or 48 h at
37°C. The medium was then aspirated, and the cells were washed once
in PBS and allowed to dry. The cells were fixed in 100% ice-cold
methanol at 4°C for 10 min followed by incubation with the primary
antibody for 1 h at 37°C; as the primary antibody,
unfractionated serum from rabbits immunized with whole virions (Ad5v,
Ad4p, Ad11p, and Ad35p) was used at a dilution of 1:200 in PBS
supplemented with 0.1% bovine serum albumin (BSA). The cells were then
washed twice in PBS for 5 min each time and incubated with the
secondary antibody, an FITC-conjugated swine anti-rabbit immunoglobulin
G (DAKO), diluted 1:40 in PBS-BSA, for 30 min at 37°C. Again the
cells were washed as previously described and examined under a
fluorescence microscope. The stained cells were stored in PBS
containing 50% glycerol. Micrographs were taken at 200× enlargement.
[35S]methionine-cysteine labeling of proteins after
infection with Ad11p.
Jurkat, DG75, U937-2, K562, HL-60, and A549
cells (1.5 million of each cell line) were infected with 2 pg of Ad5v
and Ad11p virions per cell. Virions were adsorbed in a minimal amount
of medium, DMEM for A549 cells and RPMI 1640 for the hematopoietic cell
lines, containing 5% FCS for 90 min on a rocker platform. Unbound
viruses were then removed by washing with PBS. At 22 h postinfection (p.i.), the infected cell cultures were washed once with
PBS and incubated for 2 h in 2.5 ml of methionine- and
cysteine-free DMEM or RPMI 1640 (ICN Biomedicals, Inc.) containing 5%
FCS, 20 mM HEPES, and 1× PEST to deplete endogenous methionine and
cysteine. At 24 h p.i., the cells were labeled with 0.46 mCi of
Tran35S-label (1,175 Ci/mmol, 10.5 mCi/ml; ICN Biomedicals,
Inc.) per bottle. After labeling for 1 h, 26 µl of unlabeled
cysteine (200 mM) was added, after another 4.5 h 26 µl of
unlabeled methionine (100 mM) was added, and after labeling for 24 h both unlabeled methionine and unlabeled cysteine (26 µl of each)
were added to final concentrations of 2 and 4 mM, respectively. The
infected cultures were harvested at 72 h p.i. and washed twice in
0.1 M Tris-HCl (pH 8.0) containing 5 mM EDTA and 1 mM
phenylmethylsulfonyl fluoride. The cells were dissolved in 90 µl of
the same buffer, and the volumes were adjusted to 100 µl; 10 µl of
each sample (~250,000 cells) was taken for protein separation sodium
dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) on a 12% gel. The gel was Coomassie blue stained, dried, autoradiographed for 16 to 24 h, and also analyzed in a Molecular Dynamics PhosphorImager system. Two separate labeling experiments were performed.
Production of infectious particles in Jurkat, K562, U937-2, and
A549 cells.
Jurkat, K562, U937-2, and A549 cells (105
of each cell line) were incubated with Ad11p (0.2 pg/cell) for 1, 16, 48, 96, and 144 h. Duplicate samples for each time point were
used; after 1 h of adsorption in 200 µl of DMEM or RPMI 1640 containing 2% FCS on a rocker platform at 37°C, all samples were
washed twice in 1 ml of PBS and then given 1 ml of new medium. The
duplicates were pooled at the end of the incubation and freeze-thawed
three times. The lysates were diluted in 10-fold steps, inoculated in five parallel A549 cell tubes for each dilution, and read every second
day for 12 days.
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RESULTS |
Ad11p and Ad35p bind with high efficiency to lymphocytic and
myelomonocytic cell lines.
To compare the levels of binding of
Ad5v, Ad4p, Ad11p, and Ad35p to different committed blood cell
lineages, the continuous human blood cell lines Jurkat (T cells), DG75
(B cells), U937-2 (with monocyte-like characteristics), K562
(myeloblasts), and HL-60 (granulocyte-like) were used. Virus binding
was evaluated by flow cytometry at five different virus concentrations
(0.5, 1.0, 3.0, 6.0, and 10.0 pg/cell).
