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Journal of Virology, August 2000, p. 6885-6892, Vol. 74, No. 15
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Evaluation of Hepatitis C Virus Glycoprotein E2 for Vaccine
Design: an Endoplasmic Reticulum-Retained Recombinant Protein Is
Superior to Secreted Recombinant Protein and DNA-Based
Vaccine Candidates
Jens M.
Heile,1
Yiu-Lian
Fong,2
Domenico
Rosa,1
Kim
Berger,2
Giulietta
Saletti,1
Susanna
Campagnoli,1
Giuliano
Bensi,1
Sabrina
Capo,1
Steve
Coates,2
Kevin
Crawford,2
Christine
Dong,2
Mark
Wininger,2
Gary
Baker,2
Larry
Cousens,2
David
Chien,2
Philip
Ng,2
Phillip
Archangel,2
Guido
Grandi,1
Michael
Houghton,2 and
Sergio
Abrignani1,*
IRIS Research Center, Chiron, 53100 Siena,
Italy,1 and Chiron Corporation,
Emeryville, California 946082
Received 31 January 2000/Accepted 4 May 2000
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ABSTRACT |
Hepatitis C virus (HCV) is the leading causative agent of
blood-borne chronic hepatitis and is the target of intensive vaccine research. The virus genome encodes a number of structural and nonstructural antigens which could be used in a subunit vaccine. The
HCV envelope glycoprotein E2 has recently been shown to bind CD81 on
human cells and therefore is a prime candidate for inclusion in any
such vaccine. The experiments presented here assessed the optimal form
of HCV E2 antigen from the perspective of antibody generation. The
quality of recombinant E2 protein was evaluated by both the capacity to
bind its putative receptor CD81 on human cells and the ability to
elicit antibodies that inhibited this binding (NOB antibodies). We show
that truncated E2 proteins expressed in mammalian cells bind with high
efficiency to human cells and elicit NOB antibodies in guinea pigs only
when purified from the core-glycosylated intracellular fraction,
whereas the complex-glycosylated secreted fraction does not bind and
elicits no NOB antibodies. We also show that carbohydrate moieties are
not necessary for E2 binding to human cells and that only the monomeric
nonaggregated fraction can bind to CD81. Moreover, comparing
recombinant intracellular E2 protein to several E2-encoding DNA
vaccines in mice, we found that protein immunization is superior to DNA
in both the quantity and quality of the antibody response elicited.
Together, our data suggest that to elicit antibodies aimed at blocking
HCV binding to CD81 on human cells, the antigen of choice is a
mammalian cell-expressed, monomeric E2 protein purified from the
intracellular fraction.
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INTRODUCTION |
Hepatitis C virus (HCV) is the major
cause of chronic hepatitis, which can evolve into cirrhosis, liver
failure, or hepatocellular carcinoma (2, 4). There is no
vaccine for HCV, and the only available treatment, a combination of
alpha interferon and ribavirin, is efficacious in only a minority of
patients (33). Given that approximately 200 million chronic
HCV infections have been estimated worldwide (52), there is
a pressing need to develop new therapies and vaccination strategies.
The development of such strategies will be aided greatly by a more
complete picture of the structure-function features of HCV proteins.
HCV is an enveloped plus-strand RNA virus of the
Flaviviridae family (24). Its genome is 9.5 kb in
length with one open reading frame that is translated as a single
polyprotein, which is processed by host and virus proteases into at
least three structural and seven presumptive nonstructural proteins
with various enzymatic activities (5, 22, 47). Two
glycoproteins, E1 and E2, are probably virion envelope proteins,
containing multiple N-linked glycosylation sites, and form heterodimers
in vitro (23, 32, 35, 45). The coexpressed E1-E2 complex
localizes to the endoplasmic reticulum (ER) and lacks complex N-linked
glycans (7, 8, 13, 15, 45, 49).
Neutralizing antibodies often play a pivotal role in defeating viral
infections, including prominent human pathogens such as influenza virus
and hepatitis B virus (9, 28). The assessment of
neutralizing antibody responses to HCV has been difficult because HCV
does not grow efficiently in cell cultures. To overcome this obstacle,
we developed a surrogate assay which measures the ability of antibodies
to inhibit the binding of recombinant E2 to its putative cellular
receptor CD81 on human cells (neutralization-of-binding [NOB] assay)
(44, 46). CD81 is a membrane-associated protein belonging to
the family of tetraspanins (30). Its large extracellular loop (LEL) binds E2 with a Kd of 1.8 nM
(42), and this interaction appears necessary and sufficient
for binding of bona fide HCV particles (44). Importantly,
chimpanzee sera containing antienvelope antibodies, which are capable
of preventing HCV infection in vivo, inhibit the binding of HCV to CD81
in vitro, suggesting that this interaction is relevant to infection
(44).
