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Journal of Virology, January 2001, p. 480-489, Vol. 75, No. 1
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.1.480-489.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Functional and Selective Targeting of Adenovirus
to High-Affinity Fc
Receptor I-Positive Cells by Using a
Bispecific Hybrid Adapter
Christina
Ebbinghaus,1
Ahmed
Al-Jaibaji,1
Elisabeth
Operschall,2
Angelika
Schöffel,1
Isabelle
Peter,1
Urs F.
Greber,3 and
Silvio
Hemmi1,*
Institute of Molecular
Biology1 and Institute of
Zoology,3 University of Zürich, CH-8057
Zürich, and Institute of Medical Virology, University
of Zürich, CH-8028 Zürich,2
Switzerland
Received 1 June 2000/Accepted 29 September 2000
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ABSTRACT |
Adenovirus (Ad) efficiently delivers its DNA genome into a variety
of cells and tissues, provided that these cells express appropriate
receptors, including the coxsackie-adenovirus receptor (CAR), which
binds to the terminal knob domain of the viral capsid protein fiber. To
render CAR-negative cells susceptible to Ad infection, we have produced
a bispecific hybrid adapter protein consisting of the amino-terminal
extracellular domain of the human CAR protein (CARex) and the Fc region
of the human immunoglobulin G1 protein, comprising the hinge and the
CH2 and CH3 regions. CARex-Fc was purified from COS7 cell supernatants
and mixed with Ad particles, thus blocking Ad infection of CAR-positive
but Fc receptor-negative cells. The functionality of the CARex domain was further confirmed by successful immunization of mice with CARex-Fc
followed by selection of a monoclonal anti-human CAR antibody (E1-1),
which blocked Ad infection of CAR-positive cells. When mixed with Ad
expressing eGFP, CARex-Fc mediated an up to 250-fold increase of
transgene expression in CAR-negative human monocytic cell lines
expressing the high-affinity Fc
receptor I (CD64) but not in cells
expressing the low-affinity Fc receptor II (CD32) or III (CD16).
These results open new perspectives for Ad-mediated cancer cell
vaccination, including the treatment of acute myeloid leukemia.
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INTRODUCTION |
Adenoviruses (Ad) carrying
therapeutic genes are currently among the leading candidate vectors for
gene therapy and have been used to transduce numerous types of tissues
and cell lines, although with varying efficiency. The efficacy of Ad
entry is a major determinant of transgene expression. Entry of subgroup
C Ad, including the currently used Ad2 and Ad5, depends on a primary Ad
receptor, the coxsackie-adenovirus receptor (CAR) protein (5,
53). Secondary Ad receptors have earlier been identified as
v
3- and v5-type integrins (63).
While the primary receptor is responsible for virus attachment by
binding to the distal portion of the Ad fiber protein, the integrins
bind to the RGD motif of the capsid protein penton base, thus mediating
virus uptake into the cells by receptor-mediated endocytosis (56,
59). Binding assays using radiolabeled virions or purified fiber
protein demonstrated that different cell cultures express variable
amounts of primary Ad type C receptor(s) (12, 48, 63, 65).
In polarized epithelial cells, the availability of CAR seems to be a
limiting step to successful gene expression (58). CAR
expression levels also seem to be limiting in brain tissue
(10), skeletal muscle (1, 39), endothelial
and smooth muscle cells (65), and cells of hematopoietic
origin including human leukocytes (3, 27, 48). Furthermore, the expression levels of the primary receptor were found
to vary considerably among tumors of different origins, including
hematopoietic malignancies (9, 11, 18, 61), human melanoma
cell cultures (26), bladder cancer cells
(35), and ovarian tumors (30).
Even cells lacking CAR and/or v integrin expression can
be infected with high doses of vectors (reference 26 and
unpublished data). However, a more economical and reliable procedure is
to broaden the tropism of Ad vectors. The host range of Ad can be modified by three means: genetic or biochemical alterations of the Ad
fiber protein or the use of bifunctional reagents. Genetic alterations
include modifications of capsid fiber proteins, introducing new peptide
sequences into the HI loop of the fiber knob (13, 31, 42)
and insertion of a 10-amino-acid peptide linker sequence followed by
the integrin-binding RGD motif at the carboxy terminus of the Ad5 fiber
protein (66). Alternatively, the coding sequence for a
polylysine stretch can be inserted at the C-terminal end of the fiber
gene to allow binding to cells expressing heparin-binding motifs
(64). A different approach includes the exchange of fiber of the commonly used Ad2/5 serotype with fiber of alternative serotypes
such as Ad11 and Ad35 (20, 32, 41, 50), facilitating expression in hematopoietic cell lines (46) and with
moderate success also in CD34+ cells (47).
Biochemical alterations include the coupling of asialoglycoprotein-polylysine conjugates to wild-type Ad5
(67) or formulation of Ad complexes with polycationic
polymers and cationic lipids (17). In addition, bispecific
antibodies with specificities to v integrin
(65) or CD3 (62) and a second specificity to
a FLAG epitope inserted in the penton base have been reported. Finally,
bispecific proteins containing an Ad5 fiber-specific blocking antibody
either fused or chemically coupled with receptor target-specific
molecules like folate (15), epidermal growth factor (EGF)
(60), fibroblast growth factor (22), CD40 (51), and the pancarcinoma antigen EpCAM
(23), have been introduced.
In this study, we have produced a bispecific protein, CARex-Fc, with
defined specificities and high affinities to both Ad capsid and cell
surface Fc receptor I. The CARex-Fc fusion protein consists of the
ectodomain of CAR fused to the immunoglobulin Fc domain. The protein
was produced in COS7 cells and purified by affinity chromatography.
