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Journal of Virology, July 1999, p. 5605-5612, Vol. 73, No. 7
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Mapping of Functional Elements in the Stem-Anchor
Region of Tick-Borne Encephalitis Virus Envelope Protein E
Steven L.
Allison,*
Karin
Stiasny,
Konrad
Stadler,
Christian W.
Mandl, and
Franz
X.
Heinz
Institute of Virology, University of Vienna,
Vienna, Austria
Received 16 December 1998/Accepted 12 April 1999
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ABSTRACT |
Envelope protein E of the flavivirus tick-borne encephalitis virus
mediates membrane fusion, and the structure of the N-terminal 80% of
this 496-amino-acid-long protein has been shown to differ significantly
from that of other viral fusion proteins. The structure of the
carboxy-terminal 20%, the stem-anchor region, is not known. It
contains sequences that are important for membrane anchoring, interactions with prM (the precursor of membrane protein M) during virion assembly, and low-pH-induced structural changes associated with
the fusion process. To identify specific functional elements in this
region, a series of C-terminal deletion mutants were constructed and
the properties of the resulting truncated recombinant E proteins were
examined. Full-length E proteins and proteins lacking the second of two
predicted transmembrane segments were secreted in a
particulate form when coexpressed with prM, whereas deletion of both
segments resulted in the secretion of soluble homodimeric E
proteins. Sites located within a predicted 
-helical region of the
stem (amino acids 431 to 449) and the first membrane-spanning region
(amino acids 450 to 472) were found to be important for the stability
of the prM-E heterodimer but not essential for prM-mediated intracellular transport and secretion of soluble E proteins. A separate
site in the stem, also corresponding to a predicted -helix (amino
acids 401 to 413), was essential for the conversion of soluble protein
E dimers to a homotrimeric form upon low-pH treatment, a process
resembling the transition to the fusogenic state in whole virions. This
functional mapping will aid in the understanding of the molecular
mechanisms of membrane fusion and virus assembly.
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INTRODUCTION |
Structural elements in the vicinity
of the membrane anchor participate in a number of important functions
of viral envelope proteins, including oligomerization, particle
assembly, and membrane fusion. In orthomyxoviruses (5) and
retroviruses (6, 7, 11, 29, 37, 39), structural data have
suggested that -helix-forming elements adjacent to the
membrane-spanning segment play an important role in the extensive
conformational changes that drive the fusion process, a feature that
appears to be shared by the paramyxoviruses (24) and
filoviruses (13, 38) as well.
Envelope protein E of tick-borne encephalitis (TBE) virus, a small
enveloped virus belonging to the genus Flavivirus of the family Flaviviridae, has a structure and subunit
organization fundamentally different from those of the examples
mentioned above, even though the functions they perform are similar.
The X-ray crystal structure (32) of a soluble ectodomain
fragment of this protein has revealed that it is a head-to-tail dimer
oriented parallel to the viral membrane, in contrast to most other
viral fusion proteins studied so far, which are trimeric spikes.
Another major difference is that the ectodomain fragment (sE dimer),
representing the N-terminal 80% of the molecule, consists mostly of
beta-sheet and loop structures and does not contain any long
-helical segments.
Although all of the known antigenic determinants, the putative receptor
binding site, and the putative fusion peptide reside in the ectodomain
portion of protein E (32), the remaining C-terminal 20% of
this protein, referred to as the stem-anchor region, has also been
shown to be important for a number of functions, including interactions
with the precursor of membrane protein M (prM) during viral assembly
(3), particle formation (3), and low-pH-induced structural changes associated with membrane fusion (36).
Newly synthesized E and prM proteins associate to form heterodimers
(3, 40). These are incorporated into immature virions, which
assemble in the endoplasmic reticulum and are transported via the
secretory pathway (33). The intracellular virions remain in
the immature form until shortly before release from the cell and then
are converted to the active mature form by cleavage of prM by the
cellular protease furin (35). Heterodimeric interactions between prM and E are important for proper transport and possibly folding of E (3, 25) and probably also for protection of the
immature virion against acid inactivation during transport through
acidic vesicles (14, 16, 19). Proper heterodimer interactions also appear to be required for the formation and secretion
of subviral particles, which are capable of self-assembly in the
absence of the nucleocapsid (3). These particles, which consist of native E and M proteins anchored in a lipid membrane (34), have been shown to have fusogenic properties similar
to those of whole virions (10, 34).
Membrane fusion requires acidic pH and is mediated by protein E, which,
in virions and recombinant subviral particles, is organized as a
metastable network of interacting homodimers (2, 34). When
exposed to acidic pH, the E dimers dissociate and reorganize
irreversibly into a homotrimeric form (2), a process that
appears to be required for fusion. Studies with protease-treated E
proteins have suggested that elements within the stem-anchor are
involved in the final formation of the E trimers, whereas the initial
low-pH-dependent dissociation of the dimer occurs mainly within the
ectodomain portion (36).
The stem-anchor region extends from the carboxy terminus of each of the
monomers of the crystallized ectodomain fragment, placing it at the
distal ends of the E homodimer (32). Although its structure
has not been investigated experimentally, sequence-based predictions
have allowed several potentially important structural elements to be
identified (30, 36). As shown in Fig.
1, these include two predicted
-helical regions in the stem, a conserved sequence (CS) separating
these predicted helices, and two predicted transmembrane segments in
the anchor portion. In this study, we have used this information as the
basis for constructing a series of C-terminally truncated E proteins
and have used these constructs to identify specific regions that are
important for interactions with prM, particle formation, and
low-pH-induced structural changes.
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FIG. 1.
Schematic diagram of a TBE virus protein E monomer (not
to scale) which, in the native structure, forms a homodimer with a
head-to-tail orientation. The three domains of the sE fragment (I, II,
and III), which was cleaved from purified virions by trypsin and used
previously for structure determination (32), are represented
by shaded ovals, and the positions of the putative fusion peptide at
the tip of domain II and the trypsin cleavage site next to domain III
are indicated. The part below the trypsin cleavage site represents the
C-terminal 20% of the E protein, for which only sequence-based
structure predictions are available (36). The viral membrane
is represented by parallel lines, and the portions of E corresponding
to the stem and anchor regions are indicated. H1pred
(residues 401 to 413) and H2pred (residues 431 to 449)
indicate predicted -helical regions in the stem, the CS element
(residues 414 to 430) separates these putative helices, and TM1
(residues 450 to 471) and TM2 (residues 473 to 496) are predicted
transmembrane segments (31). H2pred is
contiguous with TM1, and these together may constitute a continuous
-helix with its C-terminal half spanning the viral membrane. TM2,
which normally serves as the signal sequence for nonstructural protein
NS1, is depicted as traversing the membrane, but it is not known
whether it actually remains in the membrane after cleavage by
signalase, which separates the E and NS1 proteins during processing of
the viral polyprotein (33).
