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Journal of Virology, November 1998, p. 8988-9001, Vol. 72, No. 11
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
African Swine Fever Virus Is Enveloped by a
Two-Membraned Collapsed Cisterna Derived from the Endoplasmic
Reticulum
Germán
Andrés,
Ramón
García-Escudero,
Carmen
Simón-Mateo, and
Eladio
Viñuela*
Centro de Biología Molecular
"Severo Ochoa" (Consejo Superior de Investigaciones
Científicas-Universidad Autónoma de Madrid), Facultad de
Ciencias, Universidad Autónoma de Madrid, Cantoblanco,
28049 Madrid, Spain
Received 22 May 1998/Accepted 30 July 1998
 |
ABSTRACT |
During the cytoplasmic maturation of African swine fever virus
(ASFV) within the viral factories, the DNA-containing core becomes wrapped by two shells, an inner lipid envelope and an outer
icosahedral capsid. We have previously shown that the inner envelope is
derived from precursor membrane-like structures on which the capsid
layer is progressively assembled. In the present work, we analyzed the
origin of these viral membranes and the mechanism of
envelopment of ASFV. Electron microscopy studies on permeabilized
infected cells revealed the presence of two tightly apposed membranes
within the precursor membranous structures as well as polyhedral
assembling particles. Both membranes could be detached after digestion
of intracellular virions with proteinase K. Importantly, membrane loop
structures were observed at the ends of open intermediates, which
suggests that the inner envelope is derived from a membrane cisterna.
Ultraestructural and immunocytochemical analyses showed a close
association and even direct continuities between the endoplasmic
reticulum (ER) and assembling virus particles at the bordering areas of
the viral factories. Such interactions become evident with an ASFV
recombinant that inducibly expresses the major capsid protein p72. In
the absence of the inducer, viral morphogenesis was arrested at a stage
at which partially and fully collapsed ER cisternae enwrapped the core
material. Together, these results indicate that ASFV, like the
poxviruses, becomes engulfed by a two-membraned collapsed cisterna
derived from the ER.
| |
INTRODUCTION |
African swine fever virus (ASFV) is
a complex enveloped deoxyvirus with unique features among the
DNA-containing viruses (9, 44). Large DNA viruses include
families of icosahedral viruses (Herpesviridae and
Iridoviridae) and brick-shaped viruses
(Poxviridae). ASFV does not fit well into any of these
groups because, although its genome structure is similar to that of
poxviruses (17, 39), its icosahedral structure is like that
of iridoviruses (2, 7). So far, ASFV is the only member of
an unnamed family of animal DNA viruses (12). The viral
genome is a single molecule of double-stranded DNA that, in the case of
the avirulent strain BA71V, comprises about 150 open reading frames
(45). The viral particle contains more than 30 different
polypeptides (6) and, in spite of being an enveloped
virus, lacks major glycoproteins (11). At least six of the
major ASFV structural proteins (p150, p37, p35, p34, p15, and p14) are
synthesized as polyprotein precursors (pp220 and pp62), which is an
unusual feature in a DNA virus (36, 37).
The virus particle possesses a complex structure formed by several
concentric domains with an overall icosahedral shape and a diameter of
about 200 nm (7). The viral core is composed of a
DNA-containing nucleoid enclosed by a thick protein layer, the core
shell, which contains the mature products derived from polyprotein
pp220 (3). The core is successively surrounded by a
inner lipid envelope, a capsid formed by protein subunits arranged in a
hexagonal lattice, and, finally, an outer lipid envelope acquired by
budding at the cell surface (3, 4, 7). ASFV morphogenesis
takes place in discrete cytoplasmic areas, the viral factories, where
the replication of the viral DNA also occurs (3-5, 14, 23).
These areas contain abundant membrane-like structures, which represent
the first morphological evidence of virus assembly. Viral membranes
engulf the core material while acquiring a polyhedral shape by the
assembly of the outer capsid layer (3). To facilite the
study of ASFV assembly, we have recently developed a system for
inducible gene expression from ASFV recombinants (15). Using
this approach, we showed that the formation of the capsid on the
inner envelope is a progressive process depending on expression
of protein p72, the major component of the capsid.
In the present study, we have focused our attention to the origin and
the mechanism of acquisition of the inner viral envelope. In
general, enveloped viruses acquire their membranes from specific host
cell compartments where certain viral membrane proteins are targeted
(19, 26, 40). Envelopment usually takes place through a
budding process whereby the virus particle is wrapped by a single membrane and leaves its original compartment. However, a striking exception has arisen in recent studies on the assembly of two large
DNA-containing viruses, the poxviruses and the herpesviruses. For both
of these classes, it has been shown that the viruses become enwrapped
by cellular membrane cisternae, thus acquiring two lipid
membranes in a single step (16, 29, 33, 38, 43). With
regard to ASFV, a recent report by Cobbold et al. (8)
has suggested that ASFV is enveloped by the endoplasmic reticulum (ER).
Such a proposal was based on indirect data such as the comigration in
sucrose gradients of viral protein p72 with the luminal ER marker
protein disulfide isomerase (PDI) and on the apparent colocalization of
PDI with the viral factories in immunofluorescence experiments.
In the present work, we provide morphological and immunocytochemical
evidence showing that the ASFV inner envelope is indeed composed of two
juxtaposed membranes derived from an ER cisterna. A new model for the
structure and assembly pathway of ASFV is therefore presented.
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MATERIALS AND METHODS |
Cells and viruses.
Vero cells (ATCC CCL81) were cultured in
Dulbecco's modified Eagle's medium supplemented with 10% newborn
calf serum, which was reduced to 2% during viral infection. The ASFV
strain BA71V, adapted to grow in Vero cells, has been described
previously (13). Highly purified extracellular ASFV was
obtained by Percoll equilibrium centrifugation (6). The
recombinant virus vA72, which inducibly expresses the major capsid
protein p72 (15), was propagated in the presence of 2 mM
isopropyl-
-D-thiogalactopyranoside (IPTG). Infections
with parental BA71V and recombinant vA72 viruses were carried out at a
multiplicity of infection of 10 PFU/cell.