The two subgenus B:2 members, Ad11p and Ad35p, showed very efficient
binding to all cell lines investigated (Fig.
1
and 2) and had nearly identical binding
profiles (Fig. 2). They bound especially well to the two lymphocytic
cell lines (DG75 and Jurkat) and to myeloblasts (K562), monocytes
(U937), and granulocytes (HL-60) (listed in the order of descending
affinity). At a virus concentration of only 0.5 pg/cell, Ad11p and
Ad35p virions were bound to over 70% of DG75 and Jurkat cells, over
60% of K562 cells, and around 50% of U937-2 and 30% of HL-60 cells
(Fig. 2). At a virus concentration of 3 pg/cell, there was almost 100%
binding of Ad11p and Ad35p to all cell lines investigated. The most
commonly used adenovirus vector, Ad5v, exhibited a very low affinity
for all cell lines investigated. At the virus concentrations used, it
never bound to more than 10% of the cells of any cell line (Fig. 2).
Ad4p bound to the lymphocytic cell lines to some extent, but Ad4p and
Ad5v showed comparatively low affinity for the myelomonocytic cell
lines except perhaps for K562 cells (Fig. 1 and 2).
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FIG. 1.
Flow cytometry analysis of the human hematopoietic cell
lines Jurkat, DG75, U937, K562, and HL-60 exposed to 6.0 pg of
biotin-streptavidin-FITC labeled adenoviruses per cell to evaluate the
binding of various adenovirus serotypes to different hematopoietic
lineages.
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FIG. 2.
Binding of Ad4p, Ad5v, Ad11p, and Ad35p to hematopoietic
cell lines Jurkat (T cells), DG75 (B cells), K562 (myeloblasts), U937-2
(monocytes), and HL-60 (granulocytes), evaluated by flow cytometry
using biotin-streptavidin-FITC-labeled adenoviruses. Percentages of
virus-bound cells were plotted against virus concentration (0.5, 1.0, 3.0, 6.0, and 10.0 pg/cell). The results are presented as the
means ± 95% confidence interval of at least three independent
experiments.
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Ad11p and Ad35p uses the same, but Ad4p uses a different,
attachment receptor.
The binding profile of Ad4p was somewhat
different from those of the other adenoviruses studied, and we wanted
to test the hypothesis that Ad4p uses a different attachment receptor
than Ad11p and Ad35p. The subgenus B:2 adenoviruses Ad11p and Ad35p displayed very similar binding profiles, and we also wanted to determine whether they were binding to the same receptor. The different
cell lines were preincubated with unlabeled Ad11p virions up to 40 pg/cell, and then binding of biotinylated Ad11p and Ad35p (1 pg/cell)
and Ad4p (6 to 10 pg/cell) was investigated by flow cytometry as
before. Ad11p virions blocked the binding of Ad35p to all of the
investigated cell lines similarly to the self-blocking of the binding
(Fig. 3). Thus, they bind to the same receptor with similar affinities.
However, unlabeled Ad11p virions displayed no blocking effect on the
binding of Ad4p to the two lymphocytic cell lines. Surprisingly, there
was an increase in the binding of Ad4p after addition of Ad11p virions
(Fig. 3).
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FIG. 3.
Binding of biotin-streptavidin-FITC-labeled virions of
Ad11p, Ad35p, and Ad4p to various hematopoietic cell lines after
preincubation with unlabeled Ad11p. Flow cytometry was used to
determine the blocking effect of unlabeled Ad11p (5, 10, 20, and 40 pg/cell) on the binding of biotinylated Ad11p or Ad35p (1 pg/cell) or
biotinylated Ad4p (6 pg/cell for DG75 cell and 10 pg/cell for Jurkat
cells). Different concentrations of Ad4p were used to reach a minimum
initial binding of 25% of the cell population for both cell lines. The
results are presented as the means ± 95% confidence interval of
three independent experiments.
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Ad11p and Ad35p are more infectious to lymphocytic and
myelomonocytic cell lines than Ad4p and Ad5v.