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MATERIALS AND METHODS |
Plasmid construction and mutagenesis.
Recombinant plasmids
for coexpression of truncated E proteins with prM were derived from
plasmid SV-PEwt (1), which contains cloned cDNA
corresponding to nucleotides 388 to 2550 of the genome of TBE virus
strain Neudoerfl (GenBank accession no. U27495). This construct
includes the last 31 codons of the C gene, the entire prM and E genes,
and the first 30 codons of the NS1 gene under the control of the simian
virus 40 (SV40) early promoter (Fig. 2).
It also contains an SV40 origin of replication for amplification in COS
cells. Deletion mutants were constructed by replacing a SnaBI-NotI fragment (nucleotides 1881 to 2550)
with a shorter PCR-generated fragment containing a TAG stop codon at
the appropriate position, followed immediately by a NotI
restriction site in place of the deleted sequence.
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FIG. 2.
C-terminal truncations in recombinant E proteins. The
diagram shows the amino acid (aa) positions of the C-terminal
truncations and which of the predicted structural elements of the
stem-anchor region were present in each construct (Fig. 1 contains the
definitions of the abbreviations). These proteins are designated by an
E followed by the number of the last amino acid residue. The portion of
the TBE genome containing the prM and E genes, cloned into a plasmid
vector under the control of the SV40 early promoter (1), is
shown at the top. Small arrows indicate the sites where the polyprotein
is cleaved by signalase (33), and the short flanking
sequences belonging to the C and NS1 coding regions are labeled.
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For expression of E400 without prM, the
SnaBI-
NotI fragment containing the C-terminal
deletion was excised from the prM+E400
construct (Fig.
2) and inserted
in place of the corresponding
SnaBI-
NotI fragment
of plasmid SV-Ewt, which codes for protein
E alone (
1). The
resulting plasmid contained nucleotides 883
to 2172 of the TBE virus
genome and thus lacked all but the last
30 codons of the protein M
coding region, which were retained
to provide a signal sequence for
protein E. Plasmid SV-prM, for
expression of prM alone, was described
previously (
3).
Plasmids were propagated in
Escherichia coli HB101 and
purified by using a Qiagen Plasmid Mega Kit. The sequences of the
PCR-generated
portions, including the ligation junctions, were verified
for
each plasmid preparation before further
use.
Expression, purification, and quantitation of E proteins.
COS-1 cells (ATCC CRL 1659) were grown in Dulbecco's minimum essential
medium (MEM; Life Technologies) supplemented with 10% fetal bovine
serum, penicillin (100 U/ml), and streptomycin (100 µg/ml) at 37°C
in 5% CO2. Cells were transfected with purified plasmid by
electroporation using a Bio-Rad Gene Pulser apparatus. The cell culture
medium was replaced 22 h after transfection with serum-free
bicarbonate- and HEPES-buffered Dulbecco's MEM (Life Technologies),
and incubation was continued for 24 h until harvest. Cell culture
supernatants were cleared by centrifugation at 10,000 rpm (16,000 × g) for 30 min at 4°C in a Sorvall F16/250 rotor, concentrated
by ultrafiltration, and partially purified by centrifugation at 38,000 rpm for 20 h at 4°C in a 5 to 20% (wt/wt) sucrose gradient using a Beckman SW-40 rotor. For the pelleting experiments, the cleared
supernatant was used without further treatment. The protein E
concentration was determined by using a quantitative four-layer enzyme-linked immunosorbent assay (ELISA) after denaturation with sodium dodecyl sulfate (SDS) as described previously (19) by using SDS-treated virus or soluble protein E dimers (sE fragment) (18) as a standard. Hemagglutination (HA) activity was
measured at pH 6.4 by the method of Clarke and Casals (9)
with goose erythrocytes.
Metabolic labeling and immunoprecipitation.
Cells were
washed 41 h after transfection and incubated for 1 h at
37°C in methionine- and cysteine-free Dulbecco's MEM (Bio Whittaker). Labeling medium, consisting of the same medium with 1/20 of
the normal concentration of unlabeled cysteine,
[35S]cysteine (Amersham), and the normal concentration of
unlabeled methionine, was then applied to the cells, and labeling was
continued for 6 h. After labeling, the cells were washed and lysed
in a buffer consisting of 50 mM Tris-HCl (pH 8.0), 150 mM NaCl, 2 mM EDTA, 1% Triton X-100, 1 mM phenylmethylsulfonyl fluoride, and aprotinin at 2 µg/ml.
Lysates (70 µl) were precleared by using 2 µl of rabbit anti-mouse
immunoglobulin (Nordic) and 40 µl of a 50% slurry of protein
A
Sepharose (Pharmacia) in incubation buffer (20 mM Tris-HCl [pH
8.0],
150 mM NaCl, 2 mM EDTA, 0.5% Triton X-100, 1 mM phenylmethylsulfonyl
fluoride, aprotinin at 2 µg/ml). The specific antibody (2 µl)
and 2 µl of rabbit anti-mouse immunoglobulin were then added to
the lysate,
and the mixture was incubated for 30 min at room temperature.
The
protein A Sepharose slurry (40 µl) was then added, and incubation
was
continued for 1 h at room temperature with continuous, gentle
rocking. Immunoprecipitates were collected by centrifugation and
washed
twice with incubation buffer, twice with incubation buffer
containing
500 instead of 150 mM NaCl, and twice with 63 mM Tris-HCl
(pH 6.8). The
precipitated material was solubilized by heating
for 5 min at 95°C in
40 µl of electrophoresis sample buffer (
26)
and analyzed
by SDS-polyacrylamide gel electrophoresis (PAGE)
and fluorography.
Protein sizes were estimated by comparison to
radiolabeled molecular
weight standards
(Amersham).
Chemical cross-linking, gel electrophoresis, and
immunoblotting.
Chemical cross-linking with dimethylsuberimidate
(DMS) was done as described previously (2). The cross-linked
proteins were separated by electrophoresis on 5% polyacrylamide gels
using a continuous phosphate-buffered system as described by Maizel (28), blotted onto polyvinylidene difluoride membranes, and detected as described previously (35). The polyacrylamide
gels used in the immunoprecipitation experiments were made by the
method of Laemmli and Favre (26).
Low-pH treatment.