Antibodies.
Rabbit polyclonal serum and mouse monoclonal
antibody (MAb) 24A.G4 against the ASFV proteins pp220/p150 have been
described previously (32, 36). Rabbit antiserum against PDI
was kindly provided by J. G. Castaño (Instituto de
Investigaciones Biomédicas, Madrid, Spain) (24). Mouse
MAb and rabbit serum against ER membrane protein p63 were obtained from
A. Schweizer and J. Rohrer (Biocenter, Basel, Switzerland)
(35). Rabbit serum against membrane ER glycoproteins (anti-MERG) was a gift from D. I. Meyer (University of California, Los Angeles, Calif.) (27). Rabbit antiserum against
galactosyltransferase was a gift from Eric Berger (Physiologisches
Institut, Zurich, Switzerland) (30). Mouse MAb against
membrane protein p53 was kindly provided by H.-P. Hauri (Biocenter,
Basel, Switzerland) (34). MAb 25H8 against the
cis-Golgi network membrane protein gp74 (1) and
rabbit serum to the cis-medial-Golgi protein gp100 (46) were kindly provided by I. Sandoval (Centro de
Biología Molecular "Severo Ochoa," Madrid, Spain). Mouse
MAb 1D3 against PDI was obtained from Stressgene Biotechnologies Corp.
(Victoria, British Columbia, Canada) (42), and rabbit serum
against cathepsin L was obtained from BioAss (Diessen, Germany).
Light microscopy.
Vero cells were grown to ca. 70%
confluency in chamber slides (Lab-Tek, Nunc) and then infected at 1 PFU
per cell with ASFV BA71V. For immunofluorescence labeling, the cells
were fixed after the indicated times with methanol at 
20°C for 5 min. For staining of the trans-Golgi network, the cells were
fixed with 3% paraformaldehyde for 15 min at room temperature and
incubated with C6-NBD-ceramide (Molecular Probes Inc.,
Eugene, Oreg.) as previously described (25). Double-labeling
experiments were performed by incubating together the two primary
antibodies and, subsequently, the two secondary antibodies at 37°C
for 1 h. As a control, each antibody was tested individually. The
secondary antibodies Texas red-linked donkey anti-rabbit, Texas
red-linked sheep anti-mouse, and fluoresceinated donkey anti-rabbit
antibodies were obtained from Amersham Life Science. The
fluoresceinated goat anti-mouse immunoglobulin G was obtained from Tago
Inc. (Burlingame, Calif.). The coverslips were mounted on glass slides
with Moviol, examined with an Axiovert fluorescence microscope (Carl
Zeiss, Inc., Oberkochen, Germany), and photographed with Kodak film
(TMAX; ASA 400).
Electron microscopy (EM).
For conventional Epon section
analysis, ASFV-infected Vero cells were fixed with 2%
glutaraldehyde-2% tannic acid in 200 mM cacodylate buffer (pH 7.4) at
room temperature for 1 h. Postfixation was carried out with 1%
OsO4 and 1.5% K3Fe(CN)6 in
cacodylate buffer at 4°C for 30 min. After extensive washing with
distilled water, the samples were dehydrated and embedded in Epon.
Infected cells were permeabilized with the bacterial toxin streptolysin
O (SLO) as described by Sodeik et al. (38) with minor
modifications. Briefly, infected Vero cell monolayers were incubated on
ice with 8 U of SLO (Sigma) per ml for 15 min. After extensive washing,
the cells were incubated at 37°C for 30 min to allow pore formation
and then processed for Epon embedding.
For both cryosectioning and freeze-substitution, the infected cells
were fixed on the culture dish with 8 or 4% formaldehyde
and 0.1%
glutaraldehyde in 200 mM HEPES (pH 7.2) for 1 h at room
temperature. After fixation, the cells were carefully scraped
with a
rubber policeman and centrifuged at 1,500 ×
g for 3 min.
The cell pellets were embedded in 10% gelatin from cold water
fish skin (Sigma), cut into 1-mm
3 pieces, and then infused
with a mixture containing 10% polyvinylpyrrolidone
(10 kDa; Sigma) and
2.07 M sucrose. Sample blocks were frozen
and stored in liquid nitrogen
before use.
Ultrathin cryosections were obtained at around
110°C with a
Reichert-Jung Ultracut E apparatus (Leica, Vienna, Austria) equipped
with a 35° diamond knife and an antistatic device (Diatome, Biel,
Switzerland). Section retrieval was performed by the method of
Liou et
al. (
21). For this, the sections were picked up with
a
mixture of 2% aqueous methylcellulose (25 cP; Sigma) and 2.3
M sucrose
in 1:1 proportion. After being thawed, the sections
were transferred
onto carbon-coated Formvar films on copper grids.
Immunolabeling,
drying, and contrasting of the sections were performed
as described by
Griffiths (
18).
Freeze-substitution was carried out with Leica AFS system KF80. Sample
blocks were incubated at
90°C for 40 h in methanol
supplemented with 0.5% tannic acid. Dehydration was continued
with
pure methanol by raising the temperature to
35°C at a rate
of
3°C/h. Finally, the samples were embedded in Lowicryl K4M at
35°C
and polymerized by irradiation with UV light. Immunogold
labeling of
freeze-substituted samples was performed essentially
as described
previously (
3). The PDI labeling with MAb 1D3
was amplified
with a rabbit anti-mouse immunoglobulin G (Dako,
Copenhagen, Denmark)
followed by protein A-gold complexes (diameter,
15 nm; BioCell Research
Laboratories, Cardiff, United Kingdom).
For the double-labeling
experiment, the sections were sequentially
incubated with the serum to
pp220/p150 followed by protein A-gold
(diameter, 10 nm) and with the
anti-PDI MAb followed by protein
A-gold (diameter, 15 nm). Between the
two steps, the sections
were fixed with 1% glutaraldehyde for 5 min
and then incubated
with 100 mM glycine in phosphate-buffered saline
(PBS) for 5 min.
