Previous Article | Next Article 
Journal of Virology, February 1999, p. 1419-1426, Vol. 73, No. 2
Department of Microbiology, University of
Pennsylvania School of Medicine, Philadelphia, Pennsylvania 19104-6076
Received 13 July 1998/Accepted 3 November 1998
Proteolytic processing is required for the activation of numerous
viral glycoproteins. Here we show that the envelope glycoprotein from
the Zaire strain of Ebola virus (Ebo-GP) is proteolytically processed
into two subunits, GP1 and GP2, that are likely
covalently associated through a disulfide linkage. Murine leukemia
virions pseudotyped with Ebo-GP contain almost exclusively processed
glycoprotein, indicating that this is the mature form of Ebo-GP.
Mutational analysis identified a dibasic motif, reminiscent of
furin-like protease processing sites, as the Ebo-GP cleavage site.
However, analysis of Ebo-GP processing in LoVo cells that lack the
proprotein convertase furin demonstrated that furin is not required for
processing of Ebo-GP. In sharp contrast to other viral systems, we
found that an uncleaved mutant of Ebo-GP was able to mediate infection of various cell lines as efficiently as the wild-type, proteolytically cleaved glycoprotein, indicating that cleavage is not required for the
activation of Ebo-GP despite the conservation of a dibasic cleavage
site in all filoviral envelope glycoproteins.
The glycoproteins of many enveloped
viruses are initially synthesized as inactive precursors that, while
able to bind to their cognate cellular receptors, are unable to mediate
membrane fusion and, hence, viral entry. Proteolytic processing of the
precursor polyprotein at specific cleavage sites is required to convert these glycoproteins to an active state and render the virus infectious. Examples of such viral glycoproteins include the envelope proteins of
retroviruses such as human immunodeficiency virus type 1 (HIV-1) (27) and the avian leukosis and sarcoma viruses (ASLV)
(8) as well as the hemagglutinin (HA) glycoprotein of the
orthomyxovirus influenza A virus (24, 25) and the
paramyxovirus Newcastle disease virus F protein (29, 35).
Endoproteolytic cleavage of the envelope glycoprotein is thus a
critical step in the maturation of a virus, and the availability of
cellular enzymes capable of processing the precursor polyprotein can be
a major determinant of viral tropism and pathogenicity. For example,
the HA glycoproteins of certain avirulent strains of influenza A
viruses can be efficiently processed only by the endoproteases present
within the cells of the respiratory tract (47). These
viruses are therefore restricted to the respiratory tract and cannot
cause a disseminating infection. In pathogenic viral strains,
introduction of a polybasic cleavage site into HA renders the
glycoprotein susceptible to proteolytic processing by a family of
widely expressed cellular proteases, thereby expanding viral tropism
(3, 23). It is believed that this expanded tropism is a
pivotal determinant of the increased virulence of these viruses.
The envelope glycoproteins of the Ebola and Marburg viruses display
significant homology to the oncoretroviral transmembrane (TM)
glycoproteins (5, 45), especially those of ASLV
(12). More striking than the strong amino acid similarities
between these glycoproteins is the conservation of many putative
functional domains such as a central CX6CC motif, the
potential coiled coil, and the putative fusion peptide. Also conserved
in all strains of Ebola virus is a stretch of basic residues that in
ASLV constitute an endoproteolytic cleavage site (21, 32).
Furthermore, the spacing between this basic residue-rich region and the
adjacent presumptive fusion peptide is nearly identical between the
Ebola virus and ASLV glycoproteins (1). This structural
similarity suggests that the glycoproteins of Ebola virus and ASLV may
utilize similar mechanisms to mediate membrane fusion and viral entry even though the triggers for these processes are clearly different: the
ASLV envelope requires receptor-mediated activation, and the Ebola
virus envelope glycoprotein (Ebo-GP) is pH dependent (6, 41,
48).
Since this dibasic motif is conserved in all strains of Ebola virus and
is in a position analogous to the cleavage site of ASLV envelope, we
hypothesized that Ebo-GP is endoproteolytically processed. Analysis of
both wild-type and epitope-tagged forms of Ebo-GP revealed that this
glycoprotein is proteolytically cleaved during maturation and that the
two resulting subunits appear to be disulfide linked. Mutational
analysis of the conserved dibasic motif identified this region as the
Ebo-GP endoproteolytic processing site. Surprisingly, our results show
that an uncleaved mutant of Ebo-GP is efficiently incorporated into
murine leukemia virus (MLV) particles and is able to efficiently
mediate viral entry, indicating that, in contrast to nearly all other
viral systems where glycoprotein processing is observed, proteolytic
cleavage is not essential for the membrane fusion activity of Ebo-GP.
Cell lines and antibodies.
Human embryonic kidney 293T cells
were maintained in Dulbecco's modified Eagle medium supplemented with
10% bovine calf serum. Baby hamster kidney (BHK), murine NIH 3T3,
African green monkey kidney (Vero and BSC-1), LoVo human colon
carcinoma, Tb 1 lu bat lung, and bovine aorta endothelial cells were
maintained in Dulbecco's modified Eagle medium supplemented with 10%
fetal calf serum and nonessential amino acids (0.1 mM). All cell lines
were in addition supplemented with penicillin (100 U/ml) and
streptomycin (100 mg/ml).
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Endoproteolytic Processing of the Ebola Virus
Envelope Glycoprotein: Cleavage Is Not Required for Function
ABSTRACT
Top
Abstract
Introduction
Materials and methods
Results
Discussion
References
INTRODUCTION
Top
Abstract
Introduction
Materials and methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and methods
Results
Discussion
References
Plasmids and viruses. pHIT60 and pHIT111 have been described previously (37). Plasmid pGEM7hFurin was kindly provided by Gary Thomas (Vollum Institute, Portland, Oreg.). The expression plasmid pCB6-Ebo-GP, encoding the envelope glycoprotein of the Mayinga strain of the Ebola virus Zaire subtype has been described previously (48), as has the EnvA expression plasmid, pCB6-EnvA (13). Plasmid pGEM-EMGP2, which contains the Ebo-GP cDNA is described in reference 36.