CARex-Fc efficiently blocked transgene expression of a recombinant Ad
expressing enhanced green fluorescent protein (eGFP) in A549 human lung
carcinoma cells. The CARex-Fc protein was tested for its ability to
redirect AdCMV-eGFP-mediated expression to cells lacking CAR
expression but expressing one of the Fc receptors. In cells
expressing high levels of the high-affinity Fc receptor I, CARex-Fc
led to an up to 250-fold increase of eGFP expression. Moderate eGFP
expression was obtained in cells with low levels of cell surface CD64
expression. No eGFP expression was obtained in cells expressing
the low-affinity Fc receptors II and III, demonstrating the
selectivity of CARex-Fc. In addition, the CARex-Fc fusion protein was
used for immunization of mice and selection of an Ad infection-blocking
monoclonal antibody specific for human CAR.
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MATERIALS AND METHODS |
Cell culture.
Cells were grown in RPMI 1640 plus 10% fetal
calf serum (FCS) unless indicated differently. Jurkat (acute T-cell
leukemia), U937 (D) (monocytic lymphoma), Daudi (Burkitt's
B-lymphoma), and K562 (chronic myelogenous leukemia) cells were
provided by F. Nestle, Department of Dermatology, University of
Zürich, Zürich, Switzerland. HL-60 (promyelocytic leukemia)
cells were obtained from A. Ziogas, Medical Virology, University of
Zürich. Raji (Burkitt's B-lymphoma) cells were obtained from O. Georgiev, Institute of Molecular Biology, University of Zürich.
U937 (H) (monocytic lymphoma), THP-1 (acute monocytic leukemia),
Kasumi-1 (acute myeloid leukemia [AML]), and SigM5 (AML) cells, as
well as primary AML cells were kindly provided by G. Schoedon and
Peghini, Department of Medicine, University of Zürich. THP-1
cells were cultured in Iscove modified Dulbecco medium (IMDM) plus 10%
FCS, whereas SigM5 cells were propagated in IMDM plus 20% human serum.
All cell lines were originally purchased from the American Type Culture Collection, with exception of Kasumi-1 (Department of Human and Animal
Cell Cultures, Deutsche Sammlung von Mikroorganismen und Zellkulturen,
Braunschweig, Germany) and SigM5 (57). Primary patient AML
cells were isolated using the standard therapeutic leukapheresis
procedure after obtaining informed consent, typed, and frozen in IMDM
plus 50% pooled human serum. Short cultures of 2 days were performed
in IMDM plus 10% FCS. Natural killer cells were isolated as described
elsewhere (45) from the blood of healthy volunteers and
were propagated in AIM-V medium containing 10% human serum, 10%
leukocyte-conditioned medium (LCM), 2% HEPES, 1% sodium pyruvate, 1%
glutamine, 1% nonessential amino acids, 1% penicillin-streptomycin
and 100 U of interleukin-2 per ml. Human 911 cells were received from
Fallaux et al. (16) and grown in Dulbecco's modified
Eagle's medium (DMEM) plus 10% FCS. COS7 cells were kindly provided
by S. Nagata, Osaka University, Osaka, Japan, and were grown in low-FCS
medium (TurboDoma containing 1% FCS; Cell Culture Technologies,
Gravesano, Switzerland). DO4 cells producing CTLA4-immunoglobulin G1
(IgG1) fusion protein specific for B7 (14) were obtained
from R. Dummer, Department of Dermatology, University of Zürich,
and were grown in DMEM plus 10% FCS. The A549 human lung carcinoma
cell line was received from P. Sonderegger, Biochemisches Institut,
University of Zürich, and was grown in DMEM plus 10% FCS. All
cell lines were routinely screened for the absence of mycoplasma contamination.
Construction of pCMV1-CARex-Fc.
The pCMV1-Fc expression
plasmid was originally constructed and kindly provided by X. He,
Children's Hospital, Harvard Medical School, Boston, Mass.
(unpublished results). The plasmid contains a 699-bp Fc fragment
derived from the human IgG1 cDNA, encoding the hinge, CH2, and CH3
regions, which was amplified by the use of sequence-specific primers
and PCR. In addition to the polylinker, the plasmid contains the human
cytomegalovirus (CMV) enhancer/promoter, a polyadenylation sequence of
the human growth hormone, and a simian virus 40 origin of replication.
The sequence encoding the first 236 amino acids of the extracellular
domain of human CAR (including the endogenous Kozak motif and the
N-terminal signal sequence) was amplified from cDNA synthesized from
total RNA of 911 cells by using synthetic oligonucleotides corresponding to the published sequence (5). The PCR
product was digested with HindIII and Xbal to
allow in-frame fusion to the human IgG1-Fc sequence. The fusion
junctions were verified by sequencing.
PAGE and Western blotting.
For analysis of the CARex-Fc
protein, COS7 cells were transiently transfected as described elsewhere
(24). To reduce the levels of unrelated proteins, the
medium from transfected COS7 cells was replaced 1 day after
transfection with TurboDoma medium lacking FCS. Supernatants of
transfected cells and purified CARex-Fc protein were analyzed by
polyacrylamide gel electrophoresis (PAGE) (33) followed by
Coomassie blue staining or by Western blotting of electrotransferred
protein to Immobilon-P membranes. Membranes were saturated in
Tris-buffered saline plus 0.1% Tween 20 (TBS-T) containing 5% dry
milk and incubated with fluorescein isothiocyanate (FITC)-conjugated
rabbit anti-human IgG (Dako, Copenhagen, Denmark) for 1 h.