For analysis of low-pH-induced changes,
partially purified protein E preparations containing 0.5% Triton X-100
were acidified by adding the appropriate amount of a stock solution of
150 mM morpholineethanesulfonic acid (MES) and 0.5% Triton X-100 to
yield a final pH of 6.0. The final protein E concentration of each
sample was 40 µg/ml. The samples were incubated for 4 h at
25°C and then back-neutralized to pH 8.0 by using a stock solution of
150 mM triethanolamine and 0.5% Triton X-100.
Sedimentation analysis.
For analysis of prM-E complexes,
samples were applied to 5 to 20% (wt/wt) sucrose gradients made with
50 mM triethanolamine (pH 8.0), 100 mM NaCl, and 0.5% Triton X-100 and
centrifuged for 22 h at 38,000 rpm and 15°C in a Beckman SW-40
rotor. Fractions of 0.6 ml were collected by upward displacement using
an ISCO model 640 fraction collector and analyzed by
immunoprecipitation and SDS-PAGE as described above.
For analysis of the oligomeric structure of soluble secreted E
proteins, 7 to 20% (wt/wt) sucrose gradients containing 0.1%
Triton
X-100 were used and centrifugation was carried out for
20 h at
15°C. These samples were then analyzed by four-layer ELISA
for
protein E quantitation (
19) or chemical cross-linking and
gel electrophoresis (see
above).
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RESULTS |
Construction of deletion mutants.
To map the functionally
important regions within the protein E stem-anchor region, we
engineered a series of C-terminal deletions into wild-type expression
plasmid SV-PEwt (1), which has been used previously for
correct coexpression of prM and E proteins and production of
recombinant subviral particles (3, 10, 17, 34). In each
construct, a TAG stop codon was introduced at a position corresponding
to the boundary of one of the predicted structural elements represented
in Fig. 1 and the rest of the TBE virus-derived cDNA downstream from
that site was deleted. The positions of the protein E truncations are
shown in Fig. 2, with the number in the protein designation indicating
the last amino acid before the stop codon (e.g., E472 consists of the
first 472 amino acids of protein E). We truncated protein E472 after TM1, protein E449 after H2pred, protein E430 after CS,
protein E413 after H1pred, and protein E400 before
H1pred. In addition, a previously described construct
(SV-PEst) (1) containing a stop codon at position 435 but no
deletion was used for coexpression of prM and E434, which is truncated
within the H2pred element.
Interactions of truncated E proteins with prM.
To examine the
expression of the recombinant proteins and assess the requirements for
formation of the prM-E heterodimer, the TBE virus proteins were
expressed in COS-1 cells by transfection with the appropriate
recombinant plasmid and the cells were metabolically labeled with
[35S]cysteine and lysed in a pH 8.0 buffer containing 1%
Triton X-100. The proteins were then immunoprecipitated by using a
monoclonal antibody (MAb) specific for either protein E (MAb A5)
(15) or prM (MAb 8HI) (23) and analyzed by
SDS-PAGE as shown in Fig. 3.
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FIG. 3.
SDS-PAGE of recombinant TBE virus proteins after
immunoprecipitation with E-specific (A) and prM-specific (B) MAbs. COS
cells were transfected with recombinant plasmids encoding prM together
with one of the truncated forms of protein E shown in Fig. 2,
radiolabeled, and lysed in a buffer containing 1% Triton X-100. The
proteins were then immunoprecipitated, separated by SDS-PAGE, and
visualized by fluorography. The values on the left are molecular
weights.
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As expected, all of the C-terminally truncated E proteins were
efficiently precipitated by MAb A5 (Fig.
3A), which is known
to bind to
a site in domain II of protein E (
32). Each of the
truncated
E proteins was of the predicted size, indicating that
proper processing
had occurred. The full-length (wild-type) control,
shown in Fig.
3A,
was also of the predicted size, but in this
particular sample an
additional weaker band migrating more slowly
than protein E could also
be seen. This is possibly due to incomplete
processing of the
C-terminal end of full-length protein E, which
terminates at a
signalase cleavage site, rather than a stop codon
(Fig.
2).
Consistent with earlier results (
3), full-length protein E
(Ewt) and prM coexpressed in COS cells formed a detergent-stable
heterodimer which could be immunoprecipitated by either protein
E-specific MAb A5 (Fig.
3A) or prM-specific MAb 8HI (Fig.
3B).
Some of
the truncations, however, resulted in decreased efficiency
of
coprecipitation, suggesting that they had a direct influence
on prM-E
interactions. As shown in Fig.
3A, prM was efficiently
coprecipitated
with both Ewt and E472 when the protein E-specific
MAb was used but the
relative intensity of the prM band was somewhat
weaker with E449 and
much weaker still with E434, E430, E413,
and E400. Immunoprecipitation
of the same samples with a polyclonal
antiserum recognizing both prM
and protein E showed that the differences
in prM band intensity were
not due to differences in the relative
level of protein expression
(data not shown). Analogous results
were obtained when a prM-specific
MAb (8HI) was used instead to
precipitate the prM-E complex (Fig.
3B);
the relative efficiency
of coprecipitation with prM was strong with Ewt
and E472, intermediate
with E449, and weak with E434, E430, E413, and
E400.
To further investigate the stability of the prM-E complexes, the cell
lysates used in the experiment whose results are shown
in Fig.
3 were
placed on sucrose gradients containing 0.5% Triton
X-100 and
sedimentation analysis was carried out to evaluate the
degree to which
prM remained associated with each of the truncated
E proteins. As shown
in Fig.
4A, prM and Ewt sedimented as a
stable
complex and the band intensity ratio for these two proteins was
the same in each of the peak fractions. The sedimentation velocity
of
this complex was shown previously to correspond to a heterodimer
containing one prM molecule and one protein E molecule (
3).
A similar pattern of cosedimentation was observed with the prM-E472
complex (Fig.
4B), consistent with the coimmunoprecipitation results.
In contrast, the prM-E449 heterodimer, although clearly present
in
fractions 6 to 8, appeared to have partially dissociated during
centrifugation, with some prM proteins at a higher position in
the
gradient (Fig.
4C). In the case of E430, the prM protein did
not remain
associated at all and the proteins were found in separate
fractions
(Fig.
4D). E434, E413, and E400 also failed to cosediment
with prM
under these conditions (data not shown). These data suggest
that the
H2
pred element and the TM1 portion of protein E make an
important contribution
to the stability of the prM-E heterodimer.
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FIG. 4.