Our research has focused primarily on comparing vaccine formulations of
HCV E2, which is an obvious candidate for inclusion in a subunit
vaccine because of its potential role in HCV attachment. Thus,
targeting antibodies to HCV E2 could be a viable strategy for
disrupting the HCV-CD81 interaction. Despite the inherent difficulties
in studying HCV infection and the lack of a clear correlate of
protection, there is evidence that neutralizing antibodies can be
protective. Studies performed with human immunoglobulin (Ig)
preparations have suggested some degree of efficacy in preventing the
transmission of HCV in the transfusion setting, after liver transplants, and in sexual transmission (17, 27, 43).
Relevant data on the existence of HCV-specific neutralizing antibodies also come from experimental vaccination studies in chimpanzees, the
only species besides humans susceptible to infection. When vaccinated with recombinant envelope proteins (E1-E2
heterodimer), chimpanzees developed high titers of anti-E2 antibodies
in serum, as determined by enzyme-linked immunosorbent assay (ELISA)
and NOB assay, and were completely protected from subsequent challenge with the homologous virus (6, 46).
As with any chronic viral infection, there is a growing interest in
eliciting not only antibody but also cytotoxic T-lymphocyte (CTL)
responses to HCV. Therefore, we have begun to investigate DNA
vaccination as an alternative or complement to a vaccine based solely
on recombinant proteins. DNA vaccines have been reported to prime good
antibody responses, but, unlike subunit vaccines, they offer the
advantage of maximizing CTL responses (12, 41). Their
efficacy has been successfully demonstrated in animal models for a wide
variety of viral pathogens including hepatitis B virus, human
immunodeficiency virus, and influenza virus (10, 29, 51).
However, despite its advantages and success in rodent models, DNA
vaccination suffers from several drawbacks in that it is still largely
in the realm of basic research and nonsecreted antigens are
particularly weak stimulators of antibody responses (3).
Here we compared the quantity and quality of anti-E2 antibody responses
elicited by various forms of recombinant HCV E2 proteins or by DNA
vaccines. Our findings indicate that an ER-retained form of recombinant
HCV E2 protein is the antigen of choice for eliciting the best antibody
response in terms of both quality and quantity.
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MATERIALS AND METHODS |
Cloning, expression, and purification of E2 protein.
E2384-661 and E2384-715 were expressed from
recombinant CHO cells as described previously (46, 49). For
purification of secreted E2 (S-E2), CHO cell conditioned medium was
concentrated 23-fold by ultrafiltration and subjected to flowthrough
chromatography on a type I ceramic hydroxyapatite (HAP) (Bio-Rad)
column equilibrated in 100 mM NaCl-10 mM phosphate (pH 6.3).
E2-containing flowthrough fractions, as assessed by sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and Western
blotting, were pooled and concentrated on a 30-kDa-cutoff tangential
flow filter (Omega membrane; Pall Corp., Torrance, Calif.). Internal E2
(I-E2) was solubilized from CHO cells with lysis buffer (4% Triton
X-100, 100 mM Tris-HCl [pH 8.0], 1 mM EDTA, protease inhibitors). The solution was loaded on a Galanthus nivalis lectin (Vector
Laboratories, Burlingame, Calif.) affinity column equilibrated in 1 M
NaCl-2% Triton X-100-50mM Tris-HCl (pH 8.0). The column was washed
with 1 M NaCl-0.1% Triton X-100-20 mM phosphate (pH 6.0) and eluted with 1 M methyl-
-D-mannopyranoside. The eluate was
diluted, loaded onto a HAP column, and subjected to a concentration
step as indicated above. The HAP concentrate was processed over an
S-Fractogel column (EM Separations) equilibrated and washed with 25 mM
NaCl-10mM phosphate (pH 6.2). I-E2 was eluted with 150 mM NaCl-10 mM
phosphate (pH 6.2). To purify the different molecular weight forms of
E2, the S-E2715 concentrate and the I-E2715
eluate were adjusted to 30 mM phosphate (pH 7.0), and fractionated on a
Superdex 200 (Pharmacia) gel filtration column equilibrated with
phosphate-buffered saline (PBS) (pH 7.0)-1 mM EDTA. Aliquots of
collected fractions were trichloracetate precipitated for analysis.
Fractions containing monomers, dimers, and trimers of
S-E2715 and I-E2715 were pooled and
concentrated as indicated above.
Deglycosylation of internal E2715 and carbohydrate
analysis.
I-E2715 was digested with -mannosidase or
endo-
-N-acetylglucosaminidase H (endo H) (Boehringer
Mannheim). The exoglycosidase -mannosidase efficiently removes free
mannose (Man) residues that are 1
6 Man or 12 Man linked and
less efficiently removes 13 Man-linked residues. Endo H cleaves
between the two N-acetylglucosamine (GlcNAc) residues of
N-linked core units, leaving one GlcNAc residue linked to asparagine.
Samples were incubated with or without enzyme overnight at 37°C in 50 mM citrate (pH 5.0). -Mannosidase digestion was monitored by
SDS-PAGE, and then 100 mM borate (pH 9.5) was added to stop the
reaction. The samples were then dialyzed against 10 mM phosphate (pH
8.0) to remove digested monosaccharides. Endo H-digested carbohydrates
were removed by S-Fractogel chromatography as indicated above. For
monosaccharide content analyses, digested E2 was treated with 3 M
trifluoroacetic acid for 6 h at 100°C to release the
monosaccharides. Following lyophilization, samples were derivatized at
pH 8.0 with 50 mM phenylmethylpyralozone and extracted into
tert-butylether. The extract was then analyzed by
reverse-phase high-pressure liquid chromatography, and the monosaccharide content was determined by using an external calibration profile and an internal talose standard.