Immunoreactivity was scored using a Fluoroimager 595 (Molecular
Dynamics, Amersham, Berkhamsted, United Kingdom).
For analysis of CAR protein, cells were lysed in NETN (10 mM Tris [pH
8.0], 200 mM NaCl, 1 mM EDTA, 0.5% NP-40) containing
1 mM
phenylmethylsulfonyl fluoride. Protein concentrations were
determined
using the bicinchoninic acid assay (BCA; Pierce, Rockford,
Ill.), and
protein separation was performed by sodium dodecyl
sulfate (SDS)-PAGE
(10% polyacrylamide) under nonreducing conditions.
After transfer to
Immobilon-P membranes, the blots were blocked
in 5% dry milk in TBS-T,
and incubated with mouse monoclonal antibody
E1-1 (1:20 dilution of
hybridoma supernatant) for 1 h and then
with horseradish
peroxidase-conjugated goat anti-mouse IgG (Boehringer
Mannheim
Biochemicals, Indianapolis, Ind.) for 1 h. Immunoreactivity
was
determined using the enhanced chemiluminescence Western blotting
detection system
(Amersham).
CARex-Fc protein purification.
Low-FCS supernatant
containing CARex-Fc protein was adsorbed to protein G-Sepharose
(Amersham Pharmacia). Following washing with phosphate-buffered saline
(PBS), bound protein was eluted using 0.15 M glycine-HCl (pH 2.8) and
immediately neutralized with 1 M Tris (pH 9.5). Eluted material was
concentrated using centrifugal filter devices (Millipore, Bedford,
Mass.), dialyzed against PBS, and kept frozen in aliquots. The protein
concentration of purified CARex-Fc was determined by the BCA assay.
Immunization and hybridoma production.
BALB/c mice were
injected twice intramuscularly with 30 µg of the pCMV1-CARex-Fc
expression plasmid at 2-week intervals followed by a single 100-µg
injection after 2 weeks. Sera from tail veins were tested by
cytofluorometric analysis for the presence of anti-CAR antibodies. The
mice were further boosted with one injection of a protein-adjuvant mix
(270 µg of CARex-Fc mixed with 270 µg of polyadenylic-polyuridylic
acid adjuvant [Sigma, St. Louis, Mo.]) after an additional 2 weeks
and then 2 weeks later with an injection of 100 µg of protein without
adjuvant 3 days before cell fusion. Spleen cell preparation and fusion
with P3-X63Ag myeloma cells (a kind gift from H. Hengartner,
Experimental Immunology, University of Zürich, Zürich,
Switzerland) were performed as described previously (25).
Supernatants of HAT (Gibco-BRL)-resistant colonies were screened by a
cytofluorometric assay using 911 cells. The isotype of the E1-1
antibody was determined to be mouse IgG1, using a hemagglutination test
(Serotec, Oxford, United Kingdom). For purification of E1-1 antibody,
the hybridoma cells were cultured in TurboDoma medium and antibody was
isolated by protein G-Sepharose chromatography as described above.
Immunoreagents and flow cytometric analysis.
CTLA4-IgG1
fusion protein specific for B7 (14) was produced and
purified as described for E1-1 antibody. The mouse monoclonal antibody
RmcB specific for human CAR (5) was provided by R. Finberg, Dana-Farber Cancer Institute, Boston, Mass. FITC-labeled anti-human CD16 (30624X), CD32 (30934X), and CD64 (31844X) and appropriate isotype controls were purchased from Pharmingen, San Diego,
Calif., and secondary fluorochrome conjugates were purchased from Serotec.
For cytofluorometric analysis of adherent 911 cells, subconfluent cells
were washed with PBS and detached by treatment with
PBS-20 mM EDTA.
Approximately 10
6 cells were incubated with either 50 µl
of hybridoma supernatant
or 1 µg of various antigen-specific
antibodies in 250 µl of balanced
salt solution (BSS)-5% FCS (BSS is
0.14 M NaCl, 1 mM CaCl
2, 5.4
mM KCl, 0.8 mM
MgSO
4, 0.3 mM NaH
2PO
4, and 0.4 mM
KH
2PO
4 [pH 6.9])
for 30 min on ice. If
unlabeled primary antibodies were used,
the cells were washed by
pelleting in BSS-2% FCS, incubated with
1 µg of
phycoerythrin-labeled secondary conjugates, and washed
again before
being subjected to cytofluorometric analysis (Epics
XL; Coulter, Miami,
Fla.). Fluorescence-activated cell sorter
(FACS) measurements were
performed with 10,000 viable cells per
sample. For eGFP expression
analysis, A549 cells were transduced
with AdCMV-eGFP and 2 days later
the cells were detached and washed
as described above. To analyze
whether Ad binding competed with
E1-1 binding to 911 cells, cells were
detached, incubated with
increasing amounts of AdCMV-muB7-1 for 60 min
on ice, washed,
and stained with E1-1 as described
above.
Recombinant Ad vectors and inhibition of Ad-mediated cell
transduction.
Recombinant E1- and E3-deleted Ad vectors were
constructed and CsCl purified as described previously
(26). Viral titers were determined by incubating 2 ml of
medium on 911 cell layers in six-well plates (e.g., 6 × 109 PFU/ml for AdCMV-eGFP [kindly provided by C. Kuhl,
Institute of Molecular Biology, University of Zürich,
Zürich, Switzerland] and 1.2 × 1010 PFU/ml for
AdCMV-muB7-1, expressing the mouse B7-1 transgene). The virion
concentration of AdCMV-eGFP was determined by the method of Maizel et
al. (37) and found to be 3.4 × 1011
particles/ml.