The Ebo-GP cDNA was excised from pGEM-EMGP2 by using the BamHI and KpnI restriction enzymes and cloned into plasmid pSP72 under the control of the T7 promoter. This plasmid was named pSP72-Ebo-GP. An overlapping extension PCR protocol was used to produce an epitope-tagged version of Ebo-GP, termed Ebo-T, in which the 4 carboxyl-terminal amino acids of Ebo-GP were exchanged with the 23 carboxyl-terminal amino acids of EnvA. PCR was performed with pGEM-EMGP2 and pCB6-EnvA as templates. The flanking PCR primers used were OS 336 (5'-CGCTGAAGGTGTCGTTGC-3'), which is specific for a pGEM-EMGP2 sequence, and OS 168 (5'-CAGGGATCCGATGCTACTATATCC-3'), which is specific for a pCB6-EnvA sequence. The internal primers used were OS 444 (5'-TTATTCTGTATATGCAGAAAGATGATTAAT-3') and its reverse complement, OS 345. This final PCR product was digested with restriction enzymes EcoRV and BamHI and cloned into pCB6-Ebo-GP to create plasmid pCB6-Ebo-T and into pSP72-Ebo-GP to create plasmid pSP72-Ebo-T. A similar PCR strategy was used to produce the proteolytic processing site mutants CL-1 and CL(
). In this case, the DNA templates used were
pGEM-EMGP2 and pCB6-Ebo-T so as to produce the mutants in both the
wild-type (Ebo-GP) and epitope-tagged (Ebo-T) forms of Ebo-GP. The
flanking primers used were OS 336 and either OS 7 (5'-AATACGACTCACTATAG-3'), which is specific for the T7
primer in pGEM-EMGP2, or OS 168, which is specific for pCB6-EnvA and thus pCB6-Ebo-T. The internal primers used were either OS 446 (5'-AGAAGAACTGCAGCAGAAGCAATTGTCAATGCT-3') and OS 447 (5'-TGCTGCAGTTCTTCTCCCGCCTGTGATCAG-3') for production of the
CL-1 mutant, OS 503 (5'-AGAGCAACTGCAAGAGAAGCAATTGTCAATGCT-3') and OS 504 (5'-TCTTGCAGTTGCTCTCCCGCCTGTGATCAG-3') for
production of the CL-2 mutant, OS 505 (5'-AGAGCAACTGCTGCAGAAGCAATTGTCAATGCT-3') and OS 506 (5'-TGCAGCAGTTGCTCTCCCGCCTGTGATCAG-3') for production of the
CL-3 mutant, OS 437 (5'-GCAGGTACCGCAGCAGAAGCAATTGTCAATGCT-3') and OS438 (5'-GAAGTAGGTACCTGCCCCGCCTGTGATCAGTCC-3')
for production of the CL-7 mutant, or OS 435 (5'-GCAGGTACCGCAGCAGAAGCAATTGTCAATGCT-3') and OS 436 (5'-TGCTGCGGTACCTGCCCCGCCTGTGATCAGTCC-3') for production of
the CL() mutant. These PCR products were either digested with the
EcoRV and EcoRI restriction enzymes and cloned
into pCB6-Ebo-GP to produce plasmids pCB6-Ebo-GP.CL-1 and
pCB6-Ebo-GP.CL() or digested with EcoRV and
BamHI and cloned into pBC6-Ebo-T to produce plasmids
pCB6-Ebo-T.CL-1 and pCB6-Ebo-T.CL().
The vaccinia virus vTF-7, encoding the T7 polymerase, was obtained from
Bernie Moss, National Institutes of Health.
Sanchez et al. (36) have described a putative signal peptide
at the amino terminus of Ebo-GP. The predicted cleavage site for this
signal peptide removes the amino-terminal 32 amino acids of Ebo-GP and
produces a mature form of the protein which has an Ile in the
amino-terminal position. All numbering of the Ebo-GP amino acid
sequence will therefore start with Ile1.
Production of MLV pseudotypes.
MLV particles pseudotyped
with the various forms of Ebo-GP described above were produced through
modification of a transient MLV packaging system as previously
described (37). Briefly, 20 µg of either
pCB6-Ebo-GP, pCB6-Ebo-T, pCB6-Ebo-GP.CL-1, pCB6-Ebo-GP.CL(), pCB6-Ebo-T.CL-1, or pCB6-Ebo-T.CL() was mixed with 20 µg of a plasmid encoding the MLV Gag-Pol (pHIT60) and 20 µg of a plasmid containing a packageable genome encoding the 
-galactosidase reporter gene (pHIT111). 293T cells were transfected with these DNA mixtures by
a standard CaPO4 procedure (48) to produce
MLV(Ebo-GP), MLV(Ebo-T), MLV(Ebo-GP.CL-1), MLV(Ebo-GP.CL(),
MLV(Ebo-T.CL-1), or MLV(Ebo-T.CL()) respectively. Approximately
48 h posttransfection, the cellular supernatants containing these
viruses were collected and clarified by filtration through
0.45-µm-pore-size syringe filters. These supernatants were stored at
either 4 or 80°C as viral stocks.
Dissociation of GP1 and GP2.
MLV(Ebo-GP), MLV(Ebo-T), and MLV(Ebo-GP.CL()) were produced as
described above and centrifuged at 25,000 rpm in an SW28 rotor for 90 min. The supernatants were decanted, and the viral pellets resuspended
in TNE buffer (50 mM Tris [pH 8], 130 mM NaCl, 1 mM EDTA) overnight
at 4°C. Urea (8 M in PBS) was added to these viral stocks to a final
concentration of 0, 2, 4, or 6 M in the presence or absence of
dithiothreitol (DTT) at a final concentration of 100 mM. These
solutions were incubated at 37°C for 30 min and then layered onto
20% sucrose in PBS and centrifuged at 55,000 rpm in an SW55 rotor for
15 min. The resulting viral pellets were lysed in RIPA buffer and
resolved by SDS-PAGE. Ebo-GP expression was detected by Western
blotting with the anti-Ebo-GP and anti-RSV tail sera, as described above.
Expression of Ebo-GP and Ebo-T in LoVo cells. LoVo cells were seeded at 3 × 105 cells/well of a six-well dish the day before transfection. Mixtures containing either no DNA, 5 µg of pSP72-Ebo-T, or 5 µg of pSP72-Ebo-T and 5 µg of pGEM7hFurin were prepared and used to transfect the LoVo cells by a standard CaPO4 method as described above. Two hours posttransfection, the cells were refed and infected with the vaccinia virus vTF-7 at a multiplicity of infection of approximately 10. One hour postinfection, the cells were again refed. Eighteen hours postinfection, the cells were lysed in Triton lysis buffer (50 mM Tris [pH 8], 5 mM EDTA, 150 mM NaCl, 1% Triton X-100). Cellular lysates were resolved by SDS-PAGE, and expression of the different forms of Ebo-T was examined by Western blot analysis with the anti-RSV tail serum as described above.
Analysis of Ebo-GP processing requirement for viral entry.
All cell lines described above were seeded at 3 × 105
to 5 × 105 cells/well of a six-well dish the day
before infection. Various dilutions [1:1, 1:10, or 1:100, depending on
the previously observed MLV (vesicular stomatitis virus) pseudotype
titer on the various cell types (48)] of either MLV(Ebo-GP)
or MLV(Ebo-GP.CL()) were made in 1 ml of maintenance medium and used
to challenge these cells as described previously (48). Equal
amounts of either MLV(Ebo-GP) or MLV(Ebo-GP.CL()) were used in each
infection as judged by Western blot analysis of lysed virions with the
anti-Ebo-GP serum and by visualization of MLV Gag proteins by Ponceau S
staining of nitrocellulose membranes to which viral lysates resolved by SDS-PAGE had been transferred. Forty eight hours postchallenge, the
cells were fixed with 2% paraformaldehyde and stained for -galactosidase activity as described previously (48).