DNA constructs.
The vector pAC-FN used for DNA vaccination
will be described in detail elsewhere (J. M. Heile, S. Abrignani,
and G. Grandi, unpublished data). Briefly, expression of the gene of
interest is driven by the human cytomegalovirus immediate-early
promoter and enhancer and RNA stability is ensured by a simian virus 40 splice site and poly(A) signal. E2 DNA vaccines are derived from a
previously described construct, which directs truncated
E2384-715 of HCV genotype 1a into the ER by a
25-amino-acid (aa) tissue plasminogen activator (TPA)-derived signal
sequence (46). The tpa-E2715 insert was
transferred into the SmaI and NotI sites of the
pAC-FN polylinker by standard molecular cloning techniques, resulting
in pAC-E2715. For the construction of DNA vaccines encoding ER-retained E2, the following strategy has been used.
pAC-E2715 was modified by replacing the C-terminal part of
E2 with PCR fragments amplified from pMCMV-HC5p, which encodes HCV aa 1 to 917 (49). The fragments were cloned into the unique
ApaI site at E2 aa 470 and into the NotI site.
The sense primer used for all constructs (E2Apa-209;
5'-CCTCCTCGCACCAGGCGCCAAGC-3') anneals 209 bp upstream of
ApaI. All antisense primers are composed of the sequence
5'-ATCGTAGCGGCCGCTTA-3', comprising a NotI site
and the ochre stop codon, followed by the sequence
5'-CGCCTCCGCTTGGGATATG-3' (E2746),
5'-CGCGTACGCCCGCTGGGGC-3' (E2809),
5'-AGGCATTTTCTTTTCATCAATAAAACTGCGTCTGCTGCGCGCGTCTGCAAGCAGAAGG-3' (E2730KK), or
5'-GAGCTCGTCCTTAATGGCCCAGGACGCG-3'
(E2715DEL). The resulting constructs are referred to as
pAC-E2746, pAC-E2809, pAC-E2730KK,
and pAC-E2715DEL. All PCR-derived modifications
were verified using an ABI sequencer (Amersham Pharmacia Biotech).
In vitro analysis of constructs.
CHO cells were stably
transfected with the E2-DNA vaccines for analysis. Selection was
achieved through bicistronic expression of E2 together with a neomycin
resistance gene (neo), coupled downstream of the E2 sequence
via an internal ribosomal entry site. neo was amplified by
PCR from pcDNAINeo (Invitrogen) and cloned into BamHI and
blunt-ended NcoI sites of pCITE-2a(+) (Novagen), with
NcoI providing the ATG start codon. The resulting
IRES-neo fragment was excised with ApaI and
XbaI and blunt ended for insertion into the NotI
site of the pAC-E2 constructs. CHO DG44 cells were grown in Ham's F12
medium supplemented with 10% fetal calf serum, 2 mM L-glutamine, and
0.02% L-proline. Subconfluent monolayers grown in
100-mm-diameter dishes were transfected with 20 µg of plasmid DNA by
calcium phosphate coprecipitation. Precipitates were incubated with
cells for 6 h at 37°C and then given a 3-min shock with 15%
glycerol in PBS. Cells were grown for 48 h without selection,
divided among 15 plates, and grown for 2 weeks in medium containing 1 mg of Geneticin G418 sulfate (Gibco BRL) per ml. E2 protein was
purified from pooled transfectants without further cloning. Cells were
resuspended in lysis buffer (20 mM Tris-HCl [pH 7.5], 100 mM NaCl, 1 mM EDTA, 0.5% NP-40, 0.5% deoxycholate) containing protease
inhibitors. E2 was immunoprecipitated with serum of chimpanzee L559,
which was immunized with E1-E2 heterodimer and protected against
challenge with homologous HCV (6). Using protein A-Sepharose
CL-4B (Pharmacia), the lysate was precleared with L559 preimmune serum
and E2 was precipitated with immune serum. The pellet was directly
resuspended in 100 mM acetate (pH 5.0)-0.03% SDS and boiled for 2 min. Equal parts were incubated with or without endo H for 20 h at
37°C in the presence of protease inhibitors and then trichloroacetate
precipitated. After SDS-PAGE under reducing conditions, the E2 antigen
was detected by Western blotting with a monoclonal antibody (MAb)
raised against E2715 expressed in insect cells (MAb 3E51),
which recognizes nonconformational E2 (S. Abrignani, D. Rosa, and M. Houghton, unpublished data), followed by horseradish
peroxidase-conjugated anti-mouse Ig antiserum (Amersham).
Animals and immunizations.