Cosedimentation analysis of prM and truncated E
proteins. The cell lysates used in the experiment depicted in Fig. 3
were analyzed by centrifugation in sucrose gradients (5 to 20%, wt/wt)
containing 0.5% Triton X-100. Proteins were immunoprecipitated from
the gradient fractions by using a polyclonal antiserum recognizing both
prM and protein E, separated by SDS-PAGE, and visualized by
fluorography. Panels: A, prM and Ewt; B, prM and E472; C, prM and E449;
D, prM and E430. The sedimentation direction is left to right.
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Effect of truncations on the physical structure of secreted
proteins.
Analysis of cell culture supernatants revealed that all
of the truncated E proteins were secreted together with the mature M
protein and that the kinetics of protein E secretion were essentially identical for all of the constructs shown in Fig. 2 (data not shown).
To assess the physical form of these proteins, cell supernatants that
were harvested and cleared 48 h after transfection were subjected to ultracentrifugation and the amounts of protein E in the supernatant and pellet fractions were quantitated. As shown in Fig.
5, Ewt coexpressed with prM was found
almost exclusively in the pellet fraction, which was expected because
it had already been shown that this protein gets incorporated into
30-nm-diameter membrane-containing subviral particles (34).
Of the truncated E proteins, E472 was the only one for which the
majority of the material was found in the pellet fraction after
centrifugation. This material, like the wild-type subviral particles,
also possessed HA activity. These data suggest that E472 can also be
incorporated into a subviral particle using only the TM1 segment as its
membrane anchor. The other truncated E proteins (E449, E434, E430,
E413, and E400), all of which lacked both of the predicted
transmembrane segments, were present primarily in a soluble free form
that remained in the supernatant fraction and did not possess any HA
activity. Although E449 did tend to make a significant amount of
pelletable material (Fig. 5), this material was found to consist of
insoluble aggregates that were readily distinguishable from wild-type
subviral particles by their different sedimentation properties and lack of HA activity (data not shown).
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FIG. 5.
Pelleting efficiencies and HA activities of secreted E
proteins. Cleared supernatants from transfected COS cells were
subjected to ultracentrifugation, and the amounts of protein E in the
pellet and supernatant fractions after centrifugation were quantitated
by ELISA. HA activity was determined both before and after pelleting.
+, HA activity detected both before pelleting and in the pelleted
fraction;  , no HA activity detected.
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The oligomeric state of the soluble truncated forms of protein E (E449,
E434, E430, E413, and E400) was then investigated
by chemical
cross-linking analysis. Cell supernatants were concentrated
by
ultrafiltration and treated with the bifunctional cross-linker
DMS,
which is known to form cross-links between the ectodomains
of the
protein E dimer (
18). SDS-PAGE and immunoblotting of
the
DMS-treated proteins (Fig.
6) revealed
that all of the extracellular
soluble truncated E proteins were in the
homodimeric state, demonstrating
that the outer portion of the protein
E ectodomain has the intrinsic
ability to dimerize in the absence of
the stem-anchor. Furthermore,
all of these dimers yielded essentially
identical reactivity profiles
when tested in a four-layer ELISA system
using a panel of MAbs
recognizing different parts of protein E (data
not shown). Therefore,
the extent of the deletion in the stem-anchor
did not appear to
influence the overall folding of the protein E
ectodomain.
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FIG. 6.
Cross-linking analysis of soluble truncated E proteins.
Partially purified E proteins were analyzed by SDS-PAGE and
immunoblotting after treatment with the cross-linking reagent DMS. The
positions of the protein E monomer and dimer bands are indicated. +,
cross-linker added; , no cross-linker.
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Effect of truncations on prM-mediated secretion.
Earlier
experiments have shown that both full-length and C-terminally truncated
E434 proteins require coexpression with prM for efficient secretion
(3). It was therefore somewhat surprising that the
elimination of H2pred, which contributes to the stability
of the prM-E heterodimer, did not seem to impair the ability of the
soluble E proteins to be secreted. This suggests either that other
interactions with prM outside the protein E stem-anchor region are used
for prM-mediated transport and secretion or that the shorter forms of
protein E do not require prM for secretion. To distinguish between
these possibilities, a new plasmid construct encoding protein E400 but lacking the prM gene was made and this, together with a plasmid encoding prM alone, was used in a cotransfection experiment to assess
the effect of prM on secretion.
As shown in Fig.
7, the efficiency of
protein E400 secretion was drastically reduced when prM was omitted
from the construct.
The level of secretion could be partially restored,
however, by
providing prM in
trans by cotransfection,
demonstrating that prM
is still capable of influencing the secretion of
protein E even
when the entire stem-anchor region is deleted. These
data therefore
suggest that there are further interactions between prM
and the
outer domains of protein E, separate from those in the stem
region,
that are involved in prM-mediated transport and secretion of
protein
E.
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FIG. 7.
Effect of coexpression with prM on E400 secretion
efficiency. COS cells were transfected with expression plasmids
encoding prM and E400 in the same construct (A), E400 alone (B), or prM
and E400 on separate plasmids (C). At 29 h posttransfection, a
protein E-specific four-layer ELISA (20) was used to detect
secreted protein E in the supernatant. The transfection efficiency, as
judged by immunofluorescence using a protein E-specific MAb, was the
same (~50%) in all three samples (data not shown).
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Effect of truncations on low-pH-induced structural changes.
Earlier work has already revealed that protein E dimers dissociate and
reorganize into homotrimers when exposed to low pH and that the
stem-anchor region is important for the trimerization step
(36). To map the location of a possible trimerization site in this region, we tested the abilities of the different soluble dimeric forms of protein E to undergo rearrangement into trimers after
acid treatment. For these experiments, the truncated E proteins were
first partially purified by sucrose gradient centrifugation in the
absence of detergent. Under these conditions, the M proteins were
removed as higher-molecular-weight complexes and the fractions containing the semipurified E proteins were judged by immunoblotting to
be free of protein M (data not shown).
Protein E samples containing 0.5% Triton X-100 were treated at pH 6.0 (final protein E concentration, 40 µg/ml), back-neutralized
to pH
8.0, and subjected to sedimentation analysis in a detergent-containing
sucrose gradient to assess their oligomeric state. Full-length
detergent-solubilized E proteins from TBE virus were used as a
standard
for comparison (
36). As shown in Fig.
8A, treatment
of solubilized full-length
E proteins at low pH caused an irreversible
conversion of dimers to
trimers and the resulting shift in sedimentation
velocity was identical
to that observed previously when solubilized
E proteins from
low-pH-treated virions were used (
2). Proteins
E449, E434,
E430, and E413 also clearly retained the ability to
form trimers, and
the sedimentation profile from the shortest
of these, E413, is shown in
Fig.
8B. The identities of the dimer
and trimer peaks in these
experiments were also confirmed by chemical
cross-linking (Fig.