For transduction inhibition assays using E1-1 or CARex-Fc, A549
monolayer cultures were grown to 30% confluence in six-well
plates.
For E1-1 blocking assays, the medium was replaced with
0.5 ml of E1-1
hybridoma supernatant or with binding medium (PBS
plus DMEM-10% FCS,
1:1 mix) containing purified E1-1 and the cells
were incubated on a
rocking platform for 2.5 h on ice. Reporter
AdCMV-eGFP was added
at a multiplicity of infection (MOI) of 100,
and the cells were
incubated for an additional 2.5 h on ice. They
were then washed
twice with cold binding medium, and normal cell
culture medium
including E1-1 antibody or control antibody was
supplied, followed by
incubation for 2 days at 37°C in a CO
2 incubator.
To
assay CARex-Fc-mediated blocking, purified CARex-Fc protein
was mixed
with reporter Ad for 60 min on ice and then added to
A549 cells; this
was followed by the washing procedure and analysis
of transgene
expression as described
above.
CARex-Fc-mediated enhancement of cell transduction.
Hematopoietic cells were seeded at a concentration of 4 × 105 in 0.5 ml of medium in 12-well plates. Human serum was
replaced with FCS as indicated. AdCMV-eGFP was mixed with CARex-Fc
protein in a volume of 20 µl of medium and added to the cells. After
overnight incubation, the volume was increased to 1 ml, and eGFP
expression was analyzed 48 h postinfection. For inhibition of
Fc receptor-dependent infections, THP-1 cells were preincubated on
ice with either 2µg of CTLA4-lg or 1 µg of a mouse anti-human CD64
antibody (31841A; Pharmingen) for 30 min, washed, and processed as
described above.
| |
RESULTS |
Expression and purification of the CARex-Fc fusion protein.
An
expression plasmid encoding the ectodomain of the human Ad receptor CAR
fused to the human IgG1 Fc domain was constructed for two reasons.
First, we wanted to use such a protein for the production of new and
eventually neutralizing CAR-specific monoclonal antibodies. Existing
CAR-specific antibodies such as the RmcB produced by Hsu et al.
(28) apparently do not block Ad infection (R. Finberg,
personal communication). Second, we reasoned that such a bispecific
protein might allow targeting of Ad to cells that express Fc
receptors, but lack CAR expression. A PCR-amplified cDNA sequence
corresponding to amino acids 1 to 236 of the human CAR sequence
(including the endogenous Kozak motive and the N-terminal signal
sequence of 14 amino acids which is cleaved off in the endoplasmic
reticulum) was cloned in frame into the pCMV1-IgFc expression plasmid
containing the human IgG1 sequence (Fig.
1A). The extracellular sequence of CAR
contains the two Ig-like domains D1 and D2 (Fig. 1B), responsible for
binding to Ad and group B coxsackievirus (5, 19). The
human IgG1 Fc sequence encodes 232 amino acids comprising the hinge,
CH2, and CH3 regions. The mature fusion protein is expected to consist
of 455 amino acids with a calculated molecular mass of 50.7 kDa.
Expression of the fusion protein was controlled by the human CMV
promoter and an SV40 origin of replication (21) mediating
efficient production of the CARex-Fc fusion protein from transiently
transfected simian COS7 cells. Supernatants of transfected COS7 cells
and purified fusion protein were analyzed by SDS-PAGE under reducing
conditions and by Western blotting using an FITC-labeled rabbit
anti-human Ig. Specific staining of a diffuse band migrating as a
~60-kDa species was found in crude supernatants of COS7 cells
transfected with the pCMV1-CARex-Fc expression plasmid (Fig. 1C, lanes
3 and 4) but not in supernatants of mock transfected COS7 cells (lane 7) or cell culture medium alone (lane 1). The difference between the
apparent and calculated molecular masses and also the presence of a
faster-running species may be due to N-linked glycosylation described
previously for full-length CAR (53). As a control, the
fusion protein CTLA4-Ig (14, 36), of ~50 kDa, is shown in lane 6 (Fig. 1C). The amount of CARex-Fc protein in the supernatant increased over 5 days of cell growth, allowing the isolation of 4.5 mg
of pure CARex-Fc protein from 1 liter of culture supernatant (Fig. 1D).
Under nonreducing electrophoresis conditions, CARex-Fc migrated with
molecular mass of ~120 kDa, probably disulfide bonded by cysteines of
the hinge region (Fig. 1D, lane 2). In addition, CARex-Fc behaved as a
~120-kDa species when analyzed on a gel filtration column at
physiological salt concentrations (S. Hemmi, unpublished results).
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FIG. 1.
Production of CARex-Fc fusion protein. (A) The
expression plasmid pCMV1-CARex-Fc was generated by fusing the cDNA
encoding the 236 N-terminal amino acids, including the signal peptide
of the human CAR protein, via a linker of 1 amino acid with the cDNA
encoding 232 amino acids of the human IgG1 Fc polypeptide. (B) The
mature, signal sequence-processed protein contains the extracellular
two Ig-like domains D1 and D2 of CAR fused to the hinge, CH2, and CH3
regions of IgG1 resulting in a presumably secreted protein of 455 amino
acids (aa). (C) Western blot analysis of CARex-Fc protein. COS7 cells
were transiently transfected with pCMV1-CARex-Fc for 1 day (lane 2), 3 days (lane 3), or 5 days (lane 4) or were mock transfected (lane 7).