For negative staining of ASFV, purified virus particles were adsorbed
to glow-discharged, Formvar-coated nickel grids, rinsed
briefly with
PBS, and fixed with 2% glutaraldehyde for 5 min.
Finally, the virions
were negatively stained with 2% phosphotungstic
acid for 5 min.
Detergent and protease treatments of virus particles.
Suspensions of highly purified virions in PBS were incubated with 0.5%
-D-octylglucopyranoside or 0.5% Nonidet P-40 in PBS for
5 min at room temperature. After the treatment, the virus particles
were sedimented in a Beckman Airfuge at 100,000 × g for 5 min, fixed with 2% glutaraldehyde for 1 h, and processed for Epon embedding.
For protease treatment of intracellular virions, infected Vero cells
were perforated at 20 h postinfection (p.i.) by hypotonic
lysis as
previously described (
38). The broken cells were centrifuged
at 1,000 ×
g for 5 min and resuspended for 30 min in
0.25 M sucrose-25
mM HEPES (pH 7.2)-5 mM magnesium acetate-50 mM
potassium acetate
containing 5 mg of proteinase K (Merck, Darmstadt,
Germany) per
ml. Finally, the samples were centrifuged at 3,000 ×
g for 5 min,
rinsed twice with PBS, fixed with 2%
glutaraldehyde for 1 h, and
processed for Epon embedding.
To estimate the size of nontreated or detergent-treated virions, the
measurements were made on micrographs of particles showing
hexagonal
outlines in threefold projections. The lengths were
estimated from side
to side and expressed as means and standard
deviations. The mean
diameter of the proteinase-treated particles
was calculated by using
particles with an apparently intact core
containing a nucleoid of about
80 nm. The measurements were typically
performed on magnifications of
×150,000.
Specimens were examined with a JEOL 1010 or JEOL 1200X electron
microscope.
| |
RESULTS |
The inner envelope of ASFV is a double-membrane domain.
Figure
1A to C show extracellular ASFV particles
processed by three different EM methods: conventional Epon embedding
(Fig. 1A), cryosectioning (Fig. 1B), and negative staining of whole particles (Fig. 1C). All these images show that ASFV consists of a core
surrounded by three concentric shells with an overall icosahedral
shape. However, the nature of these layers can be differently
interpreted depending on the technique used. Thus, all of them look
usually like lipid membranes in both Epon sections and cryosections.
However, the intermediate layer, as visualized by negative staining,
clearly shows the regular array of globular protein units composing the
viral capsid (Fig. 1C). Therefore, we interpret these three layers as
an inner lipid envelope, a protein capsid, and an outer lipid envelope
(Fig. 1A to C). It is well established that the outermost envelope is a
single lipid membrane acquired by budding at the cell surface
(4). The first goal of the present study was to determine
the nature of the innermost envelope.
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FIG. 1.
Structure and assembly of ASFV. (A to C) Extracellular
ASFV particles processed by Epon sectioning (A), cryosectioning (B),
and negative staining (C). All these EM methods reveal an overall
structure consisting of a central core surrounded by three layers: the
inner envelope (ie), the capsid (c), and the outer envelope (oe). Note
that in the negatively stained particle, individual capsomers (small
arrows in panel C) are evident within the capsid. (D to J) Ultrathin
Epon sections of viral intermediates from infected Vero cells
permeabilized at 18 to 24 h p.i. Intracellular ASFV particles
mature from precursor viral membranous structures (pvm) present in the
viral factories (D), which become polyhedral particles by the gradual
formation of the capsid on one of their faces (D and E). The short
arrows in panel E indicate the limits of capsids assembling on the
inner envelopes. Note also the electron-dense core material underneath
the concave side of the inner envelope (E). Close inspection of the
assembly intermediates revealed two distinct membranes within the
precursor membranous structures (arrowheads in panel F) as well as in
polyhedral assembling particles (arrowheads in panels G to J). Note
that the ends of open particles (H to J) appeared as membrane loops,
which suggests that ASFV becomes enwrapped by a collapsed two-membraned
cisterna. Bars, 50 nm.
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|
To obtain a better visualization of the membrane profiles, the infected
cells were usually permeabilized at 18 to 24 h p.i.
with the
bacterial toxin SLO or by hypotonic lysis. Figure
1D
to J show
ultrathin Epon sections of different virus assembly
intermediates
present within the cytoplasmic viral factories.
In agreement with our
previous observations (
3), ASFV particles
were found to
assemble from precursor membrane-like structures
(Fig.
1D), which
became polyhedral particles by the gradual assembly
of the outer
capsid on one of their two faces (Fig.
1E). Concomitantly,
the
electron-dense core material appeared to associate with their
opposite faces (Fig.
1E). Since the inner viral envelope is
derived
directly from the precursor membranous structures and
the entire
assembly process occurs in the viroplasm, cytosolic ambient
ASFV
envelopment cannot be explained by a budding process at a cellular
organelle. We therefore explored the possibility that ASFV becomes
engulfed by a cellular cisterna, thus acquiring two lipid membranes
simultaneously.
Inspection of the precursor membranous forms revealed that despite
their trilaminar appearance, they were markedly different
from the host
cell membranes because of their higher electron
density and thickness
(around 12 nm) and the usual presence of
electron-dense spicules
covering their faces (Fig.
1D). Most importantly,
two tightly apposed
membranes were often detected within these
precursor structures (Fig.
1F). A similar finding was made during
the examination of
assembling polyhedral particles. Occasionally,
the inner envelope
appeared to locally separate into two distinct
lipid bilayers
(Fig.
1G). More frequently, membrane loops were
observed at the
ends of open intermediates (Fig.
1H to J). Together,
these observations
argue that the inner envelope is derived from
a collapsed two-membraned
cisterna.