8A and
B, insets).
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FIG. 8.
Sedimentation analysis of detergent-solubilized E
proteins at pH 8.0 (solid curves) or after pretreatment at pH 6.0 and
back-neutralization to pH 8.0 (dashed curves). Samples were centrifuged
in sucrose gradients (7 to 20%, wt/wt) containing 0.1% Triton X-100,
and the amount of protein E in each fraction was quantitated by ELISA.
For the insets, material from the peak fractions was subjected to DMS
cross-linking and immunoblotting as described in the legend to Fig. 6.
M, monomer; D, dimer; T, trimer.
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In contrast to the longer forms, E400, which differs from E413 only by
the lack of the 13-amino-acid-long H1
pred element, was
completely unable to form trimers under the conditions
used, and after
back-neutralization, only dimers were detected
by both sedimentation
analysis and cross-linking (Fig.
8C). Even
when the E400 concentration
during the incubation at low pH was
increased to 80 µg/ml, no
trimerization could be detected (data
not shown). If the sample was not
back-neutralized, however, and
the sedimentation analysis was carried
out at pH 6.0, the E400
protein sedimented as a monomer (data not
shown), as has been
shown previously with E proteins whose stem-anchor
region had
been proteolytically removed (
36). This indicates
that the E400
dimer undergoes a reversible dissociation in response to
low-pH
treatment but, due to the lack of the H1
pred
element, does not assemble into the trimeric
form.
Although E449, E434, E430, and E413 were efficiently converted to
trimers at low pH, monomeric forms could be detected under
conditions
that were kinetically unfavorable for trimerization
in solution, e.g.,
a lower protein E concentration (2 µg/ml) (data
not shown). This is
consistent with a two-step trimerization mechanism
(
36) in
which the truncated protein E dimers first dissociate
in response to
low pH and then, if the H1
pred element is present,
reassociate in a subsequent step to create
the trimeric
form.
| |
DISCUSSION |
The results of this study allow fine mapping of functionally
important elements within the C-terminal 20% of TBE virus protein E
and also provide new information about functions that are independent of the stem-anchor region. A summary is provided in Table
1.
Domains I, II, and III (ectodomain).
The ectodomain, defined
here as the entire portion preceding the stem-anchor, consists of
approximately the first 400 amino acids of protein E, and its
three-dimensional structure has been solved by X-ray crystallography
(32). It is composed of three separate structural domains
(designated I, II, and III), which contain all of the known antigenic
determinants, as well as the putative receptor-binding site and fusion
peptide. All three of these domains participate in homodimeric contacts
between the E monomers, and the dimeric state is preserved when the
ectodomain fragment is removed from the virion by limited trypsin
digestion (18, 32). The present study demonstrated that
C-terminally truncated recombinant E proteins lacking part or all of
the stem-anchor are secreted in a dimeric form, indicating that the
known contacts between the ectodomains are sufficient not only for
maintenance of the dimeric state but also for initial formation of the
E dimer in vivo. The ectodomain contacts are pH sensitive, and both
recombinant protein E400 and the viral ectodomain fragment obtained by
trypsin cleavage (36) dissociate in a reversible manner when
exposed to low pH. This suggests that the acid-sensitive trigger for
the fusion reaction resides in the ectodomain rather than in the stem.
In contrast to the protein E homodimer interactions, the heterodimeric
interactions between prM and protein E appear to involve
both the
ectodomain and the stem-anchor. Indirect evidence based
on comparison
of antibody binding to mature and immature flaviviruses
(
14,
19) has suggested that domain II of the protein E ectodomain
is
involved in these contacts (
32). Our observation that
coexpression
with prM enhances the efficiency of secretion of E
proteins lacking
the entire stem-anchor provides further indirect
evidence that
prM associates with the ectodomain of protein E and that
these
interactions are of particular importance for the efficient
transport
of protein
E.
The stem.
An important finding of this study is that a
predicted -helical element in the stem, H1pred (amino
acids 401 to 413) appears to be involved in the formation of protein E
homotrimers in solution upon low-pH treatment. Proteins lacking this
sequence and the rest of the stem-anchor are still secreted in a
dimeric form that dissociates at low pH but does not go on to form
trimers. In contrast, E proteins that were truncated immediately after
the H1pred element could be irreversibly converted by
low-pH treatment to the trimeric form. It is therefore likely that
residues within this element either are directly involved in trimeric
contacts between the subunits of the low-pH form of protein E or
facilitate the conversion of monomers into trimers.
Unexpectedly, our data did not reveal a function for the CS element
(amino acids 414 to 430), the part of the stem that is
most highly
conserved among flaviviruses (
36). Although its
high degree
of conservation (8 of 17 residues are invariable)
implies an important
function, it does not seem to be directly
involved in homodimeric or
trimeric interactions between the E
proteins or heteromeric
interactions with
prM.
The H2
pred element (amino acids 431 to 449) and the TM1
element (amino acids 450 to 472) were found to be important for the
stability
of the prM-E dimer and therefore may interact directly with
prM.
The weakening of the prM-E interaction by the deletion of TM1,
however, could also be due to a general destabilizing effect on
H2
pred caused by the truncation of a putative continuous
-helix extending
through both H2
pred and TM1
(
36).
The anchor.
The predicted transmembrane elements TM1 and TM2
lie at the extreme C-terminal end of protein E and are predicted to
constitute a double membrane anchor (30). It was revealed by
sequential deletion that the second of these (TM2, amino acids 473 to
496) is dispensable for the incorporation of protein E into recombinant subviral particles, whereas E proteins with both segments deleted are secreted as free homodimers when coexpressed with prM. Since the
TM2 element serves as a signal sequence for the nonstructural protein
NS1 during flavivirus protein synthesis (33), it is possible
that it has no further functional role in mature protein E, although it
is still likely to make a contribution to the overall structural
organization of the virion.
Functional role of the stem region.
In contrast to most of the
viral fusion proteins that have been studied so far, which are trimeric
in both the native and fusogenic states (21), the
detergent-stable form of TBE virus protein E is a homodimer in its
native state but is irreversibly converted to a trimeric form at the pH
of fusion (2). We demonstrate here that recombinant protein
E dimers expressed in COS cells are capable of undergoing this
transformation in solution when exposed to low pH and that the other
viral membrane protein, M, is not required for this process.
From the head-to-tail orientation of the sE dimer, it is predicted that
the stem regions of the two subunits would not interact
with each other
in the neutral form, since they extend down from
the distal ends of the
dimer and are therefore separated by a
distance of several nanometers
(
32). Recently, however, we presented
a model in which
direct interactions between the stem regions
of adjacent protein E
subunits on the virion surface are proposed
to be responsible for the
formation of trimers at low pH (
36).