Cell supernatants (30 µl) were subjected to SDS-PAGE. In addition,
1.5 µg of purified CARex-Fc (lane 5), 30 µl of DMEM plus 10% FCS
(lane 1), and supernatant of stably transfected myeloma cells
containing CTLA4-IgG1 (lane 6) were analyzed as controls. Human Igs
were detected with FITC-labeled rabbit anti-human Ig antibody. (D)
Analysis of purified recombinant CARex-Fc by PAGE and Coomassie blue
staining. Purified CARex-Fc protein (3 µg) was loaded under reducing
(lane 1) or nonreducing (lane 2) conditions.
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Production of the human CAR-specific monoclonal antibody E1-1 and
inhibition of Ad-mediated cell transduction by E1-1 and CARex-Fc
protein.
To produce monoclonal antibodies with specificity for
human CAR, BALB/c mice were immunized and boosted first with the CAR expression plasmid, and then with purified CARex-Fc protein as described in Materials and Methods. Spleen cells of immunized mice were
fused with P3-X63Ag myeloma cells, and hybridoma supernatants were
first screened by cytofluorometric analysis for positive staining of
911 cells, which have high levels of CAR and then tested for
Ad-blocking activity. The monoclonal antibody E1-1 turned out to have
both features. When tested for cell binding, the E1-1 antibody stained
911 cells and L929.CAR mouse fibroblasts stably expressing the human
CAR protein but not parental L929 cells or CAR-negative CHO cells (Fig.
2A). The staining pattern was comparable
to that of RmcB (references 5 and 28 and results not
shown). In addition, when performing Western blotting using protein
extracts from different cells, the monoclonal E1-1 antibody recognized
a single protein of ~50 kDa (Fig. 2B), similar to results described for RmcB under nonreducing conditions (52). Even
at the lowest protein amount of 911 or L929. CAR cell extracts
tested (0.3 µg), we obtained a clear signal of the 50-kDa protein
band (Fig. 2B, lanes 1 and 8, respectively). The additional two
faster-running bands seen with the higher concentrations of extracts
from L929.CAR cells may represent degradation products or proteins
derived from additional RNA splicing variants (lane 6). Accordingly,
even the largest amounts of protein extracts from CHO or L929 cells (30 µg) gave no signal, suggesting that the 50-kDa band was CAR (lanes 4 and 5, respectively).
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FIG. 2.
Specificity of the E1-1 anti-human CAR monoclonal
antibody. (A) Cytofluorometric analysis of CAR expression levels in
different cell lines, using the E1-1 antibody. White histograms show
background staining obtained using isotype control antibodies, and
shaded histograms show CAR-specific staining. (B) Western blot analysis
using E1-1 antibody and 0.3, 3, and 30 µg of protein lysate of 911 cells (lanes 1 to 3), 30 µg of protein lysate of CHO cells (lane 4),
30 µg of protein lysate of L929 cells (lane 5), and 30, 3, and 0.3 µg of protein lysate of L929.CAR cells (lanes 6 to 8, respectively).
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We then tested if E1-1 and CARex-Fc inhibited Ad-mediated
transgene expression of a recombinant Ad expressing eGFP in A549
lung carcinoma cells (which are negative for the high-affinity
Fc
receptor CD64). Blocking or competition experiments were performed
on
ice to prevent possible internalization of ligands. As shown
in Fig.
3A, both
E1-1 and CARex-Fc reduced eGFP expression when
the cells were
treated with supernatant containing the E1-1 antibody
(left panel) or
when virus was preincubated with 1 µg of purified
CARex-Fc protein
(right panel). To quantitate this inhibition,
purified E1-1 antibody
and CARex-Fc protein were titrated and
eGFP expression was determined
(Fig.
3B and C, respectively).
We found that 440 ng of E1-1 antibody
and 11 ng of CARex-Fc protein
resulted in a 50% inhibition of
Ad-mediated eGFP expression, with
the latter corresponding to a
200-fold molar excess of protein
over virus particles. A maximal input
of 20 µg of E1-1 antibody
and 10 µg of CARex-Fc protein resulted in
inhibition of 98% for
both proteins.
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FIG. 3.
Functional properties of E1-1 and CARex-Fc. (A)
Inhibition of Ad-mediated eGFP expression by E1-1 anti-human CAR
monoclonal antibody and CARex-Fc. A549 cells were either preincubated
with 250 µl of E1-1 antibody supernatant or control antibody (left
panel) and then incubated with virus or mixed with virus previously
incubated on ice with 1 µg of CARex-Fc or CTLA4-Ig (right panel)
protein. All incubations were performed for 2.5 h on ice, and the virus
was used at an MOI of 100. The cells were then washed twice, and
culture medium including E1-1, CARex-Fc, or control proteins was
supplied. The cells were incubated for 2 days and analyzed for eGFP
expression. (B and C) Quantification of the inhibitory effects of E1-1 (B) and CARex-Fc (C). Fivefold dilutions of purified
E1-1 antibody or CARex-Fc protein ( ) or control control proteins
( ) were used as described for panel A. The eGFP expression index was
calculated from the ratios of the mean eGFP expression measured in
cells incubated either with E1-1 plus AdCMV-eGFP or CARex-Fc plus
AdCMV-eGFP to the value in those treated with AdCMV-eGFP
alone. Expression values represent the mean of triplicates including
standard deviations. (D) Inhibition of E1-1 anti-human CAR monoclonal
antibody binding to 911 cells by Ad. Cells were stained with E1-1
antibody following preincubation in the cold with the indicated amounts
of AdCMV-muB7-1. Fluorescence intensities of stainings with isotype and
specific antibody are given as the mean of triplicates including
standard deviations of the mean.