To further investigate the existence of two lipid membranes within
intracellular particles, we tested the action of proteinase
K on the
viral structure. For this purpose, permeabilized infected
cells
were incubated with the proteinase and then processed for
Epon
embedding. After this treatment, most of the virus particles
present in
the viral factories exhibited pronounced changes in
their icosahedral
morphology. Compared with nontreated intracellular
virions (Fig.
2A), it was evident that the virions
incubated with
the proteinase had lost the outer layer, i.e., the
capsid, but
not the inner envelope (Fig.
2B). Furthermore, the
envelope appeared
partially dissociated into two membrane layers within
highly disrupted
particles (Fig.
2C to E).
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FIG. 2.
Selective disruption of ASFV particles. (A) Epon section
of an intact intracellular particle showing the central core
successively enclosed by the inner envelope (ie) and the outer capsid
(c). (B to E) Epon sections of intracellular virions incubated with
proteinase K. At 20 h p.i. infected Vero cells were perforated by
hypotonic lysis and subsequently incubated with proteinase K for 30 min
at room temperature. After the proteinase treatment, intracellular
particles had lost the capsid but not the inner envelope (B).
Importantly, in highly damaged virions the inner envelope appeared
dissociated in two distinct membranes (arrowheads in panels C to E).
Note also the dramatic alteration of their icosahedral morphology. (F
and G) Epon sections of purified extracellular particles treated for 30 min with the nonionic detergent -D-octylglucopyranoside.
Note the lack of the outer and the inner envelopes and the partial
disruption of the viral core. Note also that the capsid remains
apparently intact and the resulting particles retain their polyhedral
shapes. Bars, 50 nm.
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|
In another approach, purified extracellular virions were incubated with
the nonionic detergent
-
D-octylglucoside (Fig.
2F
and G) or Nonidet P-40 (data not shown). After these
treatments,
the outer and inner lipid envelopes were removed
and the core
structure was partially altered (compare Fig.
2F and G
with Fig.
1A to C and 2A). However, the capsid remained apparently
intact
and the resulting particles retained their polyhedral shape,
which
demonstrates the central role of this outer layer in the virus
symmetry. Additional support for these observations was obtained
by
comparing the sizes of the particles resulting from the different
treatments. Thus, while the average diameter of the proteinase-treated
virions (148 ± 6 nm,
n = 15) was clearly smaller
than that of
nontreated intracellular particles (170 ± 7 nm,
n = 25), the size
of the particles obtained
after the detergent incubation (166
± 7 nm,
n = 15) was not significantly different.
In summary, these findings are in agreement with the lipid nature
of the inner shell and the protein nature of the outer one.
Furthermore, they support the existence of two tightly apposed
membranes within the envelope of the intracellular ASFV
particles,
which is consistent with their being wrapped by a membrane
cisterna.
Relationship of ASFV assembly sites to cellular compartments.
To analyze the origin of the ASFV inner envelope, our first step was to
explore the possible colocalization of a set of well-characterized markers of cell organelles with the viral factories. For this, double-immunofluorescence experiments were performed on infected Vero
cells fixed at 14 to 16 h p.i. The location of viral factories was
determined with specific antibodies to ASFV polyprotein pp220 (32,
36) (Fig. 3B, D, F, and H). The ER
was visualized with a MAb (42) (results not shown) and a
polyclonal serum (24) (Fig. 3A) against the luminal marker
PDI, the membrane protein p63 (35) (results not shown), the
membrane marker of the intermediate compartment p53 (34)
(results not shown), and a purified extract of membrane ER
glycoproteins (anti-MERG [27]) (Fig. 3C). All the tested ER markers were essentially excluded from the
cytoplasmic viral factories. However, it was evident that the ER
labeling closely encompassed the assembly sites (compare Fig. 3A and C with Fig. 3B and D, respectively).
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FIG. 3.
Immunofluorescence analysis of ER and Golgi marker
proteins in ASFV-infected cells. Infected Vero cells were fixed at 12 to 16 h p.i. with methanol at 20°C. Double-labeling
experiments were performed with antibodies to ASFV polyprotein pp220 to
stain the viral factories (B, D, F, and H) and with antibodies to
different ER and Golgi proteins (A, C, E, and G), as follows. For ER
labeling, a rabbit antiserum to the luminal marker PDI (A) and a rabbit
antiserum to membrane ER glycoproteins (C) were used. For Golgi
labeling, a MAb to the membrane glycoprotein gp74 (E) and a rabbit
serum to galactosyltransferase (G) were used. The antibodies to pp220
were a mouse MAb (24A.G4) (B, D, and H) and the rabbit antiserum
anti-pp220/p150 (F). Double labeling was developed with
fluorescein-coupled secondary antibodies for the assembly sites and
Texas red-conjugated antibodies for the organelle markers. Note that
viral factories (arrows) essentially exclude the ER and Golgi markers
but are closely encompassed by them.
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Similar results were obtained with antibodies against the Golgi
membrane proteins gp74 (
1) (Fig.
3E), gp100 (
46)
(results
not shown), and galactosyltransferase (
30) (Fig.
3G). Although
these proteins did not colocalize with polyprotein pp220,
their
presence in the boundaries of the assembly sites was clear
(compare
Fig.
3E and G with Fig.
3F and H, respectively). Finally, no
colocalization
was observed with the markers to the endocytic-lysosomal
pathway,
C
6-NBD-ceramide and cathepsin L (results not
shown). Together,
these results indicate a virtual exclusion of the
host cell organelles
from the assembly sites.
We next examined the relationship between cellular organelles and
viral structures at the EM level. As shown in Fig.
4A, the
viral factories were closely
surrounded by ER cisternae and by
an enlarged Golgi apparatus, thus
confirming the results of the
immunofluorescence experiments and
previous work (
23). This
observation led us to analyze
possible interactions between host
cell membranes and viral structures
at the peripheral areas of
the assembly sites. Such examination
revealed frequent interactions
between ER cisternae and the precursor
viral membranous structures
through viroplasmic electron-dense
material (Fig.