The present data are
consistent with this model, but it cannot
yet be concluded whether the
stem regions actually make contact
with each other in the trimeric
state or whether other portions
of the molecule are
involved.
The H1
pred element has been predicted to be a
13-amino-acid-long amphipathic
-helix (
36) and, by
analogy to the fusogenic proteins
of other enveloped viruses (
4,
5-7,
11,
12,
24,
27,
29,
37-39), might be expected to
participate in the formation
of a trimeric core structure during the
membrane fusion process.
This analogy, however, is severely limited by
the fact that TBE
virus protein E does not appear to have the potential
to form
long coiled coils of
-helices, a central feature of the
general
model that is now emerging for other viral fusion proteins
(
8,
22,
39). It is therefore likely that not only the role
of
the stem region but also the overall mechanism leading to membrane
fusion might differ significantly from the established paradigm,
with
flavivirus protein E representing a different structural
class of
fusion protein. Further studies carried out in the presence
of target
membranes are necessary in order to relate structural
changes to the
membrane fusion event itself, but the mapping results
shown here should
provide important clues regarding the possible
roles of specific
structures in this
process.
| |
ACKNOWLEDGMENTS |
We thank Melby Wilfinger, Angela Dohnal, and Walter Holzer for
technical assistance; Regina Kofler for help with plasmid construction; and C. S. Schmaljohn, USAMRIID, Ft. Detrick, Md., for providing MAb 8HI.
Part of this work was supported by a grant from the International Human
Frontier Science Program.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Institute of
Virology, University of Vienna, Kinderspitalgasse 15, A-1095 Vienna,
Austria. Phone: 43-1-404-90, ext. 79505. Fax: 43-1-406-21-61. E-mail:
steven.allison{at}univie.ac.at.
| |
REFERENCES |
| 1.
|
Allison, S. L.,
C. W. Mandl,
C. Kunz, and F. X. Heinz.
1994.
Expression of cloned envelope protein genes from the flavivirus tick-borne encephalitis virus in mammalian cells and random mutagenesis by PCR.
Virus Genes
8:187-198[Medline].
|
| 2.
|
Allison, S. L.,
J. Schalich,
K. Stiasny,
C. W. Mandl,
C. Kunz, and F. X. Heinz.
1995.
Oligomeric rearrangement of tick-borne encephalitis virus envelope proteins induced by an acidic pH.
J. Virol.
69:695-700[Abstract].
|
| 3.
|
Allison, S. L.,
K. Stadler,
C. W. Mandl,
C. Kunz, and F. X. Heinz.
1995.
Synthesis and secretion of recombinant tick-borne encephalitis virus protein E in soluble and particulate form.
J. Virol.
69:5816-5820[Abstract].
|
| 4.
|
Blacklow, S. C.,
M. Lu, and P. S. Kim.
1995.
A trimeric subdomain of the simian immunodeficiency virus envelope glycoprotein.
Biochemistry
34:14955-14962[Medline].
|
| 5.
|
Bullough, P. A.,
F. M. Hughson,
J. J. Skehel, and D. C. Wiley.
1994.
Structure of influenza haemagglutinin at the pH of membrane fusion.
Nature
371:37-43[Medline].
|
| 6.
|
Caffrey, M.,
M. Cai,
J. Kaufman,
S. J. Stahl,
P. T. Wingfield,
D. G. Covell,
A. M. Gronenborn, and G. M. Clore.
1998.
Three-dimensional solution structure of the 44 kDa ectodomain of SIV gp41.
EMBO J.
17:4572-4584[Medline].
|
| 7.
|
Chan, D. C.,
D. Fass,
J. M. Berger, and P. S. Kim.
1997.
Core structure of gp41 from the HIV envelope glycoprotein.
Cell
89:263-273[Medline].
|
| 8.
|
Chan, D. C., and P. S. Kim.
1998.
HIV entry and its inhibition.
Cell
93:681-684[Medline].
|
| 9.
|
Clarke, D. H., and J. Casals.
1958.
Techniques for hemagglutination and hemagglutination inhibition with arthropod-borne viruses.
Am. J. Trop. Med. Hyg.
7:561-573.
|
| 10.
| Corver, J., A. Ortiz, S. L. Allison, J. Schalich,
F. X. Heinz, and J. Wilschut. Membrane fusion activity of
tick-borne encephalitis (TBE) virus and recombinant subviral particles
(RSPs) in a liposomal model system. Submitted for publication.
|
| 11.
|
Fass, D.,
S. C. Harrison, and P. S. Kim.
1996.
Retrovirus envelope domain at 1.7 Angstrom resolution.
Nat. Struct. Biol.
3:465-469[Medline].
|
| 12.
|
Fass, D., and P. S. Kim.
1995.
Dissection of a retrovirus envelope protein reveals structural similarity to influenza hemagglutinin.
Curr. Biol.
5:1377-1383[Medline].
|
| 13.
|
Gallaher, W. R.
1996.
Similar structural models of the transmembrane proteins of Ebola and avian sarcoma viruses.
Cell
85:477-478[Medline].
|
| 14.
|
Guirakhoo, F.,
R. A. Bolin, and J. T. Roehrig.
1992.
The Murray Valley encephalitis virus prM protein confers acid resistance to virus particles and alters the expression of epitopes within the R2 domain of E glycoprotein.
Virology
191:921-931[Medline].
|
| 15.
|
Guirakhoo, F.,
F. X. Heinz, and C. Kunz.
1989.
Epitope model of tick-borne encephalitis virus envelope glycoprotein E: analysis of structural properties, role of carbohydrate side chain, and conformational changes occurring at acidic pH.
Virology
169:90-99[Medline].
|
| 16.
|
Guirakhoo, F.,
F. X. Heinz,
C. W. Mandl,
H. Holzmann, and C. Kunz.
1991.
Fusion activity of flaviviruses: comparison of mature and immature (prM-containing) tick-borne encephalitis virions.
J. Gen. Virol.
72:1323-1329[Abstract/Free Full Text].
|
| 17.
|
Heinz, F. X.,
S. L. Allison,
K. Stiasny,
J. Schalich,
H. Holzmann,
C. W. Mandl, and C. Kunz.
1995.
Recombinant and virion-derived soluble and particulate immunogens for vaccination against tick-borne encephalitis.
Vaccine
13:1636-1642[Medline].
|
| 18.
|
Heinz, F. X.,
C. W. Mandl,
H. Holzmann,
C. Kunz,
B. A. Harris,
F. Rey, and S. C. Harrison.
1991.