Viral titers were determined by microscopic examination of stained
cells and the enumeration of -galactosidase-positive cells. These
titers were expressed as the number of -galactosidase-positive cells per milliliter of viral stock used in the infection (infectious units
[IU] per milliliter). The multiplicity of infection in these experiments was always less than 0.1.
| |
RESULTS |
|---|
|
Top
Abstract
Introduction
Materials and methods
Results
Discussion
References
|
|---|
Production of an epitope-tagged form of Ebo-GP. To facilitate analysis of the Ebola virus glycoproteins, we introduced an epitope tag at the carboxyl terminus of Ebo-GP. An overlapping extension PCR protocol was used to exchange the nucleotides encoding the 4 carboxyl-terminal amino acids of Ebo-GP with those encoding the 12 carboxyl-terminal amino acids of EnvA. The resulting PCR product was cloned into the expression plasmid pCB6 under the control of the cytomegalovirus immediate-early promoter, to create plasmid pCB6-Ebo-T. Plasmid pCB6-Ebo-GP, which encodes the wild-type form of Ebo-GP, has been described previously (48). A schematic diagram of the predicted protein products of both pCB6-Ebo-GP (Ebo-GP) and pCB6-Ebo-T (Ebo-T) is shown in Fig. 1A.
|
). To
evaluate the incorporation of Ebo-GP and Ebo-T into MLV virions, 293T
cells were transfected with MLV Gag-Pol and genome constructs with
either pCB6-Ebo-GP (Ebo-GP) or pCB6-Ebo-T (Ebo-T) or without a
glycoprotein construct (Mock). Viral supernatants were collected and
partially purified by pelleting through 20% sucrose. Cell lysates (B)
and lysed pellets (C and D) were analysed by SDS-PAGE and Western
blotting with either the anti-Ebo-GP serum (B and C) or the anti-RSV
tail serum (D). Arrows indicate the GP1, GP2,
and GP0 proteins; positions of molecular mass markers (in
kilodaltons) are shown to the left of each gel.
Production and analysis of MLV(Ebo-GP) and MLV(Ebo-T)
pseudotypes.
We have previously demonstrated efficient
incorporation of Ebo-GP into MLV particles (48). To examine
the incorporation of the epitope-tagged Ebo-T into MLV particles, 293T
cells were transiently transfected with plasmids encoding MLV
gag/pol (pHIT 60), an MLV genome containing a
-galactosidase reporter gene (pHIT111), and either pCB6-Ebo-GP or
pCB6-Ebo-T. Forty-eight hours posttransfection, cellular supernatants,
containing MLV(Ebo-GP) or MLV(Ebo-T), respectively, were collected,
clarified by filtration, and stored as viral stocks at either 4 or
80°C.
Dissociation of GP1 from MLV(Ebo-T) by reduction and denaturation. The detection of two different Ebo-GP-specific bands in the lysates of pseudotyped virions strongly suggested that Ebo-GP is a cleaved glycoprotein. We reasoned that if Ebo-GP on the virion was indeed cleaved, then we should be able to separate the two subunits by mild denaturation and/or reduction.
To examine the potential proteolytic processing of the Ebola virus glycoproteins, MLV(Ebo-GP) and MLV(Ebo-T) pseudotypes were produced as described above and concentrated by ultracentrifugation, and the viral pellets were resuspended overnight in an isotonic buffer. These virions were then treated with various concentrations of urea in the presence or absence of 100 mM DTT for 30 min at 37°C. Following this incubation, the virions were centrifuged through 20% sucrose to separate the virion-associated proteins from those dissociated from the particles by denaturation and/or reduction. The resulting viral pellet was lysed in RIPA buffer, and protein composition was analyzed by SDS-PAGE and Western blotting with either the anti-Ebo-GP or anti-RSV tail serum. Lysates of untreated MLV(Ebo-T) virions demonstrated both GP1- and GP2-specific bands when analyzed with the anti-Ebo-GP and anti-RSV tail sera (Fig. 2, lanes 1). Treatment of the MLV(Ebo-T) pseudotypes with up to 6 M urea in the absence of DTT did not alter the protein composition of the virions from that seen in untreated virions (Fig. 2; compare lanes 1, 3, 4, and 5). However, treatment of these virions with 100 mM DTT either alone or in combination with 6 M urea dramatically reduced the intensity of the GP1-specific band, while GP2 remained associated with the virion (Fig. 2; lanes 2 and 6). This result indicates that these treatments were sufficient to dissociate the two subunits from one another. Similar analysis of virions carrying the Ebo-GP also demonstrated a specific loss of GP1 with either 100 mM DTT or 6 M urea-100 mM DTT treatment (data not shown). These data strongly support the hypothesis that Ebo-GP is endoproteolytically processed into two subunits during maturation. Furthermore, it suggests that the two subunits are covalently associated by disulfide bonds.
|
Production of site-directed mutations within the proposed Ebo-GP
proteolytic processing site.
Conserved within the glycoproteins of
all known filoviruses is a consensus dibasic proteolytic processing
site similar to that found in other viral glycoproteins such as ASLV
EnvA and the HIV-1 envelope glycoprotein (8, 27) (Fig.
3A). In the envelope glycoprotein from
the Mayinga strain of Ebola virus Zaire subtype used for these studies,
this putative dibasic processing site comprises Arg465, Arg466, Thr467,
Arg468, and Arg 469 (RRTRR). To determine whether this sequence
comprised the endoproteolytic processing site, we introduced two
mutations into both the Ebo-GP and Ebo-T cDNAs. These mutations were
designed to replace the basic arginine residues of this putative
processing site with apolar amino acids. In the mutant CL-1, Arg468 and
Arg469 were changed to Ala to produce the sequence RRTAA; in the mutant
CL(), this sequence was changed to AGTAA (Fig. 3B). To analyze the
effects of these mutations on processing, MLV particles pseudotyped
with either Ebo-T, Ebo-T.CL-1, or Ebo-T.CL() were produced as
described above, partially purified by centrifugation through 20%
sucrose, and analyzed by SDS-PAGE and Western blotting with the
anti-RSV tail serum. These results demonstrated that like Ebo-T, the
Ebo-T.CL-1 mutant was incorporated efficiently into virions and was
processed efficiently into two subunits, as Western blot analysis
revealed the presence of GP2, and not GP0, in
the MLV(Ebo-GP.CL-1) virion lysates (Fig. 3C; compare lanes 2 and 3).