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Since the E1-1 antibody was capable of blocking Ad binding, we asked
whether Ad binding would block E1-1 staining. 911 cells
were incubated
with increasing amounts of AdCMV-muB7-1, washed,
and stained with E1-1
antibody. At the highest MOI (5,000) the
mean fluorescence of E1-1 was
reduced to background levels, confirming
that CAR is a major
determinant of Ad binding to these cells (Fig.
3D). Together, these
results indicated that both the E1-1 antibody
and the CARex-Fc
fusion protein were functional CAR-specific
reagents.
Binding of CARex-Fc to cells expressing CD64 high-affinity Fc
receptor I.
Using the E1-1 antibody, we next analyzed whether
CARex-Fc fusion protein bound to cells expressing either the
high-affinity Fc receptor I (CD64) or the low-affinity Fc
receptors II and III (CD32 and CD16, respectively). Using
specific anti-Fc receptor antibodies, expression levels of CD16,
CD32, and CD64 were determined by cytofluorometric analysis on primary
NK cells, primary AML cells, and a panel of hematopoietic cell lines
listed in Table 1. CAR expression was
measured using the E1-1 anti-CAR antibody both for cytofluorometric and
Western blot (data not shown) analyses. Two cell lines, the monocytic
lymphoma U937 (D) and the monocytic leukemia THP-1, and also
patient-derived primary AML cells showed relatively high expression
levels of both CD32 and CD64 but undetectable levels of CAR (Fig.
4). All cell lines were then tested for
binding of CARex-Fc in a triple-sandwich staining assay. The first
incubation was with CARex-Fc, and the second incubation was with the
mouse E1-1 antibody followed by a phycoerythrin-labeled rabbit
anti-mouse Ig conjugate. The FACS analyses in Fig.
5 shows three representative examples of
cells with negative endogenous CAR staining. Daudi cells (negative for
all three types of Fc receptor) and K562 cells (positive for CD32)
showed no CARex-Fc binding. In contrast, THP-1 cells, which were CD32
and CD64 positive, also bound CARex-Fc but gave no signal in the
absence of CARex-Fc. Taken together, these results demonstrated that
CD64-positive cells but not CD16- and CD32-positive cells bound soluble
CARex-Fc.
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TABLE 1.
Expression of low and high-affinity Fc receptors and
CAR and effects of CARex-Fc on Ad-mediated transduction
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FIG. 4.
Cytofluorometric analysis of low-affinity (CD16 and
CD32) and high-affinity (CD64) Fc receptor expression and CAR
expression of primary NK and AML cultures and hematopoietic cell lines.
Cells were stained using either isotype control (white histograms) or
specific FITC-labeled antibodies (CD16, CD32, and CD64) or the E1-1
antibody in combination with phycoerythrin-conjugated rabbit anti-mouse
IgG (black histograms).
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|
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FIG. 5.
CARex-Fc binds directly to CD64-positive cells. Daudi,
K562, and THP-1 cells were incubated first with or without CARex-Fc
(shaded and white histograms, respectively) and then with E1-1 and
phycoerythrin-conjugated rabbit anti-mouse IgG.
|
|
CD64- and CARex-Fc-mediated increase of Ad transgene
expression.
To test whether CARex-Fc protein allowed improved
Ad-mediated eGFP expression in cells containing one of the Fc
receptors, the cells listed in Table 1 were incubated with AdCMV-eGFP
at an MOI of 10, either alone or premixed with 1.0 µg of CARex-Fc protein. eGFP staining was analyzed 48 h postinfection. A
representative collection of histograms using four different types of
cells (Jurkat, HL-60, THP-1, and primary AML) is shown in Fig.
6A. For HL-60, THP-1, and primary AML
cells, virus alone gave rise to a small number of cells expressing eGFP
at low mean fluorescence values. In contrast, premixing of Ad with
CARex-Fc resulted in a strong increase of eGFP expression with 90%
(THP-1) or 75% (AML) of the cells shifted to eGFP expression at high
mean fluorescence values. When CARex-Fc was replaced by comparable
amounts of the control CTLA4-Ig protein, which binds to the Fc
receptor but not to Ad, no effect on eGFP expression was observed (data
not shown), suggesting that ligation of the high-affinity Fc
receptor alone does not induce uptake of Ad. For HL-60 cells, only
about 20% of the cells showed a similar increase of expression, most
probably reflecting the cell population expressing CD64. Jurkat cells
demonstrated no change of eGFP expression on addition of CARex-Fc
protein. A systematic analysis of eGFP expression levels of THP-1 cells as a function of CARex-Fc levels and Ad MOIs is depicted in Fig. 6B.