4B). Most important,
however, was the occasional finding
of collapsed ER membranes
in the close vicinity of (Fig.
4C) and even
in direct continuity
with (Fig.
4D) assembling virions. No interactions
were apparent
between viral intermediates and the Golgi complex.
Collectively,
these observations argue that viral membranes are derived
from
ER membranes.
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FIG. 4.
Relationship between viral membranes and ER membranes.
Ultrathin Epon sections of ASFV-infected Vero cells at 24 h p.i.
are shown. (A) Viral factories (VF) were usually encompassed by an
enlarged Golgi complex (G) and ER cisternae (ER). The plasma membrane
(PM) and the nucleus (N) are also indicated. (B to D) At the limits of
the assembly sites, a close association between ER membranes and viral
structures was often evident. (B) Several precursor viral membranes
(pvm, arrows) are present between two cellular cisternae (arrowheads).
Note the presence of electron-dense viroplasmic material associated
with both viral and cellular membranes. (C) An apparently collapsed ER
cisterna (small arrowheads) with attached ribosomes (large arrowheads)
is in close vicinity to precursor viral membranes. (D) Eventually,
direct continuities (arrow) between membranes with attached ribosomes
(arrowheads) and assembling virions were also evident. Bars: 500 nm
(A), 100 nm (B to D).
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ASFV zipper-like structures.
Inspection of the areas
contiguous with the assembly sites revealed the presence of a minor
subpopulation of atypical viral structures (Fig.
5A). These viral forms which we refer to
as zipper-like structures, seemed to consist of two ER cisternae bound
by an extended and electron-dense viral domain structurally similar to
the core shell (see below). To elucidate the unusual structure of these
viral intermediates, two different approaches were undertaken. On the
one hand, we examined the zipper-like structures of infected cells
permeabilized with SLO. By this method, the soluble contents of the
cytosol were extracted but the luminal contents, which were now easily
identifiable, were not extracted (Fig. 5B). Under these conditions, the
core shell appeared unequivocally limited by the luminal spaces of
adjacent ER cisternae, thus confirming the previous interpretation. In
the other aproach, the zipper-like structures were analyzed by using
serial sections. As deduced from Fig. 5C, the viral domain is a laminar
structure whose limiting surfaces are bound to the cytoplasmic sides of
the ER membranes. Together, these finding confirm the interaction of
ASFV structures with ER membranes.
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FIG. 5.
Topology of the zipper-like structures. (A and B)
Ultrathin Epon sections of marginal zipper-like structures within a
nonpermeabilized (A) or SLO-permeabilized (B) infected cell at 16 h p.i. Note in the control (A) how the limits of the viral intermediate
appear to be continuous with two adjacent ER cellular cisternae
(arrowheads). After cell permeation (B), the cytosol (C) is extracted
but not the luminal contents (L), which become obvious. Thus, it is
clear that the core shell is a cytosolic structure limited by two ER
cisternae. (C1 to C3) Set of serial sections of
a peripheral zipper-like structure. The core shell is interpreted as a
laminar structure whose limiting surfaces interact with the cytoplasmic
sides of ER cisternae. Note the presence of ribosomes (small arrows)
attached to ER membranes (arrowheads). Bars: 200 nm (A and B) and 100 nm (C1).
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A closely related type of zipper-like structures was also found within
the viral factories. When comparing the marginal (Fig.
6A and
B) and internal (Fig.
6C to F)
zipper-like structures,
it was evident that, in the latter case, the
core shell was limited
by two typical viral membrane-like structures
(Fig.
6D). Moreover,
a close examination revealed the existence of two
apposed membranes
within each viral envelope, as well as loop
structures at their
ends (Fig.
6E and F). Collectively, these
findings argue again
that viral envelopes are derived from
collapsed ER cisternae.
Eventually, the zipper-like intermediates
became polyhedral structures
(Fig.
6G to K). As with normal ASFV
particles, this process was
found to be a direct consequence of the
progressive assembly of
an outer capsid on one of the limiting
envelopes (Fig.
6G and
H). Thus, the resulting closed icosahedral
particles contained
an extra inner envelope beneath the core shell. In
a minor proportion
of these double-enveloped particles, an
electron-dense material
appeared to be encapsidated to give rise to a
nucleoid-like domain
(Fig.
6I to K).
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FIG. 6.
Assembly of zipper-like structures. Epon sections of
viral zipper-like structures present in the bordering areas of the
assembly sites (A and B) or within them (C to I). (A and B) Outside the
viral factories (VF), these atypical viral intermediates (arrows in
panel A) consist of an extended core shell limited by two membrane
cisternae (arrowheads in panel B). (C to E) Within the viral factories,
closely related zipper-like structures are also found (arrows in panel
C). These intermediates are composed by an extended core shell limited
by two typical membrane-like structures (arrowheads in panel D). When
examined in detail (panels E and F are higher magnifications of the
areas delimited in panel D), two apposed lipid membranes (arrowheads)
can be discerned within each limiting viral envelope. (G to K)
Eventually, the zipper-like structures become polyhedral particles by
the progressive formation of a capsid layer (c) on one of the two
limiting envelopes (ie). Concomitantly, a nucleoprotein-like material
appears to be encapsidated within some double-enveloped particles
(arrowheads in panels I and J). Finally, after membrane fusion events,
the resulting closed particles contain two inner envelopes encompassing
the core shell (K). Note that the core shell is formed by two regular
arrays of protein subunits (arrowheads in panel K) separated by a thin
electron-dense protein layer. Bars: 500 nm (A) and 100 nm (B to K).
|
|
Together, these observations show the existence of an alternative
assembly pathway leading to the formation of a minor and
structurally
distinct class of ASFV particles. It is noteworthy
that the external
layers, and even the core shell, of such particles
seem to be
morphologically identical to the corresponding domains
of normal
virions (
3) (compare Fig.