Analysis of virions produced with Ebo-GP.CL() also indicated
efficient incorporation of this mutant glycoprotein, however, in this
instance, Western blot analysis with the anti-RSV tail serum revealed
the specific loss of GP2 and the gain of an approximately
160-kDa band (Fig. 3C, lane 4). This larger form of Ebo-GP was likely
representative of the unprocessed form of Ebo-GP, GP0,
suggesting that this mutation blocked the endoproteolytic processing of
Ebo-T. In support of this hypothesis, Western blot analysis of MLV
particles pseudotyped either Ebo-GP, Ebo-GP.CL-1, or Ebo-GP.CL() with
the anti-Ebo-GP serum also demonstrated a specific loss of
GP1 in the lysates of virions pseudotyped with the
Ebo-GP.CL() glycoprotein and the gain of an approximately 160-kDa
band (data not shown). Together, these data strongly suggest that the
identified dibasic motif in the envelope glycoprotein of Ebola Zaire is
the endoproteolytic processing site.
|
GP0 is not dissociated from MLV(Ebo-GP.CL()) by
reduction and denaturation.
The CL() mutation (AGTAA) appears to
block endoproteolytic processing of the Ebola virus glycoprotein. To
confirm this observation, we attempted to determine if the presumably
unprocessed glycoprotein in virions carrying this mutant glycoprotein
were resistant to dissociation by reduction and denaturation. Wild-type
and CL()-pseudotyped virions were produced as described above and
gently ultracentrifuged, and the resulting viral pellets were
resuspended in an isotonic buffer overnight at 4°C. These
concentrated virions were then treated with 100 mM DTT, alone or with 6 M urea, for 30 min at 37°C. Virion-associated proteins were partially
purified by centrifugation through 20% sucrose. After lysis with RIPA
buffer, the protein composition of the pelleted virions was analyzed by
SDS-PAGE and Western blotting with the polyclonal anti-Ebo-GP antibody.
)-pseudotyped virions
under either of these conditions did not result in a significant
release of the glycoprotein from the virions (Fig. 4B). These results
strongly support the hypothesis that the Ebo-GP.CL() protein
represents an uncleaved form of Ebo-GP.
|
Proteolytic processing of Ebo-GP does not require furin. Furin is a widely expressed cellular protease that cleaves proteins at paired basic amino acid sites (20). Moreover, it has been shown to be responsible for the cleavage of a number of viral glycoproteins, including the human parainfluenza virus type 3 F protein (31) and the HAs of various strains of pathogenic influenza A viruses (19, 40). To address whether furin is the cellular enzyme responsible for the endoproteolytic processing of Ebo-GP, we attempted to express this envelope glycoprotein in a human colon carcinoma cell line (LoVo) that specifically lacks furin activity (42, 43).
Ebo-T was expressed in LoVo cells with or without the coexpression of human furin. Cellular lysates were prepared, resolved by SDS-PAGE and examined by Western blot analysis with both the anti-Ebo-GP and anti-RSV tail sera. When these cellular lysates were examined with the anti-Ebo-GP polyclonal serum, it was apparent that Ebo-T produced in LoVo cells was of a greater apparent molecular mass than when furin was coexpressed (Fig. 5A; compare lanes 1 and 2). This larger form of Ebo-GP, found specifically in the lysates of LoVo cells expressing Ebo-T alone, appears to be similar in size to GP0, suggesting that in the absence of furin, Ebo-T is not efficiently cleaved. Similar results were obtained when the wild-type form of Ebo-GP was expressed in LoVo cells (data not shown). However, when these same cellular lysates were examined with the anti-RSV tail serum, it became apparent that there was significant processing of Ebo-T in these furin-deficient LoVo cells. In addition, an increased amount of GP2 was observed when human furin was coexpressed in the LoVo cells with Ebo-T (Fig. 5B, lanes 1 and 2). The presence of GP2 in the LoVo cell lysates indicates that Ebo-T is endoproteolytically processed in the absence of furin and implies that furin is likely not the only cellular enzyme responsible for the endoproteolytic processing of Ebo-GP.
|
Analysis of entry mediated by Ebo-GP.CL().
The conservation
of an endoproteolytic processing site in the glycoproteins of all known
strains of Ebola virus strongly suggests that cleavage may be important
for glycoprotein function. To investigate the importance of processing
for Ebo-GP-mediated viral entry, we produced MLV particles pseudotyped
with either the wild-type glycoprotein or the cleavage-deficient
mutant, Ebo-GP.CL(). These viral pseudotypes were normalized with
respect to Ebo-GP by Western blot analysis with the anti-Ebo-GP
antiserum and then used to challenge a variety of target cell lines as
described in Materials and Methods.
) glycoprotein than
wild-type Ebo-GP. However, there was no difference in titer between MLV
pseudotyped with either of these two glycoproteins on Vero cells which,
like the BSC-1 cells, are derived from African green monkey kidney. It
seems unlikely that the small difference observed on BSC-1 cells
represents a major effect of processing upon glycoprotein function.
Therefore, it appears that, in contrast to the glycoproteins of the
oncoretroviruses, to which the Ebola virus glycoproteins bear a
striking homology, endoproteolytic processing of Ebo-GP is not required
for glycoprotein function; this suggests a more subtle reason for the
conservation of this dibasic endoproteolytic processing site in the
Ebola virus glycoproteins.
|
| |
DISCUSSION |
|---|
|
Top
Abstract
Introduction
Materials and methods
Results
Discussion
References
|
|---|
In this study, we demonstrated that Ebo-GP is endoproteolytically processed during maturation into two subunits that we have designated GP1 and GP2, thus confirming other recently described results (46). It is the smaller, membrane-anchored subunit, GP2, which is homologous to the TM glycoproteins of the oncoretroviruses and contains many of the putative structures believed to be important for glycoprotein-mediated membrane fusion. When the epitope-tagged form Ebo-T was pseudotyped into MLV particles, we observed that the cleaved form of the glycoprotein was preferentially incorporated into the virions. The peripheral GP1 subunit could be specifically stripped from these pseudotyped particles by treatment with the reducing agent DTT but not with the denaturant urea, indicating that the two subunits are likely disulfide linked. Furthermore, mutational analysis of this glycoprotein identified a dibasic motif, conserved in all membrane-anchored filoviral glycoproteins, as the Ebo-GP endoproteolytic cleavage site.
Furin is a proprotein convertase that has been implicated in the endoproteolytic processing of numerous cellular proteins (39) as well as the proteolytic activation of many viral glycoproteins, including HA of certain strains of influenza A virus (19, 40) and the prM glycoprotein of tick-borne encephalitis virus (38). Furin is expressed in a wide variety of cell types and cleaves proteins after dibasic motifs of the general consensus Arg-X-Lys/Arg-Arg (20). To determine whether furin was required for the processing of Ebo-GP, we analyzed Ebo-T expression in the furin-deficient LoVo cell line. We found that the processing of Ebo-T, although incomplete, was still observed in these cells, indicating that other endoproteases that may be present in the LoVo cells, such as PC2 or PACE4 (39), are competent to cleave the Ebo-GP. Contrary to our results, Volchkov and others (46) have recently reported that Ebo-GP is not cleaved in LoVo cells, leading them to hypothesize that furin is required for the endoproteolytic processing of this glycoprotein. The presence of an epitope tag at the carboxyl terminus of Ebo-T provides us with an extremely powerful assay with which to detect Ebo-GP processing, and it is likely the lack of such a sensitive assay that is the cause for the discrepancy between our results. Moreover, the hypothesis that furin is not required for Ebo-GP processing is strengthened by the fact that the Ebo-GP cleavage mutants Ebo-GP.CL-1, Ebo-GP.CL-2, and Ebo-GP.CL-3, in which the consensus furin recognition site has been disrupted, are still processed, albeit less efficiently than the wild type. Indeed, in the Ebo-GP.CL-3 mutant, only one arginine residue remains at the cleavage site.