To determine whether
the adenoviruses under study also were infectious to and could
propagate in the hematopoietic cells, immunostainings against viral
structural proteins were done on cultures of Jurkat, DG75, K562,
U937-2, and HL-60 cells 1 and 48 h after infection with Ad4p,
Ad5v, Ad11p, and Ad35p at a concentration of 2 pg/cell, which
corresponds to a multiplicity of infection (MOI) of 100 for Ad11p and
probably more for Ad5v (15). The original inoculum virus
could be detected on the cell surfaces of the hematopoietic cell lines
after 1 h of incubation, especially for adenovirus serotypes that
display high binding efficiency, as previously determined by FACS (Fig.
4).
However,
the location and intensity of the fluorescence became clearly different
after 48 h of incubation in cases of infection. The infected cells
were also in many cases larger than surrounding uninfected cells,
reflecting a cytopathogenic effect caused by the productive infection
(Fig. 4).
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FIG. 4.
Infectivity of Ad4p, Ad5v, Ad11p, and Ad35p in various
hematopoietic cell lines. Immunofluorescence with virion-specific
antisera was performed on cultures of Jurkat (a), DG75 (b), K562(c),
U937-2 (d), and HL-60 (e) cells 1 and 48 h after inoculation with
Ad11p, Ad35p, Ad4p, and Ad5v. Micrographs show immunostainings of cells
infected with 2 pg of adenoviruses per cell. NC, negative control
(uninfected cells). Representative micrographs were taken at 200×
enlargement.
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Ad11p and Ad35p were the serotypes most infectious to the hematopoietic
cell lines and thus infected the highest proportion
of cells of all
cell lines eventually except DG75. Ad11p and Ad35p
infected almost all
of the Jurkat cells and many K562 cells at
the dose given (Fig.
4a and
c). However, just a few DG75 or U937-2
cells produced viral structural
proteins, though capped uninternalized
virus particles could still be
detected on many uninfected cells
48 h p.i. (Fig.
4b and d). Only
one or two Ad11p antigen-positive
HL-60 cells were occasionally seen
per well (Fig.
4e). Ad11p was
the only serotype found to cause
productive infections in HL-60
cells. Ad4p and Ad5v structural proteins
could be detected primarily
in Jurkat and K562 cells and also in a few
DG75 cells but in neither
U937-2 nor HL-60 cells (Fig.
4). Jurkat and
K562 were thus the
cell lines most susceptible to infection by all
adenoviruses investigated,
whereas DG75, U937-2, and HL-60 (listed in
order of increasing
refractivity) were
refractory.
Ad11p structural proteins are highly expressed in Jurkat and K562
cells.
To confirm the immunofluorescence results and determine
which viral proteins were produced in the hematopoietic cell lines, Jurkat, DG75, K562, U937-2, and HL-60 cells were infected with Ad11p or
Ad5v (2 pg/cell) and pulsed with [35S]methionine and
[35S]cysteine 24 h p.i. A549 cells were infected
with the same amount of adenoviruses and pulsed for comparison with
expression in permissive epithelial cells. To distinguish the viral
proteins from cellular proteins, a mock-infected control of Jurkat
cells was included. Viral proteins of both serotypes could be detected
in Jurkat and K562 cells but not in the other cell lines (Fig.
5), which were found to be refractory to
adenovirus infection also in the immunofluorescence experiment. The
production of Ad5v hexons in A549 cells was more than sixfold higher
than that of Ad11p, indicating that the amount of virions added
corresponded to a higher MOI for Ad5v than for Ad11p (Fig.
6a). However, in the hematopoietic cell
lines the production of Ad11p hexon was about 30-fold higher in Jurkat
and 14-fold higher in K562 compared to the production of Ad5v hexon, which was the only detectable viral protein for Ad5v in both Jurkat and
K562 cells, clearly showing that Ad11p is more effectively expressed in
these cells (Fig. 6b). All of the main structural proteins of Ad11p
seemed to be produced both in Jurkat and K562 cells, although there
seemed to be a low production of protein III (penton base). In
addition, there was a viral or induced cellular band with an apparent
size of 78 to 79 kDa which was more than 2 times stronger in Jurkat
cells and 24 times stronger in K562 cells than in A549 cells (Fig. 5
and 6).