2A and
6K). Likewise, the
apparent
mechanisms of acquisition of the inner envelope, by wrapping
from ER
cisternae, and of the outer capsid, by a gradual building
process, are
also consistent with the assembly model described
for normal particles.
Whether the unusual double-enveloped virions
are also infectious
remains to be answered.
Immunolocalization of ER proteins within viral structures.
To
confirm the cellular origin of the viral envelopes, we performed
immunogold labeling with antibodies to ER proteins on sections of
infected cells processed at 18 h p.i. for freeze-substitution (Fig. 7A to C) or cryosectioning (Fig. 7D
and E). As shown in Fig. 7A, the labeling with antibodies to the
luminal protein PDI was virtually excluded from the assembly sites.
However, a strong signal was observed in the intracisternal spaces of
marginal zipper-like structures (Fig. 7B). The mixted cellular and
viral nature of these intermediates was confirmed by double-labeling
experiments with antibodies to the ER protein PDI and to ASFV
polyprotein pp220, which has been shown previously to localize within
the viral core shell (3). As shown in Fig. 7C, whereas the
luminal contents was labeled with anti-PDI antibodies, the viral
domains were labeled with the anti-pp220 serum. On the other hand, the serum against membrane ER glycoproteins showed low but significant labeling associated with virus intermediates within the assembly sites
(Fig. 7D) and strong labeling on the membranes of marginal zipper-like
structures (Fig. 7E).
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FIG. 7.
Immunogold labeling of ER marker proteins in
ASFV-infected cells. Vero cells infected with ASFV for 18 h p.i.
were processed by freeze-substitution (A to C) or cryosectioning (D and
E). (A and B) Ultrathin sections were incubated with a MAb against the
luminal ER protein PDI followed by rabbit anti-mouse immunoglobulin G
and protein A-gold (diameter, 15 nm). Note that anti-PDI labeling
(arrowheads) is essentially excluded from the assembly sites (A) but
not from the luminal contents of peripheral zipper-like structures (B).
(C) Double labeling of a zipper-like structure with antiserum to
polyprotein pp220 followed by protein A-gold (diameter, 10 nm) and with
the anti-PDI MAb followed by protein A-gold (diameter, 15 nm). The
anti-pp220 labeling (arrowheads) is located within the core shell,
while PDI (arrows) is present within the associated cisterna. (D and E)
Thawed cryosections were incubated with anti-MERG antiserum followed by
protein A-gold (diameter, 10 nm). The labeling is associated with the
membranes of marginal zipper-like structures (D and E) and, to a much
lesser extent, to viral structures within the viral factories (E).
Bars: 500 nm (A) and 200 nm (B to E).
|
|
As mentioned in the introduction, a recent study by Cobbold et al.
(
8) has suggested colocalization of PDI with the viral
factories on the basis of immunofluorescence experiments. Close
examination of the reported photograph (Fig. 7 of reference
8)
reveals
that anti-PDI labeling was surprisingly much more intense
within
the assembly sites than in the surrounding cytoplasm. Such
a location
is not supported by our findings obtained with the
same MAb and other
ER markers by both immunofluorescence and immuno-EM.
Recombinant vA72 intermediates are enwrapped by collapsed ER
cisternae.
We have recently shown that the zipper-like structures
can be accumulated after infection with a recombinant virus, vA72, which inducibly expresses the major capsid protein p72 (15). Such a recombinant is IPTG dependent, and in the absence of the inducer, ASFV assembly is arrested at a stage where capsid formation is
inhibited and most of the precursor membranes form zipper-like intermediates (15). We therefore took advantage of these
observations to analyze the process of viral envelopment. To produce
large amounts of zipper-like structures, Vero cells were infected
with recombinant virus vA72 for 18 h in the absence of IPTG.
After this period, the cells were processed by conventional Epon
embedding. As shown in Fig.
8A, the assembly sites
showed a virtual absence of icosahedral virus particles but a great
accumulation of zipper-like structures. Importantly, these
intermediates appeared clearly associated with ER cisternae at
the boundaries of the viral factories (Fig. 8A and B). Moreover,
such ER cisternae appeared often collapsed by the apposition of the
limiting membranes and the subsequent constriction of the luminal
spaces (Fig. 8C).
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FIG. 8.
Origin of the inner envelope of ASFV recombinant vA72.
Epon sections of Vero cells infected with recombinant virus vA72 for
18 h in the absence of IPTG (A to C), or treated with the inducer
at 18 h p.i. for an 8-h period (D) are shown. (A) Under
nonpermissive conditions, the viral factories (VF) show a great
accumulation of zipper-like structures and a virtual absence of
polyhedral viral structures, as a consequence of the inhibition of
capsid formation. In the peripheral areas of the assembly sites, the
zipper-like structures appear clearly associated with ER cisternae
(arrowheads). (B) Higher magnification of the region delimited in
panel A. Note how a rough ER cisterna (arrowheads) appears
directly bound to an extended viral core shell. The small arrows
indicate ribosomes. (C) Partially collapsed ER cisternae associated
with zipper-like structures. The arrowheads delimit local extensions
where the cisternal structure is still evident. In our interpretation,
the collapse would lead to formation of the viral envelopes by the
tight apposition of the two limiting lipid bilayers. (D) Detail of a
viral factory after an 8-h period of IPTG induction. Under these
conditions, the zipper-like structures become polyhedral intermediates
by the de novo and gradual assembly of the capsid layer (c) on the
inner envelope (ie). The arrows indicate the ends of two capsids
assembling on opposite faces of the same zipper-like structure. Note
also the presence of membrane loops (arrowheads) at the ends of the
viral envelopes. Bars: 500 nm (A) and 100 nm (B to D).
|
|
After 8 h of IPTG induction, the zipper-like structures became
polyhedral forms by the progressive de novo assembly of the
capsid
layer on their external surfaces (Fig.
8D). As occurs with
parental
virus infections, evidence of the cisternal structure
of the limiting
envelopes was eventually detected at their ends,
in the form of
membrane loops. As recently described, a further
evolution of these
intermediates led to the assembly of closed
double-enveloped
icosahedral particles (
15).