Our result demonstrating processing in LoVo cells is not entirely surprising, as it has been shown that the HIV-1 glycoprotein, which is also processed at a consensus furin-like protease recognition motif, is efficiently cleaved in the absence of furin (7, 16, 22, 30). These data strongly suggest that Ebo-GP may be cleaved by a variety of proprotein convertases in different cell types and not by furin alone. Moreover, Ebo-GP was cleaved even when the dibasic motif was replaced with a consensus chymotrypsin protease recognition motif (Ebo-GP.CL-7), suggesting that the cleavage site of this glycoprotein may be highly exposed in the native structure and thus accessible to a great number of different proteases.
Endoproteolytic processing is a requirement for the fusogenic activity
of many viral glycoproteins, including the HIV-1 envelope glycoprotein,
the MLV envelope glycoprotein, and the influenza A virus HA (11,
24, 25, 27). Site-directed mutagenesis of both the HIV-1 and ASLV
glycoprotein cleavage sites has shown that in the absence of
processing, these glycoproteins are unable to mediate viral entry
(8, 10, 17, 32). Similarly, many apathogenic strains of
influenza A virus are restricted to replicating in the cells of the
respiratory tract due to the localized expression of proteases capable
of cleaving the HA glycoprotein (39). Acquisition of a
furin-like endoprotease recognition site in the HA of these viruses,
and the consequent expanded cellular tropism, is a pivotal determinant
of the increased pathogenesis of virulent influenza A virus strains
(3, 4, 39). It was therefore surprising, especially in view
of the close relationship between the Ebola virus and retrovirus TM
sequences, to discover that the uncleaved Ebo-GP mutant, Ebo-GP.CL()
was able to mediate viral entry into a variety of cell types as
efficiently as the wild-type glycoprotein, indicating that, unlike most
other cleaved viral glycoproteins, endoproteolytic processing is not
required for Ebo-GP function. A recent report suggests that the
coronavirus mouse hepatitis virus (MHV) A59 does not require
glycoprotein cleavage either in vivo or in vitro (2, 18). In
contrast to the filoviruses, however, many coronavirus glycoproteins
have no obvious conserved cleavage site and are not generally found as
cleaved proteins, and thus the relevance of this result with MHV A59
for Ebola virus is unclear.
The lack of a requirement for endoproteolytic processing is puzzling,
since the dibasic motif is highly conserved in the envelope glycoproteins of all known strains of Ebola virus and the closely related Marburg virus (1, 46). It is possible that
processing of Ebo-GP is required for viral replication only in certain
cell types. The Sindbis virus E2 glycoprotein is normally
endoproteolytically processed during maturation (26).
However, cleavage is required only for viral growth in invertebrate
cells, while the virus retains the ability to grow in the cells of
vertebrates, albeit with significantly reduced efficiency
(33). A similar situation may exist for Ebola virus, where
glycoprotein processing may be important for the infection of certain
species or tissue types. However, our preliminary survey of eight cell
lines of different tissues and species revealed only a modest 3- to
10-fold reduction in one cell line. The absolute conservation of this
dibasic cleavage site in all filoviruses might suggest that
endoproteolytic processing of Ebo-GP is critical for some stage of the
viral life cycle. We may discover that glycoprotein processing is
important for Ebola virus replication in the species that is the
natural reservoir for this virus. If this is the case, and
endoproteolytic processing of Ebo-GP is required only for the infection
of certain cell types, then the analysis of the ability of MLV(Ebo-GP)
and MLV(Ebo-GP.CL()) to infect a very wide selection of different
cell types from diverse species might provide important clues for the
identification of the elusive Ebola virus reservoir.
Another possible explanation for the highly conserved cleavage site is that cleavage confers an advantage to Ebo-GP-mediated viral entry that cannot be resolved in our one-step infection assay. Over many rounds of viral replication during an infection in vivo, a small advantage might provide the selective pressure required for retention of this motif. It has been shown for MHV A59 that although cleavage is not required for viral infectivity, the uncleaved glycoprotein mediates cell-to-cell fusion with delayed kinetics (1a, 15). Similarly, while proteolytic processing of the Sindbis virus E2 glycoprotein is not required for viral infectivity, virions containing mutations that abrogate E2 processing are avirulent in vivo and produce small plaques in vitro (34). Techniques for reverse genetics are not available for filoviruses but do exist for the closely related rhabdoviruses (28). When such techniques become available for the filoviruses, it will be of great interest to determine whether viruses containing an uncleavable form of Ebo-GP can replicate in vitro and if such viruses are pathogenic in animal models. A recent report described the use of peptides to inhibit the endoproteolytic processing of Ebo-GP (46). If, as with Sindbis virus, proteolytic processing of the glycoprotein is important in pathogenesis, then the administration of such peptides might represent a novel approach to treating individuals infected with this deadly virus.
| |
ACKNOWLEDGMENTS |
|---|
We thank Gary Thomas (Vollum Institute, Portland, Oreg.) for the human furin expression plasmid, George Prendergast for the LoVo cell line, and Bernie Moss (National Institutes of Health) for vaccinia virus vTF-7. We thank John Balliet for critical reading of the manuscript and other members of the Bates laboratory for useful discussions.
This work was supported by grant CA63531 to P.B. from the National Institutes of Health.
| |
FOOTNOTES |
|---|
* Corresponding author. Mailing address: Department of Microbiology, School of Medicine, University of Pennsylvania, 202B Johnson Pavilion, 3610 Hamilton Walk, Philadelphia, PA 19104-6076. Phone: (215) 573-3509. Fax: (215) 898-9557. E-mail: pbates{at}mail.med.upenn.edu.
| |
REFERENCES |
|---|
|
Top
Abstract
Introduction
Materials and methods
Results
Discussion
References
|
|---|
| 1. | Bates, P. Unpublished observations. |
| 1a. | Bos, E. C., L. Heijnen, W. Luytjes, and W. J. Spaan. 1995. Mutational analysis of the murine coronavirus spike protein: effect on cell-to-cell fusion. Virology 214:453-463[Medline]. |
| 2. | Bos, E. C., W. Luytjes, and W. J. Spaan. 1997. The function of the spike protein of mouse hepatitis virus strain A59 can be studied on virus-like particles: cleavage is not required for infectivity. J. Virol. 71:9427-9433[Abstract]. |
| 3. | Bosch, F. X., W. Garten, H. D. Klenk, and R. Rott. 1981. Proteolytic cleavage of influenza virus hemagglutinins: primary structure of the connecting peptide between HA1 and HA2 determines proteolytic cleavability and pathogenicity of avian influenza viruses. Virology 113:725-735[Medline]. |
| 4. | Bosch, F. X., M. Orlich, H. D. Klenk, and R. Rott. 1979. The structure of the hemagglutinin, a determinant for the pathogenicity of influenza viruses. Virology 95:197-207[Medline]. |
| 5. | Bukreyev, A., V. E. Volchkov, V. M. Blinov, and S. V. Netesov. 1993. The GP-protein of Marburg virus contains the region similar to the `immunosuppressive domain' of oncogenic retrovirus P15E proteins. FEBS Lett. 323:183-187[Medline]. |
| 6. |
Damico, R. L.,
J. Crane, and P. Bates.
1998.