Hartley female guinea pigs were
purchased from Elmhill, Chumford, Mass. Five animals per group were
immunized intraperitoneally (i.p.) with 8 µg of S-E2715
or I-E2715 in MF59-0 adjuvant on days 0, 30, and 90, and
bled on day 110. Groups of eight 6- to 8-week-old female C57BL/6 mice
(Charles River, Calco, Como, Italy) were injected intramuscularly
(i.m.) in both hindlegs with either DNA in PBS or protein in MF59-0
adjuvant on days 0 and 35 and bled on day 49. Plasmid DNA was prepared
using endotoxin-free purification columns (Qiagen, Hilden, Germany).
Per mouse and injection, a total of 100 µl of 1-µg/µl E2-DNA (100 µg) or 50-ng/µl I-E2715 protein (5 µg) was administered.
Antibody titers.
Anti-E2 antibody titers were measured by
ELISA. For guinea pig sera, Nunc maxisorb microtiter plates were coated
with HeLa E1-E2 antigen (0.3 µg/ml) purified as previously described
(6). The sera were analyzed with horseradish
peroxidase-conjugated anti-guinea pig IgG antiserum (Sigma). Mouse sera
were analyzed with Nunc CovaLink microtiter plates coated with CHO
I-E2715 protein at 0.5 µg/ml, using alkaline
phosphatase-conjugated anti-mouse IgG (Sigma). Antibody titers were
calculated as the dilution which gave an optical density (OD) that
equaled the cutoff. The cutoff was established as the mean OD + 3 standard deviations for eight preimmune sera.
E2 binding assay.
Binding of E2 to target cells was measured
as described previously (46). Briefly, MOLT-4 cells were
incubated with different concentrations of E2 protein. Cell-bound E2
was detected with anti-E1-E2 antiserum from chimpanzee L559 followed by
phycoerythrin-labeled anti-human Ig, F(ab')2 fragment
specific (Southern Biotechnology Associates, Birmingham, Ala.), or with
antiserum from guinea pigs immunized with I-E2715 or
S-E2715 followed by fluorescein isothiocyanate-labeled anti-guinea pig IgG, F(ab')2 fragment specific (Jackson
ImmunoResearch, West Grove, Pa.). Cell-bound fluorescence was analyzed
with a FACScan flow cytometer (Beckton Dickinson). The net mean
fluorescence intensity (MFI) was calculated by subtracting the value
obtained in parallel with chimpanzee L559 or guinea pig preimmune
serum. The specificity of E2 binding to CD81 on human cells was
confirmed as described previously (44) by competing E2
binding to human cells with soluble human CD81 LEL, which was purified
as described previously (42) and incubated at a
concentration of 50 µg/ml with E2 prior to incubation with MOLT-4 cells.
NOB assay.
Mouse and guinea pig sera were tested for their
ability to inhibit the binding of E2 protein to human target cells as
previously described (25, 46). Briefly, NOB titers were
determined by incubation of MOLT-4 cells with a nonsaturating
concentration of biotinylated I-E2715 protein (1.5 µg/ml), which was previously incubated with a test serum at different
dilutions. Following incubation of the cells with a
streptavidin-phycoerythrin conjugate (Southern Biotechnology
Associates) at 2.5 µg/ml, E2 binding was measured with a FACScan. NOB
titers correspond to the reciprocal values of serum dilutions which
inhibit 50% of binding.
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RESULTS |
I-E2 but not S-E2 binds human target cells and elicits NOB
antibodies following immunization.
The E2 protein is processed
from the HCV polyprotein, leading to a polypeptide backbone of 363 residues, spanning residues 384 to 746 (31). aa 716 to 746 serve as a membrane anchor, and their deletion can lead to secretion of
the E2 protein when expressed in mammalian cells (34, 48).
We previously described stably transfected CHO cell lines expressing
E2, targeted to the ER via a TPA-derived leader sequence fused to its N
terminus and carboxy-terminally truncated at residues 661 (E2661) or 715 (E2715). Both lines secrete a
fraction of the E2 protein and retain part of it in the ER
(49). Although E2661 is secreted from CHO
transfectants with more efficiency than are longer truncated versions,
we first aimed to purify and analyze the largest secreted E2 protein
possible, and we previously reported the purification and binding to
human target cells of E2715 (46). This E2
protein had been affinity purified from culture supernatants with MAb
5E5/H7 raised against the HeLa intracellular E1-E2 heterodimer, and we
obtained E2 only in extremely small quantities. The low yield achieved
with a conformational MAb used for purification led us to suspect that
we had actually captured either a minor well-folded fraction or an
intracellular fraction that had been released into the supernatant by
occasional cell lysis. We then purified both the supernatant fraction
(S-E2715) and the intracellular fraction
(I-E2715) from the same line without the use of E2-specific
antibodies. In Western blots, S-E2715 appeared as a broad
band of about 74 kDa whereas I-E2715 appeared as a sharper
band of about 60 kDa (Fig. 1A),
indicating extensive usage of the 11 N-linked glycosylation sites
within E2.
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FIG. 1.
I-E2 induces higher anti-E2 NOB titers than S-E2 does.
(A) E2715 protein was expressed in CHO cells and purified
from the supernatant (S-E2) and from lysed cells (I-E2). The two
fractions were analyzed by SDS-PAGE (10% acrylamide) under reducing
conditions and Western blotting with chimpanzee anti-E1/E2 antiserum.