Collectively, these observations support the conclusion that ASFV inner
envelopes originate from the collapse of the ER compartment
in the
vicinity of the assembly sites. Within the viral factories,
the two
membranes composing the viral envelope would be so closely
juxtaposed
that they would appear to be a single membrane.
| |
DISCUSSION |
Large enveloped DNA viruses like poxviruses and herpesviruses take
their membranes by an enwrapping process from cellular cisternae
(16, 29, 33, 38, 43). In the present study, we propose that
ASFV, another complex DNA virus, uses a similar mechanism to acquire
its inner envelope. According to our previous work, the assembly
pathway of ASFV is a complex multistep process which is first
manifested by the appearence of electron-dense membranous structures
within cytoplasmic viral factories. These precursor viral membranes
enclose the core material while becoming polyhedral particles by the
gradual assembly of the capsid on their convex surfaces (3,
15). As a consequence, the resulting intracellular particles are
composed of a core surrounded by two shells, an inner envelope and an
outer capsid. The whole process occurs in the cytosol, so that a
budding process cannot explain ASFV envelopment. Additionally, this
implies that both faces of the viral envelope are exposed to a
cytosolic environment. Our model is not, however, topologically
consistent with the classical view of the structure of ASFV and of the
related iridoviruses, which considers the inner envelope to be a single
lipid membrane (7, 10, 20, 41). Cellular membranes are
asymmetric structures, with one face exposed to the cytosol and the
other exposed to either the luminal or the extracellular space.
Assuming that viral membranes are derived from the host cell and
respect its topology (19, 26, 40), we first asked whether
ASFV is wrapped by a cellular cisterna instead of a single
membrane.
The results of the present work, based on both ultrastructural and
immunocytochemical EM approaches, support the conclusion that the inner
viral envelope is derived from a collapsed two-membraned ER
cisterna. Two distinct membranes could be discerned within all
intracellular viral forms, from the precursor membrane-like structures
onward. However, they appeared so tightly bound that they usually
seemed to be a single lipid bilayer. Importantly, the two membranes
appeared to be frequently interconnected by loop-like structures at the
ends of the precursor viral membranes as well as in open
polyhedral assembling virions. Together, these data argue for
the cisternal nature of the inner envelope.
Additional support for this model was obtained from experiments
involving selective disruption of virus particles. This approach revealed that the outer capsid was resistant to treatments with nonionic detergents but digested with proteinase K. The resulting particles retained the icosahedral symmetry in the first case but not
in the second. These results are in agreement with the protein nature
of the capsid and confirm its central role in the ASFV morphology
(7, 15). By contrast, the inner envelope showed the opposite
behavior. It was removed by detergents but not by the proteinase.
Importantly, after the proteinase K treatment, two detached membranes
became obvious within the inner envelope of highly disrupted particles,
which is consistent with the architecture proposed for ASFV.
During the preparation of this communication, a report by Roullier et
al. (31) suggested a different structure for the
intracellular ASFV particles. On the basis of the
electron-lucent appearance alone, these authors interpret the two main
shells encompassing the viral core to be lipid membranes. Additionally,
in such a model, the capsid is an outermost structure that,
surprisingly, is not visible or identified in the reported micrographs.
In our opinion, it is well established that the second, outer shell of ASFV and also of the related iridoviruses is an icosahedral capsid made
up of protein units, the capsomers, closely packaged in an hexagonal
arrangement (Fig. 1C) (2, 7, 10, 20, 41). We have recently
shown that this layer is progressively assembled on preexisting
membrane-like structures, which concomitantly become polyhedral
particles (Fig. 1E and 6G and H) (3). Moreover, its
formation can be reversibly inhibited with a recombinant virus, vA72,
that inducibly expresses the major capsid protein p72 (Fig. 8A to C)
(15). In other words, this shell does not exist when p72
expression is inhibited but it can be assembled de novo on the inner
envelope after IPTG induction (Fig. 8D). Finally, the present work
shows that this layer is resistant to detergent treatments whereas it
is digested by proteinase K (Fig. 2). We therefore believe that the
outer shell described by Roullier et al. as a lipid membrane is in fact
the viral capsid.
An alternative possibility based on both models, i.e., that the capsid
is a virus-modified membrane, does not seem probable. On the one hand,
the above considerations do not support the presence of a lipid
membrane within the capsid layer. On the other hand, such a hypothesis
would imply that the capsomers are inserted into a lipid bilayer.
However, the major capsid protein p72 lacks transmembrane domains
(22) and has been recently characterized by Cobbold et al.
as a peripheral membrane protein (8). Such evidence is
consistent with our present model.
The second important question analyzed in the present study
is the origin of the inner viral envelope.
Double-immunofluorescence experiments showed a strong presence of
ER and Golgi markers at the limits of the assembly sites but a drastic
exclusion of these proteins from the internal areas. At the EM level,
morphological and immunocytochemical approaches revealed a close
association and even direct continuities between ER membranes and viral
intermediates at the periphery of the assembly sites. Collectively,
these results indicate that the viral envelopes are derived from ER
cisternae and that their transformation into viral intermediates is
probably confined to the peripheral areas of the viral factories. This would explain the virtual absence of cell organelles within the assembly sites and the difficulty in detecting direct continuities between cellular and viral membranes (3, 23; see above). In this
respect, the immunolabeling data are in agreement with the extended
view that the enveloped viruses effectively exclude and replace the
host membrane proteins by virus-encoded proteins (26, 40). A
study by Brookes et al. (5) showed that during ASFV
infection, the viral factory increases in size considerably, conquering
new cytoplasmic areas. According to our observations, this fact
could be the result of the continued demand for ER membranes during ASFV assembly.