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FIG. 5.
Expression of viral structural proteins in Jurkat, DG75,
K562, U937-2, HL-60, and permissive A549 cells. Cultures of 1.5 million
cells of the different cell lines were infected with Ad11p or Ad5v (2 pg/cell) and pulsed with [35S]methionine-cysteine 24 h p.i. Equal amounts of cell lysates obtained from the different
cultures were separated by SDS-PAGE on a 12% gel and autoradiographed
for 16 to 24 h. Purified Ad11p and Ad5v separated on the same gel
were used to identify the viral structural proteins. The arrows show
the Ad11p structural proteins and the Ad5v hexon band, which was the
only Ad5v band detected in the hematopoietic cell lines. Mock-infected
Jurkat cells (negative control [NC]) were used to distinguish between
viral and cellular bands. *, the hexon band has apparent sizes of 120 kDa for Ad11p and 110 kDa for Ad5v (39).
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FIG. 6.
PhosphorImager analysis of Ad11p and Ad5v expression in
Jurkat, K562, and permissive A549 cells. The SDS-PAGE-separated
35S-labeled lysates of the cell lines infected with Ad11p
or Ad5v (Fig. 5) were also analyzed in a PhosphorImager system, and
values obtained from a representative experiment were normalized
against the value of the Ad11p hexon band in A549 cells. The values
were determined for hexons, the unknown 78- to 79-kDa protein and
actin.
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Cellular protein synthesis was more effectively turned off in A549
cells infected with Ad11p than Ad5v, despite higher production
of Ad5v
proteins in this cell line. In Jurkat cells, the cellular
proteins
became equally labeled in the Ad11p-infected culture
and the
mock-infected control. The actin band was about 10 times
stronger in
Jurkat than in A549 cells after Ad11p infection (Fig.
5 and
6b). The
immunofluorescence experiment indicated that almost
all Jurkat cells
became infected with Ad11p at an MOI of 100.
Thus, the level of labeled
cellular proteins, which was the same
as in the mock-infected control,
indicates that cellular protein
synthesis is not turned off in Jurkat
cells during Ad11p infection;
alternatively, cellular protein synthesis
is turned off later
during infection (Fig.
5).
Infectious Ad11p particles are produced to only a small extent in
Jurkat, K562, and U937-2 cells.
To investigate if any infectious
virions were produced in the hematopoietic cell lines, the lymphocytic
cell line Jurkat the myeloblastic cell line K562, and the monocytic
cell line U937-2 were chosen. In earlier experiments, Jurkat and K562
appeared to be permissive to Ad11p infection, while U937-2 cells were
refractory. We wanted to investigate if the production of particles was
as high in Jurkat and K562 as the expression of structural proteins would indicate and if there was any production of infectious particles in the refractory U937-2 cells. Cultures of Jurkat, K562, and U937-2
cells were incubated for 1, 16, 48, 96, and 144 h with Ad11p at an
MOI of 10. The samples were freeze-thawed, and the lysates were titered
in A549 cells. To obtain a reference system, A549 cells were incubated
in the same way. In Jurkat and K562 cells, the titer increased 2 and
2.5 logs, respectively, from ~4.0 log 50% tissue culture infective
doses (TCID50) at 1 h, which was the lowest point, to
5.8 and 6.5 log TCID50 at 144 h, respectively (Fig.
7). In U937-2, the lowest titer was obtained 48 h p.i.; from this
time point to 144 h p.i., the titer increased 1 log (Fig.
7). However, the total increase in titer
was only 0.5 log in the U937-2 cells. In A549 cells, the titer
increased to 9.4 log TCID50 after 144 h of incubation,
compared to 6.5, 5.8, and 4.5 log TCID50 in K562, Jurkat,
and U937-2 cells, respectively, which corresponds to at least
1,000-fold higher production of infectious particles in A549 cells than
in the hematopoietic cell lines (Fig. 7). The kinetics of the infection
in Jurkat, K562, and U937-2 cells was also delayed in comparison with
that in A549 cells. In A549 cells the production of complete virions
started before 16 h p.i. and peaked before 48 h p.i. In
Jurkat and K562 cells, the titer had increased by 48 h p.i., and
in U937-2 cells an increase in titer was not seen until 96 h p.i.