Receptor-triggered membrane association of a model retroviral glycoprotein.
Proc. Natl. Acad. Sci. USA
95:2580-2585 |
| 7. |
Decroly, E.,
M. Vandenbranden,
J. M. Ruysschaert,
J. Cogniaux,
G. S. Jacob,
S. C. Howard,
G. Marshall,
A. Kompelli,
A. Basak,
F. Jean, et al.
1994.
The convertases furin and PC1 can both cleave the human immunodeficiency virus (HIV)-1 envelope glycoprotein gp160 into gp120 (HIV-1 SU) and gp41 (HIV-I TM).
J. Biol. Chem.
269:12240-12247 |
| 8. |
Dong, J. Y.,
J. W. Dubay,
L. G. Perez, and E. Hunter.
1992.
Mutations within the proteolytic cleavage site of the Rous sarcoma virus glycoprotein define a requirement for dibasic residues for intracellular cleavage.
J. Virol.
66:865-874 |
| 9. | Elliott, L. H., M. P. Kiley, and J. B. McCormick. 1985. Descriptive analysis of Ebola virus proteins. Virology 147:169-176[Medline]. |
| 10. |
Freed, E. O.,
D. J. Myers, and R. Risser.
1989.
Mutational analysis of the cleavage sequence of the human immunodeficiency virus type 1 envelope glycoprotein precursor gp160.
J. Virol.
63:4670-4675 |
| 11. |
Freed, E. O., and R. Risser.
1987.
The role of envelope glycoprotein processing in murine leukemia virus infection.
J. Virol.
61:2852-2856 |
| 12. | Gallaher, W. R., J. M. Ball, R. F. Garry, M. C. Griffin, and R. C. Montelaro. 1989. A general model for the transmembrane proteins of HIV and other retroviruses. AIDS Res. Hum. Retroviruses 5:431-440[Medline]. |
| 13. |
Gilbert, J. M.,
P. Bates,
H. E. Varmus, and J. M. White.
1994.
The receptor for the subgroup A avian leukosis-sarcoma viruses binds to subgroup A but not to subgroup C envelope glycoprotein.
J. Virol.
68:5623-5628 |
| 14. | Gilbert, J. M., L. D. Hernandez, J. W. Balliet, P. Bates, and J. M. White. 1995. Receptor-induced conformational changes in the subgroup A avian leukosis and sarcoma virus envelope glycoprotein. J. Virol. 69:7410-7415[Abstract]. |
| 15. |
Gombold, J. L.,
S. T. Hingley, and S. R. Weiss.
1993.
Fusion-defective mutants of mouse hepatitis virus A59 contain a mutation in the spike protein cleavage signal.
J. Virol.
67:4504-4512 |
| 16. | Gu, M., J. Rappaport, and S. H. Leppla. 1995. Furin is important but not essential for the proteolytic maturation of gp160 of HIV-1. FEBS Lett. 365:95-97[Medline]. |
| 17. | Guo, H. G., F. M. Veronese, E. Tschachler, R. Pal, V. S. Kalyanaraman, R. C. Gallo, and M. S. Reitz, Jr. 1990. Characterization of an HIV-1 point mutant blocked in envelope glycoprotein cleavage. Virology 174:217-224[Medline]. |
| 18. |
Hingley, S. T.,
I. Leparc-Goffart, and S. R. Weiss.
1998.
The spike protein of murine coronavirus mouse hepatitis virus strain A59 is not cleaved in primary glial cells and primary hepatocytes.
J. Virol.
72:1606-1609 |
| 19. |
Horimoto, T.,
K. Nakayama,
S. P. Smeekens, and Y. Kawaoka.
1994.
Proprotein-processing endoproteases PC6 and furin both activate hemagglutinin of virulent avian influenza viruses.
J. Virol.
68:6074-6078 |
| 20. |
Hosaka, M.,
M. Nagahama,
W. S. Kim,
T. Watanabe,
K. Hatsuzawa,
J. Ikemizu,
K. Murakami, and K. Nakayama.
1991.
Arg-X-Lys/Arg-Arg motif as a signal for precursor cleavage catalyzed by furin within the constitutive secretory pathway.
J. Biol. Chem.
266:12127-12130 |
| 21. |
Hunter, E.,
E. Hill,
M. Hardwick,
A. Bhown,
D. E. Schwartz, and R. Tizard.
1983.
Complete sequence of the Rous sarcoma virus env gene: identification of structural and functional regions of its product.
J. Virol.
46:920-936 |
| 22. |
Inocencio, N. M.,
J. F. Sucic,
J. M. Moehring,
M. J. Spence, and T. J. Moehring.
1997.
Endoprotease activities other than furin and PACE4 with a role in processing of HIV-I gp160 glycoproteins in CHO-K1 cells.
J. Biol. Chem.
272:1344-1348 |
| 23. |
Kawaoka, Y., and R. G. Webster.
1988.
Sequence requirements for cleavage activation of influenza virus hemagglutinin expressed in mammalian cells.
Proc. Natl. Acad. Sci. USA
85:324-328 |
| 24. | Klenk, H. D., R. Rott, M. Orlich, and J. Blodorn. 1975. Activation of influenza A viruses by trypsin treatment. Virology 68:426-439[Medline]. |
| 25. | Lazarowitz, S. G., and P. W. Choppin. 1975. Enhancement of the infectivity of influenza A and B viruses by proteolytic cleavage of the hemagglutinin polypeptide. Virology 68:440-454[Medline]. |
| 26. | Mayne, J. T., C. M. Rice, E. G. Strauss, M. W. Hunkapiller, and J. H. Strauss. 1984. Biochemical studies of the maturation of the small Sindbis virus glycoprotein E3. Virology 134:338-357[Medline]. |
| 27. | McCune, J. M., L. B. Rabin, M. B. Feinberg, M. Lieberman, J. C. Kosek, G. R. Reyes, and I. L. Weissman. 1988. Endoproteolytic cleavage of gp160 is required for the activation of human immunodeficiency virus. Cell 53:55-67[Medline]. |
| 28. |
Mebatsion, T.,
M. J. Schnell,
J. H. Cox,
S. Finke, and K. K. Conzelmann.
1996.