MOIs of 3.3, 10, 30, and 90 were combined with different amounts of
CARex-Fc, ranging from 882 to 3.6 ng, and the relative eGFP expression
on day 2 postinfection was determined. For all MOIs used, a strong
increase in eGFP expression was found, ranging from 30-fold at an MOI
of 3.3 to 100-fold at MOIs of 30 and 90. For MOIs of 3.3, 10, and 30, peak induction was obtained with 294 or 98 ng of purified CARex-Fc
protein, which corresponded to a protein/virus particle ratio of 6,400 to 2,100. Maximal (250-fold) induction was obtained when the analysis
was performed on day 1 with an MOI of 90, and the minimal amount of
CARex-Fc protein which still increased the eGFP expression level was
130 pg (data not shown). At all MOIs used except 90, the largest amount
of CARex-Fc protein (882 ng) gave a weaker stimulation than did optimal amounts of CARex-Fc, presumably due to binding competition of soluble
CARex-Fc protein with virus-bound CARex-Fc for the high-affinity Fc
receptor. Likewise, high concentrations of CARex-Fc also had an
inhibitory effect on Jurkat, U937 (H) and K562 cells (summarized in
Table 1). Weak signals for endogenous CAR were seen for Jurkat and K562
cells in Western blots (data not shown) but not in FACS experiments.
Surprisingly, Raji cells, which yielded a robust CAR signal in both
assays, did not show any inhibitory effect. Ramos cells were completely
resistant to Ad-mediated eGFP expression, possibly because they were
shown to stain negative for several surface integrins
(44).
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|
FIG. 6.
CARex-Fc-mediated increase of Ad transgene expression in
hematopoietic cells. (A) Jurkat, HL-60, THP-1, and primary AML cells
were transduced with AdCMV-eGFP using an MOI of 10 in the absence (red)
or presence (green) of 1 µg of CARex-Fc protein. Cells alone are
shown as solid blue histograms. (B) MOI and CARex-Fc dose effects on
the transduction efficiency of THP-1 cells. Results are given as means
of duplicate determinations of eGFP mean values. The results of one of
three comparable experiments are shown. (C) Inhibition of
CARex-Fc-mediated transgene expression by preincubation of THP-1 cells
with 2 µg of CTLA4-Ig for 30 min on ice. Experimental settings were
comparable to those in panel B when using AdCMV-eGFP at an MOI of 10 and various amounts of CARex-Fc protein. (D) Inhibition of transgene
expression by preincubation of THP-1 cells with 1 µg of an monoclonal
mouse anti-human CD64 antibody.
|
|
Enhanced eGFP expression was obtained by two different protocols.
Either CARex-Fc protein was premixed briefly with Ad and
then added to
cells and left on the cells for 48 h or cells were
first incubated
on ice with CARex-Fc only, washed, and incubated
with virus (data not
shown). The results of the two methods were
comparable, suggesting that
the CARex-Fc fusion protein was functionally
independent of whether it
was first bound to Ad or to the target
cells.
Of the 11 cell lines and 2 primary cell cultures of myeloid or
lymphatic origin, 2 cell lines, THP-1 and U937 (D), and one
primary
patient-derived AML cell culture showed a high increase
of Ad
transduction efficiency due to CARex-Fc (Table
1). The
CARex-Fc-responsive cells expressed the high-affinity Fc
receptor
CD64 at relatively high levels (Fig.
4). Low levels of CD64 expression
on HL-60, Kasumi-1, and SigM5 cells correlated with a low but
significant increase of CARex-Fc-mediated
expression.
To supply further evidence that the high-affinity Fc
receptor is
responsible for mediating the increased transduction efficiency,
premixed virus and CARex-Fc was added to cells pretreated with
either
the CTLA4-Ig fusion protein binding to Fc
receptor or
a monoclonal
antibody against human CD64 (Fig.
6C and D, respectively).
In both
cases, a reproducible 33- and 7-fold reduction of the
eGFP expression
levels were observed at small amounts of CARex-Fc.
Taken together,
these results indicate that the bispecific fusion
protein CARex-Fc is
capable of bridging the CD64 surface protein
and the Ad fiber protein
and thereby increases Ad infection in
these
cells.
| |
DISCUSSION |
Several approaches have been used to improve the Ad
transduction efficiency of cells normally resistant to Ad. In the best cases, genetically modified Ad vectors containing heterologous peptides, such as RGD in the HI loop of the fiber (13, 31, 42) or at the C-terminal end (64, 66), were
reported to increase the transduction efficiency up to 500-fold across
a broad range of cell types. However, cells of hematopoietic origin
with low levels of integrin expression (29) are not
expected to be good targets of RGD-modified Ad. An additional
limitation of such a genetic approach is the small size of the
targeting peptide tolerated by the virus capsid structure (8,
66). Further extension of productive Ad-cell interactions by
selective strategies is thus important to broaden Ad tropism for
medical purposes. Toward this goal, we have designed bispecific and
simple-to-produce fusion proteins. We have demonstrated that a
bispecific fusion protein consisting of the ectodomain of CAR fused to
the immunoglobulin Fc domain improves the transduction efficiency of
hematopoietic cells devoid of the primary Ad receptor CAR by up to
250-fold. This transduction increase is highly significant and fully
dependent on the presence of high-affinity Fc receptor I (CD64). The
transduction increase is significantly reduced by CTLA4-Ig protein or
an anti-human CD64 monoclonal antibody, which bind to the high-affinity
Fc receptor I. The inclusion of the CAR ectodomain in our fusion construct is useful since this domain confers high-affinity binding to
the fiber protein of Ad. If all the fibers are decorated with CARex-Fc,
we expect that such modified virus prefers to bind to Fc receptors
rather than to the receptor of native Ad, CAR.
Accordingly, we have demonstrated that coincubation of virus with
CARex-Fc strongly reduced Ad-mediated expression in CAR-positive, Fc
receptor-negative A549 cells, arguing for the correct folding of at
least the D1 domain of CARex-Fc (19). In addition, the successful production of a virus-neutralizing monoclonal anti-human CAR-specific antibody using the CARex-Fc protein to boost the immune
response, together with the demonstration of direct binding of the
CARex-Fc protein to CD64-positive cells, adds further evidence for the
functionality of our hybrid adapter protein.