After 48 h p.i., the increase in titer was parallel in Jurkat,
K562, and U937-2 cells (Fig. 7). The production of infectious particles
was thus low and seemed delayed in the hematopoietic cell lines.
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FIG. 7.
Production of Ad11p infectious particles in Jurkat,
K562, U937-2, and permissive A549 cells. Cultures of 105
Jurkat, K562, and U937-2 cells were infected with Ad11p at an MOI of 10 (0.2 pg/cell) and incubated for 1, 16, 48, 96, and 144 h. The
cultures were freeze-thawed three times at the end of the incubation,
and endpoint titrations of the lysates were performed in A549 cells to
determine the production of infectious particles at the different time
points. To obtain a reference system, A549 cells were incubated in the
same way. The results are presented as the means ± 95%
confidence interval of at least two independent experiments.
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DISCUSSION |
The subgenus C serotypes Ad5 and Ad2, which most adenovirus
vectors are based on, have been reported to have very limited ability
to infect human leukocytes (3, 9, 13, 16, 35). This
nonpermissiveness of hematopoietic cells to subgenus C adenoviruses could be explained in part by the limited capacity of subgenus C
adenoviruses to bind to hematopoietic cells (9, 16, 35), which was also confirmed by our experiments. CAR, which has been shown
to function as a fiber attachment receptor for Ad2 and Ad5, has also
been found to be expressed at very low levels on resting peripheral
blood leukocytes (16, 18, 30, 35, 38). Fiberless vectors
have recently been created and found to have significantly reduced
infectivity, demonstrating the importance of the high-affinity fiber
binding to the target cell for the establishment of an infection (23, 44). Ectopic CAR expression has also been seen to be sufficient to render almost resistant lymphocytic cell lines
susceptible to subgenus C infection (24). In this study we
searched for and found adenovirus serotypes, namely, the subgenus B:2
serotypes Ad11p and Ad35p, that show remarkably high binding efficiency for all of the hematopoietic cell lines studied. The two lymphocytic cell lines Jurkat and DG75 cells seemed to express the highest amounts
of the subgenus B:2 receptor since Ad11p and Ad35p showed particularly
high binding to these cell lines. It has been known for a long time
that subgenus B uses a different attachment receptor than the subgenus
C adenoviruses (12, 14, 21, 36), and it has been shown that
the subgenus B adenoviruses cannot bind CAR (33). Therefore,
finding the receptor of these adenoviruses with apparent differences in
tropism would be valuable. Chimeric vectors expressing the fiber genes
or parts of these genes of Ad3 or Ad7 (subgenus B:1) have been created
(14, 21, 36) and shown to be more infectious than the
subgenus C adenoviruses to hematopoietic cells (36), in
accordance with what we have observed for the subgenus B:2 serotypes,
Ad11p and Ad35p. However, there could be two different subgenus B
attachment receptors since members of this subgenus can be further
divided into two different DNA clusters, B:1 and B:2, with tropism for
the respiratory and urinary tracts, respectively. Ad4p showed some
affinity for the two lymphocytic cell lines (DG75 and Jurkat) but not
for the myelogenous ones and thus expressed a pattern of binding
different from those of both Ad5v and the two subgenus B:2 serotypes
used in this study. Blocking experiments confirmed that Ad11p and Ad35p
share the same attachment receptor, which they bind to with similar
affinities although they have very different fiber compositions
(28, 29). However, Ad11p could not block the binding of Ad4p
to the lymphocytic cell lines, indicating that Ad4p uses a cellular
attachment receptor other than the receptor used by the subgenus B:2
adenoviruses, probably a receptor other than CAR since Ad5v showed no
affinity to any of the hematopoietic cell lines used in this study.
Ad4p has been shown to attach to the CAR protein (33) but
has not been proven to use this protein as its receptor, or as its only receptor. On the contrary, preincubation with Ad11p seems to increase the binding efficiency of Ad4p, especially to Jurkat cells. Since the
experiments were performed on ice, this phenomenon could hardly be
explained by receptor induction.