The flavivirus envelope protein E: isolation of a soluble form from tick-borne encephalitis virus and its crystallization.
J. Virol.
65:5579-5583[Abstract/Free Full Text].
|
| 19.
|
Heinz, F. X.,
K. Stiasny,
G. Püschner-Auer,
H. Holzmann,
S. L. Allison,
C. W. Mandl, and C. Kunz.
1994.
Structural changes and functional control of the tick-borne encephalitis virus glycoprotein E by the heterodimeric association with protein prM.
Virology
198:109-117[Medline].
|
| 20.
|
Heinz, F. X.,
W. Tuma,
F. Guirakhoo, and C. Kunz.
1986.
A model study of the use of monoclonal antibodies in capture enzyme immunoassays for antigen quantification exploiting the epitope map of tick-borne encephalitis virus.
J. Biol. Stand.
14:133-141[Medline].
|
| 21.
|
Hernandez, L. D.,
L. R. Hoffman,
T. G. Wolfsberg, and J. M. White.
1996.
Virus-cell and cell-cell fusion.
Annu. Rev. Cell Dev. Biol.
12:627-661[Medline].
|
| 22.
|
Hughson, F. M.
1997.
Enveloped viruses: a common mode of membrane fusion?
Curr. Biol.
7:R565-R569[Medline].
|
| 23.
|
Iacono-Connors, L. C.,
J. F. Smith,
T. G. Ksiazek,
C. L. Kelley, and C. S. Schmaljohn.
1996.
Characterization of Langat virus antigenic determinants defined by monoclonal antibodies to E, NS1 and preM and identification of a protective, non-neutralizing preM-specific monoclonal antibody.
Virus Res.
43:125-136[Medline].
|
| 24.
|
Joshi, S. B.,
R. E. Dutch, and R. A. Lamb.
1998.
A core trimer of the paramyxovirus fusion protein: parallels to influenza virus hemagglutinin and HIV-1 gp41.
Virology
248:20-34[Medline].
|
| 25.
|
Konishi, E., and P. W. Mason.
1993.
Proper maturation of the Japanese encephalitis virus envelope glycoprotein requires cosynthesis with the premembrane protein.
J. Virol.
67:1672-1675[Abstract/Free Full Text].
|
| 26.
|
Laemmli, U. K., and M. Favre.
1973.
Maturation of the head of bacteriophage T4. I. DNA packaging events.
J. Mol. Biol.
80:575-599[Medline].
|
| 27.
|
Lu, M.,
S. C. Blacklow, and P. S. Kim.
1995.
A trimeric structural domain of the HIV-1 transmembrane glycoprotein.
Nat. Struct. Biol.
2:1075-1082[Medline].
|
| 28.
|
Maizel, J. V., Jr.
1971.
Polyacrylamide gel electrophoresis of viral proteins.
Methods Virol.
5:179-246.
|
| 29.
|
Malashkevich, V. N.,
D. C. Chan,
C. T. Chutkowski, and P. S. Kim.
1998.
Crystal structure of the simian immunodeficiency virus (SIV) gp41 core: conserved helical interactions underlie the broad inhibitory activity of gp41 peptides.
Proc. Natl. Acad. Sci. USA
95:9134-9139[Abstract/Free Full Text].
|
| 30.
|
Mandl, C. W.,
F. Guirakhoo,
H. Holzmann,
F. X. Heinz, and C. Kunz.
1989.
Antigenic structure of the flavivirus envelope protein E at the molecular level, using tick-borne encephalitis virus as a model.
J. Virol.
63:564-571[Abstract/Free Full Text].
|
| 31.
|
Mandl, C. W.,
F. X. Heinz, and C. Kunz.
1988.
Sequence of the structural proteins of tick-borne encephalitis virus (Western subtype) and comparative analysis with other flaviviruses.
Virology
166:197-205[Medline].
|
| 32.
|
Rey, F. A.,
F. X. Heinz,
C. Mandl,
C. Kunz, and S. C. Harrison.
1995.
The envelope glycoprotein from tick-borne encephalitis virus at 2 Å resolution.
Nature
375:291-298[Medline].
|
| 33.
|
Rice, C. M.
1996.
Flaviviridae: the viruses and their replication, p. 931-959.
In
B. N. Fields, D. N. Knipe, P. M. Howley, R. M. Chanock, J. L. Melnick, T. P. Monath, B. Roizman, and S. E. Straus (ed.), Virology, 3rd ed. Lippincott-Raven, Philadelphia, Pa.
|
| 34.
|
Schalich, J.,
S. L. Allison,
K. Stiasny,
C. W. Mandl,
C. Kunz, and F. X. Heinz.
1996.
Recombinant subviral particles from tick-borne encephalitis virus are fusogenic and provide a model system for studying flavivirus envelope glycoprotein functions.
J. Virol.
70:4549-4557[Abstract].
|
| 35.
|
Stadler, K.,
S. L. Allison,
J. Schalich, and F. X. Heinz.
1997.
Proteolytic activation of tick-borne encephalitis virus by furin.
J. Virol.
71:8475-8481[Abstract].
|
| 36.
|
Stiasny, K.,
S. L. Allison,
A. Marchler-Bauer,
C. Kunz, and F. X. Heinz.
1996.
Structural requirements for low-pH-induced rearrangements in the envelope glycoprotein of tick-borne encephalitis virus.
J. Virol.
70:8142-8147[Abstract].
|
| 37.
|
Tan, K.,
J.-H. Liu,
J.-H. Wang,
S. Shen, and M. Lu.
1997.
Atomic structure of a thermostable subdomain of HIV-1 gp41.
Proc. Natl. Acad. Sci. USA
94:12303-12308[Abstract/Free Full Text].
|
| 38.
|
Weissenhorn, W.,
L. J. Calder,
S. A. Wharton,
J. J. Skehel, and D. C. Wiley.
1998.
The central structural feature of the membrane fusion protein subunit from the Ebola virus glycoprotein is a long triple-stranded coiled coil.
Proc. Natl. Acad. Sci. USA
95:6032-6036[Abstract/Free Full Text].
|
| 39.
|
Weissenhorn, W.,
A. Dessen,
S. C. Harrison,
J. J. Skehel, and D. C. Wiley.
1997.
Atomic structure of the ectodomain from HIV-1 gp41.
Nature
387:426-430[Medline].
|
| 40.
|
Wengler, G., and G. Wengler.
1989.
Cell-associated West Nile flavivirus is covered with E+Pre-M protein heterodimers which are destroyed and reorganized by proteolytic cleavage during virus release.