Highly stable expression of a foreign gene from rabies virus vectors.
Proc. Natl. Acad. Sci. USA
93:7310-4731 |
| 29. | Nagai, Y., H. Ogura, and H. Klenk. 1976. Studies on the assembly of the envelope of Newcastle disease virus. Virology 69:523-538[Medline]. |
| 30. |
Ohnishi, Y.,
T. Shioda,
K. Nakayama,
S. Iwata,
B. Gotoh,
M. Hamaguchi, and Y. Nagai.
1994.
A furin-defective cell line is able to process correctly the gp160 of human immunodeficiency virus type 1.
J. Virol.
68:4075-4079 |
| 31. |
Ortmann, D.,
M. Ohuchi,
H. Angliker,
E. Shaw,
W. Garten, and H. D. Klenk.
1994.
Proteolytic cleavage of wild type and mutants of the F protein of human parainfluenza virus type 3 by two subtilisin-like endoproteases, furin and Kex2.
J. Virol.
68:2772-2776 |
| 32. |
Perez, L. G., and E. Hunter.
1987.
Mutations within the proteolytic cleavage site of the Rous sarcoma virus glycoprotein that block processing to gp85 and gp37.
J. Virol.
61:1609-1614 |
| 33. |
Presley, J. F.,
J. M. Polo,
R. E. Johnston, and D. T. Brown.
1991.
Proteolytic processing of the Sindbis virus membrane protein precursor PE2 is nonessential for growth in vertebrate cells but is required for efficient growth in invertebrate cells.
J. Virol.
65:1905-1909 |
| 34. |
Russell, D. L.,
J. M. Dalrymple, and R. E. Johnston.
1989.
Sindbis virus mutations which coordinately affect glycoprotein processing, penetration, and virulence in mice.
J. Virol.
63:1619-1629 |
| 35. |
Samson, A. C., and C. F. Fox.
1973.
Precursor protein for Newcastle disease virus.
J. Virol.
12:579-587 |
| 36. | Sanchez, A., M. P. Kiley, B. P. Holloway, and D. D. Auperin. 1993. Sequence analysis of the Ebola virus genome: organization, genetic elements, and comparison with the genome of Marburg virus. Virus Res. 29:215-240[Medline]. |
| 37. |
Soneoka, Y.,
P. M. Cannon,
E. E. Ramsdale,
J. C. Griffiths,
G. Romano,
S. M. Kingsman, and A. J. Kingsman.
1995.
A transient three-plasmid expression system for the production of high titer retroviral vectors.
Nucleic Acids Res.
23:628-633 |
| 38. | 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]. |
| 39. |
Steiner, D. F.,
S. P. Smeekens,
S. Ohagi, and S. J. Chan.
1992.
The new enzymology of precursor processing endoproteases.
J. Biol. Chem.
267:23435-23438 |
| 40. | Stieneke-Grober, A., M. Vey, H. Angliker, E. Shaw, G. Thomas, C. Roberts, H. D. Klenk, and W. Garten. 1992. Influenza virus hemagglutinin with multibasic cleavage site is activated by furin, a subtilisin-like endoprotease. EMBO J. 11:2407-2414[Medline]. |
| 41. |
Takada, A.,
C. Robison,
H. Goto,
A. Sanchez,
K. G. Murti,
M. A. Whitt, and Y. Kawaoka.
1997.
A system for functional analysis of Ebola virus glycoprotein.
Proc. Natl. Acad. Sci. USA
94:14764-14769 |
| 42. | Takahashi, S., K. Kasai, K. Hatsuzawa, N. Kitamura, Y. Misumi, Y. Ikehara, K. Murakami, and K. Nakayama. 1993. A mutation of furin causes the lack of precursor-processing activity in human colon carcinoma LoVo cells. Biochem. Biophys. Res. Commun. 195:1019-1026[Medline]. |
| 43. |
Takahashi, S.,
T. Nakagawa,
K. Kasai,
T. Banno,
S. J. Duguay,
W. J. Van de Ven,
K. Murakami, and K. Nakayama.
1995.
A second mutant allele of furin in the processing-incompetent cell line, LoVo. Evidence for involvement of the homo B domain in autocatalytic activation.
J. Biol. Chem.
270:26565-26569 |
| 44. | Volchkov, V. E., S. Becker, V. A. Volchkova, V. A. Ternovoj, A. N. Kotov, S. V. Netesov, and H. D. Klenk. 1995. GP mRNA of Ebola virus is edited by the Ebola virus polymerase and by T7 and vaccinia virus polymerases. Virology 214:421-430[Medline]. |
| 45. | Volchkov, V. E., V. M. Blinov, and S. V. Netesov. 1992. The envelope glycoprotein of Ebola virus contains an immunosuppressive-like domain similar to oncogenic retroviruses. FEBS Lett. 305:181-184[Medline]. |
| 46. |
Volchkov, V. E.,
H. Feldmann,
V. A. Volchkova, and H. D. Klenk.
1998.
Processing the Ebola virus glycoprotein by the proprotein convertase furin.
Proc. Natl. Acad. Sci. USA
95:5762-5767 |
| 47. | Webster, R. G., and R. Rott. 1987. Influenza virus A pathogenicity: the pivotal role of hemagglutinin. Cell 50:665-666[Medline]. |
| 48. |
Wool-Lewis, R. J., and P. Bates.
1998.
Characterization of Ebola virus entry by using pseudotyped viruses: identification of receptor-deficient cell lines.
J. Virol.
72:3155-3160 |
Journal of Virology, February 1999, p. 1419-1426, Vol. 73, No. 2
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Dube, D., Brecher, M. B., Delos, S. E., Rose, S. C., Park, E. W., Schornberg, K. L., Kuhn, J. H., White, J. M.
(2009). The Primed Ebolavirus Glycoprotein (19-Kilodalton GP1,2): Sequence and Residues Critical for Host Cell Binding. J. Virol.
83: 2883-2891
[Abstract] [Full Text] -
Kaletsky, R. L., Francica, J. R., Agrawal-Gamse, C., Bates, P.
(2009). Tetherin-mediated restriction of filovirus budding is antagonized by the Ebola glycoprotein. Proc. Natl. Acad. Sci. USA
106: 2886-2891
[Abstract] [Full Text] -
Brindley, M. A., Hughes, L., Ruiz, A., McCray, P. B. Jr., Sanchez, A., Sanders, D. A., Maury, W.
(2007). Ebola Virus Glycoprotein 1: Identification of Residues Important for Binding and Postbinding Events. J. Virol.
81: 7702-7709
[Abstract] [Full Text] -
Clemente, R., de la Torre, J. C.
(2007). Cell-to-Cell Spread of Borna Disease Virus Proceeds in the Absence of the Virus Primary Receptor and Furin-Mediated Processing of the Virus Surface Glycoprotein. J. Virol.