As expected, the binding properties of the serotypes studied correlated
with their abilities to infect and replicate in the hematopoietic cell
lines, as seen both in the immunofluorescence experiment, where Ad11p
and Ad35p infected the highest proportion of cells, and in the
[35S]methionine-cysteine labeling experiment, showing 10- and 30-fold higher expression of Ad11p hexons than Ad5v hexons in K562
and Jurkat cells, respectively. However, Ad11p and Ad35p are relatively uncharacterized serotypes, and there could be several additional differences between them and Ad5v that also account for their remarkably high expression in Jurkat and K562 cells. For example, it
has been shown that there are differences between subgenus B and
subgenus C in endosome lysis and route to the nucleus (6, 7,
12). The cell lines studied also differed significantly in
permissiveness to adenovirus infection. Jurkat cells and K562 cells
were much more susceptible to adenovirus infection than DG75, U937-2,
and HL-60 cells, as shown in the immunofluorescence and 35S
protein labeling experiments. Varying levels of permissiveness of
established hematopoietic cell lines to adenovirus infection have also
been observed by others (22, 40). Primary leukocytes are
known to express low levels of the adenovirus internalization receptors, v
3 and
v5 integrins. The nonpermissiveness of
these cells can be partly overcome by stimulation of the cells with several different stimulation protocols (5, 17, 18, 30), and
the activated cells have also been seen to upregulate the v3 and v5
integrins (5, 18). Adenovirus aggregates were found to be
trapped on surfaces of cells with low permissiveness and still
detectable at 48 h p.i. This would indicate that lack of
adenovirus internalization receptors is the major obstacle to
adenovirus infection in the refractory cell lines. Jurkat cells express
v3 and v5
integrins according to leukocyte typing VI (Becton Dickinson).
Different expression levels of the v3 and
v5 integrins may thus explain the highly
variable permissiveness observed by us and others between different
hematopoietic cell lines.
Although Jurkat and K562 cells seem susceptible to Ad11p infection, as
seen in both the immunofluorescence and 35S labeling
experiments, the production of Ad11p infectious particles is 1,000-fold
less than in A549 cells, indicating that virus replication is somehow
disturbed in these cells. The 35S labeling of viral
proteins shows that all of the major structural proteins seem to be
produced in both Jurkat and K562 cells, although protein III (penton
base) seems to be produced to a lesser extent in Jurkat and K562 cells
than in A549 cells. There is also a viral or induced cellular protein
with an apparent size 78 to 79 kDa that seems to be produced in excess
in both Jurkat and K562 cells. However, the penton base is not known to
have any precursor. The only viral protein migrating in this region
known to have a precursor is IIIa, which for Ad5 has an
apparent size of 67 kDa, and this precursor could be of a different
size for Ad11p. Faucon and coworkers detected an increase of the 64- to
66-kDa band in lymphoblastoid cell lines after infection with Ad5
(13). However, the 78- to 79-kDa protein appearing in Jurkat
and K562 cells after infection with Ad11p remains to be identified.
To summarize, hematopoietic cells seem to be semipermissive to Ad11p
and probably also other subgenus B:2 infections. From a vector
perspective this must be advantageous since the risk of getting
productive infections from leaky vectors will be reduced. These
findings regarding adenovirus serotypes with high binding efficiency
for hematopoietic cells we hope will contribute to the development of
more efficient gene delivery vectors in relation to hematopoietic
cells. The problems with cytotoxicity (10, 37, 42) observed
with the currently used adenovirus vectors, based on Ad2 or Ad5, will
probably be overcome by using a vector with high affinity for its
target since such a vector can be used in lower concentrations.
| |
ACKNOWLEDGMENTS |
This work was financed by grants from the Swedish Cancer Foundation.
We thank Eva Maria Fenyö, Karolinska Institutet, Stockholm,
Sweden, who gave us some of the hematopoietic cell lines.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Virology, Umeå University, 901 85 Umeå, Sweden. Phone: 46907852879. Fax: 4690129905. E-mail: Anna.Segerman{at}climi.umu.se.
| |
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Top
Abstract
Introduction