The sizes (in kilodaltons) of protein molecular mass markers are
indicated on the left. (B and C) Hartley female guinea pigs were
immunized i.p. with 8 µg of S-E2 or I-E2 in MF59-0 adjuvant on days
0, 30, and 90. Sera taken on day 110 were analyzed by ELISA (B) and the
NOB assay (C). Anti-E2 ELISA titers (total IgG) are expressed as the
highest serum dilution resulting in an OD450 that equaled
the cutoff (mean OD + 3 standard deviations for eight preimmune
sera). Anti-E2 NOB titers are expressed as reciprocal values of serum
dilutions which inhibit 50% of E2 binding to CD81 on MOLT-4 cells. The
results are given as the mean values for five individual animals.
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The E2 protein is an ideal vaccine candidate for the generation of
antibodies that inhibit the binding of virus to target
cells. This
antibody subset can be estimated in vitro by the NOB
assay. To test the
quality of different E2 antigens, we used S-E2
715 and
I-E2
715 for immunization studies in guinea pigs. Both
fractions
raised high antibody titers as measured by ELISA, but only
the
internal fraction raised NOB antibodies (Fig.
1B and
C).
We then measured the binding of the different forms of recombinant
E2
715 to CD81 and also included recombinant
E2
661 in these
studies. For both truncated forms, I-E2
binding to target cells
was saturable and was detected at
concentrations as low as 0.1
µg/ml. Moreover, addition of purified
recombinant human CD81 LEL
blocked this binding completely,
demonstrating the specificity
of the interaction (Fig.
2A). By contrast, S-E2 bound weakly to
cells and did not reach saturation at the maximum concentration
used.
As previously described, cell-bound E2 was detected using
anti-E2
antiserum raised in a chimpanzee immunized with intracellular
E1-E2
heterodimer (
46). We considered the possibility that the
observed difference in binding was due to a decreased ability
of this
antiserum to recognize the complex glycosylated S-E2.
We therefore
repeated the experiments using antisera raised in
guinea pigs against
I-E2
715 or S-E2
715. Both antisera confirmed
our
finding that only the internal but not the secreted fractions
of
truncated E2 bind efficiently to CD81 (Fig.
2B and C).
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FIG. 2.
Binding of various truncated E2 proteins to human cells.
S-E2 (circles) and I-E2 (squares) truncated at position 661 (open
symbols) or at position 715 (solid symbols) and expressed in CHO cells,
were tested for their capacity to bind MOLT-4 cells. Cell-bound E2 is
indicated as net MFI as detected by flow cytometry using chimpanzee
anti-E1-E2 antiserum (A) or using antiserum raised in guinea pigs
against I-E2715 (B) or S-E2715 (C). The star
represents the effect of 50 µg soluble human CD81 LEL per ml on the
binding of I-E2661.
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Internal E2 monomers but not dimers or trimers bind efficiently to
human cells.
The recombinant E2 protein expressed in mammalian
cells tends to aggregate, and these aggregates are stabilized by
disulfide bonds. Such multimers of the HCV envelope are thought to be
dead-end products (11, 34). We investigated whether the
presence of oligomerized E2 protein in our preparations influences
their ability to bind CD81. We separated forms of I-E2715
and S-E2715 with different molecular weights by gel
filtration, through which we were able to purify monomers, dimers, and
trimers of each. Both E2 forms display very similar gel filtration
profiles, indicating that in both cases about 60% of the
unfractionated material is monomeric (Fig.
3A). Only the monomeric fraction of
I-E2715 bound efficiently to cellular targets, while the
dimeric and trimeric fractions bound poorly. By contrast, neither
monomers, dimers, nor trimers of S-E2715 bound CD81
efficiently. CD81 LEL blocks the binding of monomeric
I-E2715 and S-E2715 completely, demonstrating
the specificity of the interaction (Fig. 3B). Thus, aggregated
recombinant I-E2715 fractions have an impaired capacity to
present the conformational binding epitopes.
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FIG. 3.
Monomers of I-E2715 bind human cells better
than do dimers and trimers. Purified I-E2715 and
S-E2715 were fractionated further by size exclusion
chromatography into different molecular weight forms. (A) The elution
profiles of I-E2715 and S-E2715 are shown.
Individual fractions were monitored by SDS-PAGE under nonreducing
conditions (data not shown). The monomeric, dimeric, and trimeric forms
of E2 are indicated. The triangles indicate the elution time of size
exclusion molecular weight standards. (B) Monomers (squares), dimers
(circles), and trimers (diamonds) of I-E2715 (solid
symbols) and S-E2715 (open symbols) were compared by their
capacity to bind MOLT-4 cells. Cell-bound E2 was measured by flow
cytometry using chimpanzee anti-E1-E2 antiserum and is indicated as net
MFI. The ability of the chimpanzee serum to recognize monomers, dimers,
and trimers of I-E2715 and S-E2715 was
confirmed by staining Western blots of E2 SDS-PAGE gels under
nonreducing conditions (data not shown). The effect of 50 µg of
soluble human CD81 LEL per ml on the binding of monomeric
I-E2715 (asterisk) and monomeric S-E2715 (star)
is represented.