81: 5968-5977
[Abstract] [Full Text] -
Neumann, G., Geisbert, T. W., Ebihara, H., Geisbert, J. B., Daddario-DiCaprio, K. M., Feldmann, H., Kawaoka, Y.
(2007). Proteolytic Processing of the Ebola Virus Glycoprotein Is Not Critical for Ebola Virus Replication in Nonhuman Primates. J. Virol.
81: 2995-2998
[Abstract] [Full Text] -
Marzi, A., Akhavan, A., Simmons, G., Gramberg, T., Hofmann, H., Bates, P., Lingappa, V. R., Pohlmann, S.
(2006). The Signal Peptide of the Ebolavirus Glycoprotein Influences Interaction with the Cellular Lectins DC-SIGN and DC-SIGNR.. J. Virol.
80: 6305-6317
[Abstract] [Full Text] -
Schornberg, K., Matsuyama, S., Kabsch, K., Delos, S., Bouton, A., White, J.
(2006). Role of endosomal cathepsins in entry mediated by the ebola virus glycoprotein.. J. Virol.
80: 4174-4178
[Abstract] [Full Text] -
Tscherne, D. M., Jones, C. T., Evans, M. J., Lindenbach, B. D., McKeating, J. A., Rice, C. M.
(2006). Time- and Temperature-Dependent Activation of Hepatitis C Virus for Low-pH-Triggered Entry. J. Virol.
80: 1734-1741
[Abstract] [Full Text] -
Sanchez, A. J., Vincent, M. J., Erickson, B. R., Nichol, S. T.
(2006). Crimean-Congo Hemorrhagic Fever Virus Glycoprotein Precursor Is Cleaved by Furin-Like and SKI-1 Proteases To Generate a Novel 38-Kilodalton Glycoprotein. J. Virol.
80: 514-525
[Abstract] [Full Text] -
Netter, R. C., Amberg, S. M., Balliet, J. W., Biscone, M. J., Vermeulen, A., Earp, L. J., White, J. M., Bates, P.
(2004). Heptad Repeat 2-Based Peptides Inhibit Avian Sarcoma and Leukosis Virus Subgroup A Infection and Identify a Fusion Intermediate. J. Virol.
78: 13430-13439
[Abstract] [Full Text] -
Xu, Y., Liu, Y., Lou, Z., Qin, L., Li, X., Bai, Z., Pang, H., Tien, P., Gao, G. F., Rao, Z.
(2004). Structural Basis for Coronavirus-mediated Membrane Fusion: CRYSTAL STRUCTURE OF MOUSE HEPATITIS VIRUS SPIKE PROTEIN FUSION CORE. J. Biol. Chem.
279: 30514-30522
[Abstract] [Full Text] -
Fielding, B. C., Tan, Y.-J., Shuo, S., Tan, T. H. P., Ooi, E.-E., Lim, S. G., Hong, W., Goh, P.-Y.
(2004). Characterization of a Unique Group-Specific Protein (U122) of the Severe Acute Respiratory Syndrome Coronavirus. J. Virol.
78: 7311-7318
[Abstract] [Full Text] -
Simmons, G., Rennekamp, A. J., Chai, N., Vandenberghe, L. H., Riley, J. L., Bates, P.
(2003). Folate Receptor Alpha and Caveolae Are Not Required for Ebola Virus Glycoprotein-Mediated Viral Infection. J. Virol.
77: 13433-13438
[Abstract] [Full Text] -
Elshuber, S., Allison, S. L., Heinz, F. X., Mandl, C. W.
(2003). Cleavage of protein prM is necessary for infection of BHK-21 cells by tick-borne encephalitis virus. J. Gen. Virol.
84: 183-191
[Abstract] [Full Text] -
Aguilar, H. C., Anderson, W. F., Cannon, P. M.
(2002). Cytoplasmic Tail of Moloney Murine Leukemia Virus Envelope Protein Influences the Conformation of the Extracellular Domain: Implications for Mechanism of Action of the R Peptide. J. Virol.
77: 1281-1291
[Abstract] [Full Text] -
Jeffers, S. A., Sanders, D. A., Sanchez, A.
(2002). Covalent Modifications of the Ebola Virus Glycoprotein. J. Virol.
76: 12463-12472
[Abstract] [Full Text] -
Simmons, G., Wool-Lewis, R. J., Baribaud, F., Netter, R. C., Bates, P.
(2002). Ebola Virus Glycoproteins Induce Global Surface Protein Down-Modulation and Loss of Cell Adherence. J. Virol.
76: 2518-2528
[Abstract] [Full Text] -
Neumann, G., Feldmann, H., Watanabe, S., Lukashevich, I., Kawaoka, Y.
(2002). Reverse Genetics Demonstrates that Proteolytic Processing of the Ebola Virus Glycoprotein Is Not Essential for Replication in Cell Culture. J. Virol.
76: 406-410
[Abstract] [Full Text] -
Feldmann, H., Volchkov, V. E., Volchkova, V. A., Stroher, U., Klenk, H.-D.
(2001). Biosynthesis and role of filoviral glycoproteins. J. Gen. Virol.
82: 2839-2848
[Full Text] -
Jasenosky, L. D., Neumann, G., Lukashevich, I., Kawaoka, Y.
(2001). Ebola Virus VP40-Induced Particle Formation and Association with the Lipid Bilayer. J. Virol.
75: 5205-5214
[Abstract] [Full Text] -
Takada, A., Watanabe, S., Okazaki, K., Kida, H., Kawaoka, Y.
(2001). Infectivity-Enhancing Antibodies to Ebola Virus Glycoprotein. J. Virol.
75: 2324-2330
[Abstract] [Full Text] -
Ito, H., Watanabe, S., Takada, A., Kawaoka, Y.
(2001). Ebola Virus Glycoprotein: Proteolytic Processing, Acylation, Cell Tropism, and Detection of Neutralizing Antibodies. J. Virol.
75: 1576-1580
[Abstract] [Full Text] -
Harty, R. N., Brown, M. E., Wang, G., Huibregtse, J., Hayes, F. P.
(2000). A PPxY motif within the VP40 protein of Ebola virus interacts physically and functionally with a ubiquitin ligase: Implications for filovirus budding. Proc. Natl. Acad. Sci. USA
10.1073/pnas.250277297v1
[Abstract] [Full Text] -
Delos, S. E., Gilbert, J. M., White, J. M.
(2000). The Central Proline of an Internal Viral Fusion Peptide Serves Two Important Roles. J. Virol.
74: 1686-1693
[Abstract] [Full Text] -
Harty, R. N., Brown, M. E., Wang, G., Huibregtse, J., Hayes, F. P.
(2000). A PPxY motif within the VP40 protein of Ebola virus interacts physically and functionally with a ubiquitin ligase: Implications for filovirus budding. Proc. Natl. Acad. Sci. USA
97: 13871-13876
[Abstract] [Full Text]
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Copyright © 2009 by the American Society for Microbiology. For an alternate route to Journals.ASM.org, visit: http://intl-journals.asm.org | More Info»