J. Virol.
63:2521-2526[Abstract/Free Full Text].
|
Journal of Virology, July 1999, p. 5605-5612, Vol. 73, No. 7
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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-
Nickells, M., Chambers, T. J.
(2003). Neuroadapted Yellow Fever Virus 17D: Determinants in the Envelope Protein Govern Neuroinvasiveness for SCID Mice. J. Virol.
77: 12232-12242
[Abstract]
[Full Text]
-
Huang, C. Y.-H., Butrapet, S., Tsuchiya, K. R., Bhamarapravati, N., Gubler, D. J., Kinney, R. M.
(2003). Dengue 2 PDK-53 Virus as a Chimeric Carrier for Tetravalent Dengue Vaccine Development. J. Virol.
77: 11436-11447
[Abstract]
[Full Text]
-
Lorenz, I. C., Kartenbeck, J., Mezzacasa, A., Allison, S. L., Heinz, F. X., Helenius, A.
(2003). Intracellular Assembly and Secretion of Recombinant Subviral Particles from Tick-Borne Encephalitis Virus. J. Virol.
77: 4370-4382
[Abstract]
[Full Text]
-
Chambers, T. J., Liang, Y., Droll, D. A., Schlesinger, J. J., Davidson, A. D., Wright, P. J., Jiang, X.
(2003). Yellow Fever Virus/Dengue-2 Virus and Yellow Fever Virus/Dengue-4 Virus Chimeras: Biological Characterization, Immunogenicity, and Protection against Dengue Encephalitis in the Mouse Model. J. Virol.
77: 3655-3668
[Abstract]
[Full Text]
-
Op De Beeck, A., Molenkamp, R., Caron, M., Ben Younes, A., Bredenbeek, P., Dubuisson, J.
(2002). Role of the Transmembrane Domains of prM and E Proteins in the Formation of Yellow Fever Virus Envelope. J. Virol.
77: 813-820
[Abstract]
[Full Text]
-
Molenkamp, R., Kooi, E. A., Lucassen, M. A., Greve, S., Thijssen, J. C. P., Spaan, W. J. M., Bredenbeek, P. J.
(2002). Yellow Fever Virus Replicons as an Expression System for Hepatitis C Virus Structural Proteins. J. Virol.
77: 1644-1648
[Abstract]
[Full Text]
-
Lorenz, I. C., Allison, S. L., Heinz, F. X., Helenius, A.
(2002). Folding and Dimerization of Tick-Borne Encephalitis Virus Envelope Proteins prM and E in the Endoplasmic Reticulum. J. Virol.
76: 5480-5491
[Abstract]
[Full Text]
-
Stiasny, K., Allison, S. L., Schalich, J., Heinz, F. X.
(2002). Membrane Interactions of the Tick-Borne Encephalitis Virus Fusion Protein E at Low pH. J. Virol.
76: 3784-3790
[Abstract]
[Full Text]
-
Gibbons, D. L., Kielian, M.
(2002). Molecular Dissection of the Semliki Forest Virus Homotrimer Reveals Two Functionally Distinct Regions of the Fusion Protein. J. Virol.
76: 1194-1205
[Abstract]
[Full Text]
-
Mackenzie, J. M., Westaway, E. G.
(2001). Assembly and Maturation of the Flavivirus Kunjin Virus Appear To Occur in the Rough Endoplasmic Reticulum and along the Secretory Pathway, Respectively. J. Virol.
75: 10787-10799
[Abstract]
[Full Text]
-
Chambers, T. J., Nickells, M.
(2001). Neuroadapted Yellow Fever Virus 17D: Genetic and Biological Characterization of a Highly Mouse-Neurovirulent Virus and Its Infectious Molecular Clone. J. Virol.
75: 10912-10922
[Abstract]
[Full Text]
-
Guirakhoo, F., Arroyo, J., Pugachev, K. V., Miller, C., Zhang, Z.-X., Weltzin, R., Georgakopoulos, K., Catalan, J., Ocran, S., Soike, K., Ratterree, M., Monath, T. P.
(2001). Construction, Safety, and Immunogenicity in Nonhuman Primates of a Chimeric Yellow Fever-Dengue Virus Tetravalent Vaccine. J. Virol.
75: 7290-7304
[Abstract]
[Full Text]
-
Stiasny, K., Allison, S. L., Mandl, C. W., Heinz, F. X.
(2001). Role of Metastability and Acidic pH in Membrane Fusion by Tick-Borne Encephalitis Virus. J. Virol.
75: 7392-7398
[Abstract]
[Full Text]
-
Allison, S. L., Schalich, J., Stiasny, K., Mandl, C. W., Heinz, F. X.
(2001). Mutational Evidence for an Internal Fusion Peptide in Flavivirus Envelope Protein E. J. Virol.
75: 4268-4275
[Abstract]
[Full Text]
-
Holbrook, M. R., Wang, H., Barrett, A. D. T.
(2001). Langat Virus M Protein Is Structurally Homologous to prM. J. Virol.
75: 3999-4001
[Abstract]
[Full Text]
-
Arroyo, J., Guirakhoo, F., Fenner, S., Zhang, Z.-X., Monath, T. P., Chambers, T. J.
(2001). Molecular Basis for Attenuation of Neurovirulence of a Yellow Fever Virus/Japanese Encephalitis Virus Chimera Vaccine (ChimeriVax-JE). J. Virol.
75: 934-942
[Abstract]
[Full Text]
-
Lee, E., Lobigs, M.
(2000). Substitutions at the Putative Receptor-Binding Site of an Encephalitic Flavivirus Alter Virulence and Host Cell Tropism and Reveal a Role for Glycosaminoglycans in Entry. J. Virol.
74: 8867-8875
[Abstract]
[Full Text]
-
Huang, C. Y.-H., Butrapet, S., Pierro, D. J., Chang, G.-J. J., Hunt, A. R., Bhamarapravati, N., Gubler, D. J., Kinney, R. M.
(2000). Chimeric Dengue Type 2 (Vaccine Strain PDK-53)/Dengue Type 1 Virus as a Potential Candidate Dengue Type 1 Virus Vaccine. J. Virol.
74: 3020-3028
[Abstract]
[Full Text]
-
Aberle, J. H., Aberle, S. W., Allison, S. L., Stiasny, K., Ecker, M., Mandl, C. W., Berger, R., Heinz, F. X.
(1999). A DNA Immunization Model Study with Constructs Expressing the Tick-Borne Encephalitis Virus Envelope Protein E in Different Physical Forms. J. Immunol.
163: 6756-6761
[Abstract]
[Full Text]
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Abstract
Introduction