Other strategies to alter Ad host range have involved conjugates
containing blocking anti-Ad fiber knob Fab (15) or an
anti-FLAG epitope antibody (65). Most closely related to
our approach is the use of a bispecific protein consisting of the
neutralizing scFv antibody fragment recognizing the fiber knob fused to
the EGF ligand, termed the adenobody (60). In this system,
viral gene delivery to cells expressing the EGF receptor was enhanced 16-fold. Since all the cells tested in these experiments also expressed
CAR, the contribution of the additional EGF domain to retargeting Ad
was difficult to define. Besides the EGF receptor, additional receptors
like the folate receptor (15) and CD3 on T lymphocytes
(62) have been used as targets for bispecific conjugates
to extend Ad tropism. A similar approach was described for
retroviruses by using a bispecific soluble virus receptor fused to EGF
(6, 49). In this system, improved transduction was
obtained by preincubating cells with the hybrid protein and then
incubating them with virus. Alternatively, virus was incubated with the fusion protein and purified and then the complex was added to
target cells.
In contrast to several of the previous reports, our approach was
effective for cells lacking the natural virus receptor. The presence of
the high-affinity Fc receptor I on the target cells was sufficient
for a robust Ad-mediated gene expression. It is not known at present if
CARex-Fc-modified Ad entered the CAR-less cells by a clathrin-dependent
pathway, which was suggested to operate for Ad infection of
fibroblast-type cells (59). Possibly, our
CARex-Fc-modified Ad is taken up by a clathrin-independent route
similar to Fc receptor-mediated endocytosis in phagocytic cells
(2). This pathway operates in an actin-dependent manner, typically with particles larger than 0.5 µm. Since the CARex-Fc bridging protein seems to be dimeric, multiple Ads could become cross-linked and thus might induce phagocytosis. However, the low-affinity Fc receptors II and III, which primarily recognize immune complexes (55), were inefficient for CARex-Fc-Ad
infection, suggesting that the CARex-Fc-Ad complexes were poorly
recognized by the low-affinity Fc receptor uptake system. Further
experiments are necessary to clarify the mechanisms of Ad-mediated
transgene delivery into Fc receptor I-positive cells.
Nonetheless, CARex-Fc-modified Ad may have clinical potential. CD64 is
expressed on monocytes, macrophages, and subtypes of AML cells but not
on maturating dendritic cells (7, 43, 55) (Fig. 4). Since
global survival rates for patients with AML are poor, the further
development of immunotherapy and immune vaccine approaches is a
valuable goal to pursue (4). The concept of immune gene
therapy for cancer is based on the presumption that the host immune
system is capable of recognizing tumor-associated antigens. For AML,
little information is available about potential immunostimulatory
antigens. Recently, isolation of AML-specific T-cell clones was
reported (38, 40), but no corresponding peptide sequences
have so far been published. High levels of transiently expressed
cytokines and immune modulators might be sufficient to activate the
immune system in vivo and thereby achieve the therapeutic goal
(34, 54). Cells of the hematopoietic system are
particularly suitable for gene therapy, since the techniques for bone
marrow and blood cell transplantations are well established and,
importantly, the transductions can be performed ex vivo. Primary AML
cells can be obtained from patient bone marrow aspirates or peripheral
blood mononuclear cells and can be kept in culture in the presence of
interleukin-3, stem cell factor, or kit ligand (for a review, see
reference 4). However, none of the currently used
gene therapy vectors allow efficient gene transfer to malignant cells of hematopoietic origin. Therefore, the development of
CARex-Fc for Ad-mediated gene transfer provides a promising alternative to specifically transfer therapeutic genes into CD64-positive AML
malignancies. For other types of malignancies, alternative cell surface
markers may serve as targets. Replacement of the Fc portion of CARex-Fc
with other polypeptide sequences that bind to surface markers, such as
receptor ligands or single-chain antibodies, may allow the production
of a whole range of bifunctional, soluble Ad receptor-ligand fusion proteins.
| |
ACKNOWLEDGMENTS |
This work has been supported by the Kanton Zürich and by a
grant of the Krebsliga of the Kanton Zürich (to S.H.).
We thank P. Forte (University Hospital, Zürich, Switzerland) for
providing the cultivated NK cells, G. Schoedon (Department of Medicine,
University of Zürich, Zürich, Switzerland) for several cell
lines and patient AML cells, R. Fischer (Laboratory of Biochemistry,
Swiss Federal Institute of Technology, Zürich, Switzerland) for
advice relating to hybridoma production, L. Hangartner (Experimental
Immunology, University of Zürich, Zürich, Switzerland) for
isotype determination of the E1-1 antibody, and F. Ochsenbein for
graphic designs.
| |
ADDENDUM |
After submission of this article, another group reported the use
of a bispecific fusion protein consisting of the soluble truncated form
of CAR fused with epidermal growth factor mediating Ad targeting to
epidermal growth factor receptor-positive cells (13a).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Institute of
Molecular Biology, University of Zürich, Winterthurerstr. 190, CH-8057 Zürich, Switzerland. Phone: 0041 1 635 3120. Fax: 0041 1 635 6864. E-mail: hemmi{at}molbio.unizh.ch.
| |
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Journal of Virology, January 2001, p. 480-489, Vol. 75, No. 1
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.1.480-489.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