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Sugar moieties are not necessary for E2 binding to human
cells.
Because the E2 protein elicited NOB antibodies upon
immunization and bound CD81 only when core glycosylated but not when
complex glycosylated, we tested whether core glycosylation was required for these activities. To this end, we performed binding studies using
deglycosylated E2. We digested I-E2715 with -mannosidase or with endo H and analyzed the products for the presence of
monosaccharides and for their binding activity.
-Mannosidase-digested E2 retains all GlcNAc residues compared to the
undigested control, as well as, most probably, the 14
GlcNAc-linked and some 13 mannose-linked mannose residues, which
are not efficiently cleaved by the enzyme (Table
1). Endo H digestion was complete, with
approximately half of the GlcNAc residues cleaved off and only trace
amounts of uncleaved mannose left. Importantly, the deglycosylated
forms and the undigested controls were identical in their capacity to bind CD81 (Fig. 4). The enzymes alone
have no binding activity (data not shown). Thus, core glycosylation is
not necessary for E2 binding to CD81 and complex glycosylation is
likely to mask the E2 binding epitope for its cellular receptor. This
also may explain the inability of complex glycosylated
S-E2715 to raise NOB antibodies after immunization. By
treating S-E2 with peptide-N-glycosidase F (PNGase F), which
removes complex sugars completely, we attempted to restore its binding
activity. However, PNGase F-digested S-E2 formed high-molecular-weight
aggregates, with the majority of the protein precipitating out of
solution. The aggregates that remained in solution did not migrate into
an SDS gel. This is presumably due to hydrophobic interactions
following removal of all hydrophilic carbohydrates or due to
conformational changes through the conversion of asparagine at the
N-glycosylation site to aspartate. Therefore, it was not possible to
compare completely deglycosylated S-E2 with untreated or endo H-treated
I-E2 (data not shown).
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FIG. 4.
Deglycosylation of I-E2 does not influence its binding
activity. I-E2715 was digested with -mannosidase or with
endo H. MOLT-4 binding activity of -mannosidase-treated (solid
circles) and endo H-treated (solid squares) E2 was compared to that of
mock-treated E2 (open symbols). Cell-bound E2 was measured by flow
cytometry using chimpanzee anti-E1-E2 antiserum and is indicated as net
MFI.
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Construction and in vitro analysis of ER-retained E2 DNA
vaccines.
Given the potential benefits of DNA vaccines over
recombinant proteins (12), we assessed the ability of
different E2 forms to stimulate humoral immunity if delivered in the
form of a DNA vaccine. Using the DNA vaccination vector pAC, we
constructed five E2-encoding plasmids (Fig.
5). (i) pAC-E2715 corresponds to the construct used for E2715 expression in CHO cells in
that it encodes the same C-terminally truncated E2, directed into the ER by a TPA-leader sequence fused to its N terminus (aa 384), and
driven by the human cytomegalovirus promoter. It was the basis for the
other constructs, which all have the same N terminus and were made by
modifying the C terminus of E2715. (ii and iii)
pAC-E2746 (ii) and pAC-E2809 (iii) encode two
naturally occurring membrane-anchored E2 species differing in their C
termini (aa 746 and 809, respectively). The larger product contains a
small highly hydrophobic region from aa 747 to 809, known as p7. Both
forms are retained in the ER (31, 36, 48). Because the
cellular localization of purified E2 antigen is critical, we assumed
that ER retention of E2 protein expressed by DNA vaccines would favor
the induction of NOB antibodies. (iv and v) Based on the same
rationale, we additionally constructed pAC-E2715DEL (iv) by
adding to the C-terminal lysine (aa 715) the three amino acids DEL to
obtain the canonical signal for ER retention of luminal proteins, the
amino acid motif KDEL (38), and pAC-E2730KK (v)
by fusing to the C terminus of the first transmembrane-spanning domain
of E2 (aa 730) the cytoplasmic tail of the adenovirus E3/19K protein,
which confers ER retention and retrieval to transmembrane proteins
(40, 50). The latter was constructed because despite the
convincing in vitro data indicating its retention in the ER, full-length E2 has been reported to be present on the plasma membrane of hepatocytes in transgenic mice (26).
View larger version (17K):
[in this window]
[in a new window]
|
FIG. 5.
Diagram of the E2 constructs used for DNA immunization.
The relevant HCV proteins are shown at the top. The black box
corresponds to the signal peptide at the C terminus of E1 directing E2
into the ER, and terminal amino acid positions in the constructs are
indicated. HCV sequences present in each construct are indicated by
black lines which are drawn to scale and oriented with respect to the
HCV proteins shown at the top. Grey boxes represent an N-terminal 25-aa
TPA-derived signal peptide directing E2 into the ER, the white box
indicates three additional C-terminal amino acids leading to the motif
KDEL, and the hatched box indicates the C-terminal cytoplasmic tail of
the adenovirus E3/19K protein (SRRSFIDEKKMP).
|
|
We next compared biochemical properties of E2 expressed in CHO cells
stably transfected with our five DNA vaccination constructs.