The analysis of the viral zipper-like structures provided a useful
approach to understanding the process of envelopment of ASFV. These
viral intermediates, which are frequently observed although in small
amounts, consist of two adjacent membrane cisternae bound by an
extended viral domain structurally similar to the viral core
shell (3). In relation to the limiting membrane cisternae,
two extreme situations were observed. In the peripheral areas of the
viral factories, they appeared as typical ER cisternae with
ribosome-attached membranes containing both luminal and membrane ER
host proteins. By contrast, within the viral factories, the zipper-like structures appeared limited by typical viral envelopes made
up of two closely apposed membranes. This finding suggests, together
with the observation of zipper-like structures with partially collapsed ER cisternae during the assembly of recombinant vA72, that
the collapse of ER cisternae leads to the formation of the inner
viral envelope.
An interesting aspect of the zipper-like structures is the unusual
topology of the core shell. Whereas the core shell of normal particles
is located between the inner envelope and the nucleoid, in the
zipper-like intermediates it is encompassed by lipid membranes. Interestingly, in both cases, this viral domain appears to be composed
of two regular arrays of globular subunits separated by a thin
electron-dense layer (3) (Fig. 6K). Such a configuration is
consistent with the symmetrical features of the zipper-like intermediates but does not explain the polarization of the core shell
in normal particles. This difference might reflect the eventual absence
of a key viral component(s) during the assembly of the zipper-like
structures. In this sense, the finding that these viral forms
accumulate when the expression of the capsid protein p72 is inhibited
(15) implies that this protein and the process of capsid
formation play a role in the polarization of the virus intermediates.
Collectively, the results of this work suggest a model for the assembly
of ASFV as presented in Fig. 9. The
process probably begins with the insertion of key viral proteins into
the ER membranes and the concomitant exclusion of the host cell
proteins. Intraluminal interactions between viral membrane proteins
would lead to the collapse of the ER cisternae, giving rise to the
precursor viral membranous structures. Subsequently, peripheral
membrane proteins like p72 (8) would bind to the viral
envelope to form the capsid layer on one face, while other
membrane-associated proteins such as polyprotein pp220 (3)
would form the core shell on the opposite side. Such a model implies a
polarization of the collapsed cisternae that needs to be elucidated.
One possibility is that distinct viral membrane integral proteins are
differently sorted into the outer and inner membranes of the viral
envelope. Another possible explanation is that the viral envelope
becomes polarized by cooperative interactions between peripheral
membrane proteins on local extensions of the collapsed cisterna. In
this sense, the progressive assembly of the capsid components and the
subsequent bending of the envelope could represent a key event in the
generation of asymmetrical viral envelopes. During the late stages of
ASFV morphogenesis, the nucleoprotein material of the nucleoid is
probably assembled within the particle at the time when it is closing
(3). Finally, the intracellular particles would be released
to the extracellular space by a budding process at the plasma
membrane (4). As a consequence, the resulting ASFV particles
would contain three lipid membranes, with the two innermost ones being
derived from a collapsed cisterna. Although this model is
strongly supported by morphological and immunocytochemical evidence,
further efforts will be required to understand the molecular mechanisms
involved in crucial events such as the collapse and polarization
of the cisternal viral envelope or the encapsidation of the viral
genome.
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FIG. 9.
Model for ASFV assembly. Intracellular ASFV particles
acquire their inner envelopes from the ER. The envelopment probably
begins by the insertion of viral proteins into the ER membranes and,
concomitantly, the exclusion of the host membrane proteins. During this
process, the cell compartment would be collapsed to give rise to
precursor viral structures formed by two tightly apposed membranes.
Subsequently, the capsid would be gradually assembled on one side of
the inner envelope whereas the core shell would form beneath the
opposite face. At the time the particle is closing, the nucleoprotein
material of the nucleoid would become engulfed. Finally, the
intracellular particles would release from the cell by budding at the
plasma membrane (PM). According to this model, the resulting
extracellular ASFV particles would contain three lipid membranes.
|
|
Despite the obvious morphological differences between ASFV
and the poxviruses, this assembly model is analogous in some
aspects to that described for the intracellular mature form of vaccinia virus (IMV). According to Roos et al. (29), the lipid
envelope of IMV consists of two juxtaposed lipid membranes covered by a brush-like array of protein spicules on its convex surface. This envelope is derived from cisternal elements of the intermediate compartment, a specialized region of the ER contiguous with the Gogi complex (38). Importantly, the two apposed membranes of IMV are usually indiscernible but become obvious after protease treatments (38). ASFV and the poxviruses share striking
features such as the genome organization (44) or the
transcriptional control of gene expression (28). In this
context, our present work establishes a new similarity between the
two families of complex deoxyviruses. On the other hand, considering
the closely related morphology of the iridoviruses and ASFV (7,
41), which was formerly considered to be one of them, it could be
predicted that a similar mechanism would also explain their assembly
pathway.
| |
ACKNOWLEDGMENTS |
We thank M. L. Salas and J. Salas for critical reading of
the manuscript. We are very grateful to E. Berger, J. G. Castaño, H.-P. Hauri, D. I. Meyer, J. Rohrer, I. Sandoval,
and A. Schweizer for their generous gifts of antibodies. We
also thank C. San-Martin and M. Rejas for technical assistance and
J. A. Pérez Gracia for skillful help with the photography
work.
This study was supported by grants from the Dirección General de
Investigación Científica y Técnica
(PB96-0902-C02-01), the European community (FAIR-CT97-3441), and
Fundación Ramón Areces. Germán Andrés
was supported by fellowships from Fundación Rich and Comunidad
Autónoma de Madrid, and Ramón García-Escudero was
supported by a fellowship from the Comunidad Autónoma de Madrid.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Centro de
Biología Molecular "Severo Ochoa," Facultad de Ciencias,
Universidad Autónoma de Madrid, Cantoblanco, 28049 Madrid, Spain.
Phone: 34 91 397 84 36. Fax: 34 91 397 84 90. E-mail:
Evinuela{at}mvax.cbm.uam.es.
| |
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Journal of Virology, November 1998, p. 8988-9001, Vol. 72, No. 11
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