We were
not able to detect an E2
730KK protein, suggesting rapid
degradation possibly due to incorrect folding. The other forms
of E2
could be detected by Western blotting, and, as expected,
all four are
endo H sensitive, indicating an ER localization (Fig.
6). The proteins expressed from
pAC-E2
809 (E2-p7) and pAC-E2
746 (E2) have the
same apparent molecular weight, indicating that
p7 is cleaved,
consistent with previous reports (
31,
36,
48).
Endo H
digestion of these two membrane-anchored E2 forms leads
to the same
sharp double band, suggesting inaccessibility for
efficient cleavage of
one core carbohydrate unit or the presence
of an additional E2 form
shorter than E2
746. The two proteins
encoded by
pAC-E2
715 and pAC-E2
715DEL show a difference of
about
5 kDa in their apparent molecular mass and one sharp band after
endo H treatment. This suggests that the KDEL motif causes differences
in carbohydrate trimming in the ER or when the protein is recycled
between the ER and the
cis Golgi.
View larger version (69K):
[in this window]
[in a new window]
|
FIG. 6.
E2 stably expressed from the different DNA immunization
constructs in CHO cells is endo H sensitive. E2 was immunoprecipitated
from cell lysates with chimpanzee anti-E1-E2 antiserum and treated with
endo H (+) or left untreated ( ). The samples were analyzed by
SDS-PAGE (10% acrylamide) under reducing conditions and Western
blotting. Arrows indicate the presence of two closely migrating bands.
Sizes (in kilodaltons) of the molecular mass markers are indicated on
the left.
|
|
Comparison of DNA and protein immunization in mice.
We
analyzed the anti-E2 antibody response elicited in C57BL/6 mice after
i.m. priming and boosting. As seen before (Fig. 1B), immunization with
recombinant I-E2715 elicits high anti-E2 IgG titers and
good NOB titers in mice (Table 2). By
contrast, the antibody response generated by DNA immunization, using
either of our constructs, is both quantitatively and
qualitatively less efficacious. The two truncated E2 forms,
E2715 and E2715DEL, elicit comparable
antibody titers as measured by ELISA, but no NOB antibody titers were
detected. The two membrane-anchored forms, E2746 and E2809, elicit even lower anti-E2 IgG titers. However, these
two constructs did elicit low but detectable NOB titers in three out of
eight mice. The anti-E2 IgG ELISA titers in individual mice in a group
were all very similar (data not shown), suggesting that NOB titers do
not directly correlate with total anti-E2 IgG. Intriguingly,
pAC-E2730KK raises measurable anti-E2 antibody titers, although we were not able to detect the protein in transfected CHO
cells.
| |
DISCUSSION |
The experiments presented here were performed to determine the
optimal form of the HCV E2 antigen to include in a vaccine from the
perspective of the generation of antibodies. The quality of recombinant
E2 protein was assessed by two means: (i) the capacity to bind its
putative receptor CD81 on human target cells and (ii) the capacity to
elicit antibodies, in particular those that inhibit receptor binding
(NOB antibodies). We show that CHO cell-expressed truncated E2 protein,
when derived from the core glycosylated intracellular fraction (I-E2)
but not from the complex glycosylated secreted fraction (S-E2), binds
with high efficiency to human cells and elicits NOB antibodies in
guinea pigs. We also show that carbohydrate moieties are not necessary
for I-E2 binding to cellular targets and that only the monomeric
fraction binds efficiently compared to multimers. Moreover, comparing
recombinant I-E2 protein to several E2-encoding DNA vaccines in mice,
we found that for both quantity and quality of the antibody response,
protein immunization is superior to DNA. Based on these results, we
propose that, for the induction of antibody responses, the E2 antigen needed in a future HCV vaccine is a recombinant, monomeric protein purified from the intracellular fraction.
In chimpanzees vaccinated with the E1-E2 heterodimer, high NOB antibody
titers correlate with protection from infection with an homologous HCV
isolate (46). However, when vaccinated chimpanzees were
challenged with a heterologous virus, infection occurred in all animals
but 9 of the 10 vaccinees did not develop chronic infection (M. Houghton and S. Abrignani, unpublished data). Antisera from animals
immunized with recombinant E1-E2 derived from the HCV-1 strain
contained high titers of anti-E2 antibodies that were able to block
CD81 binding of recombinant E2 derived not only from HCV subtype 1a but
also from subtype 1b. By contrast, anti-E1 antibodies did not block the
binding of E1-E2 to human cells. Together, immunization experiments in
chimpanzees indicate that a vaccine based on HCV envelope proteins is
able to prevent at least chronic HCV infection and that in the E1-E2
heterodimer, it is E2 that can generate antibodies capable of blocking
virus binding to target cells. Thus, although sterilizing immunity was not achieved following challenge with heterologous virus, the prevention of chronic infection still holds promise, given that acute
HCV infections are often asymptomatic and clinically inconsequential.
In an effort to produce recombinant HCV E2 in CHO cells, we originally
focused on S-E2715, whose purification is easier to scale
up than is that of the intracellular fraction. Although we found that a
supernatant fraction of E2 obtained by affinity chromatography binds
human cells (46), we realized that our culture supernatant
contained only a minor fraction of biologically active (in our binding
assay) E2 protein. In an attempt to define the optimal forms of E2 for
binding CD81, we assessed intracellular or secreted fractions of
different truncated E2 proteins expressed in CHO cells. We found that
both I-E2661 and I-E2715 bind substantially better to CD81 than do S-E2661 and S-E2715. It
was found previously that S-E2661 binds well to CD81
(18). However, the same authors recently reviewed this
finding and reported that I-E2661 binds CD81 with higher
efficiency than does S-E2661 (19). Our results not only confirm this finding but also give a functional correlate to
the superior binding of I-E2 to CD81. We demonstrate, using S-E2715 or I-E2715 in immunization studies,
that both fractions elicit high anti-E2 antibody titers as assessed by
ELISA whereas only the I-E2 fraction raises NOB antibody titers. The
finding that deglycosylated I-E2715 binds CD81 on human
cells as well as untreated I-E2715 suggests that
carbohydrates are not directly involved in the recognition of CD81.
They could, however, play a role in the correct folding of E2 in the ER.
Given that robust virus cell entry assays and infection assays are not
available, we do not know whether CD81 mediates HCV entry into cells.
However, we have evidence that (i) CD81 is very inefficient in
mediating internalization of bound ligands (42) and (ii)
some hepatoma cell lines can bind recombinant envelope proteins in the
absence of CD81 (data not shown), suggesting that human cells contain
other molecules which interact with HCV and may mediate entry.
Recently, the low-density lipoprotein receptor has been proposed as a
possible HCV receptor (37) or, more generally, as a molecule
exploited by members of the family Flaviviridae to enter
human cells (1). However, until reliable infection assays
are available, it will always be difficult to sort out the relative
importance of candidate HCV receptors.
Little is known about the assembly and maturation of HCV. However,
studies with recombinant proteins indicate that noncovalent heterodimers of E1 and E2 reside in the ER and are core glycosylated. They have been proposed as the prebudding form of the HCV envelope glycoprotein complex (11, 14). When truncated forms of E2 pass through the Golgi and are secreted, they become complex
glycosylated. Our results indicate that these modifications almost
completely abolish the ability of E2 to bind to CD81 on human cells and
to elicit NOB antibodies. Our view is that these complex sugars mask the binding site, most probably through steric or charge interference. Based on the results reported here, I-E2 probably mimics the native envelope form present in the virus, and thus the viral envelope should
not be complex glycosylated. Consistent with this view, HCV could
assemble at the ER membrane, bud into the ER, and be released into the
extracellular environment by host cell lysis, similar to rotaviruses
(16). By this mechanism, complex carbohydrate modifications
are prevented because viral particles do not pass through the Golgi.
Alternatively, it may be that HCV exits through the Golgi in a form
which protects at least the carbohydrates in and around the CD81
binding site from further modifications.
For the development of a vaccine against intracellular pathogens (e.g.,
viruses), it is advantageous to optimize antibody, T-helper cell, and
CTL responses, all of which have been achieved by DNA vaccination of
experimental animals (12). However, here we show that DNA
vaccination elicits low ELISA titers of anti-E2 antibodies and low NOB
titers compared to immunization with E2 protein. These data parallel
results obtained by others with mice or small primates by using
truncated E2 constructs for DNA immunization (20, 21, 39).
Although NOB titers do not necessarily correlate with total anti-E2
antibody titers in our experience with human sera (46), we
cannot rule out that the low efficiency of NOB antibody production
following DNA immunization is a direct consequence of the inability of
the same DNA constructs to induce high anti-E2 antibody titers in
general. DNA vaccines encoding intracellular proteins elicit poor
antibody responses in comparison to secreted proteins (3).
E2-encoding DNA vaccines therefore might be limited by their inherent
inaccessibility to antibodies. Another possible explanation of the lack
of NOB antibody responses is that the uptake of DNA and the expression
of E2 in vivo alter the glycosylation pattern, localization, and/or
conformation of the E2 protein.
In conclusion, to elicit antibodies aimed at blocking HCV binding to
CD81 on human cells, protein immunization is superior to DNA
immunization. Cellular responses could potentially be achieved by
administering DNA in combination with recombinant protein, and
investigating the influence of one to another will be an important step
in defining optimal vaccination strategies for HCV.
| |
ACKNOWLEDGMENTS |
Jens M. Heile and Yiu-Lian Fong contributed equally to this work.
We thank Nicholas Valiante for critical reading of the manuscript and
insightful discussions, and we thank Giorgio Corsi for artwork.
J.M.H. was supported by EU grant PL 960505.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: IRIS Research
Center, Chiron, Via Fiorentina 1, Siena 53100, Italy. Phone: (39) 0577 243 032. Fax: (39) 0577 243 564. E-mail:
sergio_abrignani{at}biocine.it.
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Journal of Virology, August 2000, p. 6885-6892, Vol. 74, No. 15
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
