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Previous Article | Next Article 
Journal of Virology, July 2000, p. 6600-6613, Vol. 74, No. 14
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Trafficking of Varicella-Zoster Virus Glycoprotein gI:
T338-Dependent Retention in the trans-Golgi
Network, Secretion, and Mannose 6-Phosphate-Inhibitable Uptake of
the Ectodomain
Zuo-Hong
Wang,1
Michael D.
Gershon,2
Octavian
Lungu,3
Zhenglun
Zhu,2,
and
Anne A.
Gershon4,*
Institute of Human
Nutrition1 and Departments of Anatomy & Cell Biology,2
Microbiology,3 and
Pediatrics,4 Columbia University College
of Physicians and Surgeons, New York, New York 10032
Received 3 February 2000/Accepted 25 April 2000
 |
ABSTRACT |
The trans-Golgi network (TGN) is putatively the site
where varicella-zoster virus is enveloped. gE is targeted to the TGN by
selective retrieval from the plasmalemma in response to signaling sequences in its endodomain. gI lacks these sequences but forms a
complex with gE. We now find that gI is targeted to the TGN and plasma
membrane when expressed in Cos-7 cells; nevertheless, surface labeling
revealed that gI is not retrieved from the plasma membrane. TGN
targeting of gI depended on the T338 of its endodomain and
was lost when T338 was deleted or mutated to A, S, or D. The endodomain of gI was sufficient, if it contained T338,
to target a fusion protein containing the ectodomain of the human
interleukin-2 receptor to the TGN. A truncated protein consisting only
of the gI ectodomain was secreted and taken up by nontransfected cells.
This uptake of the secreted gI ectodomain was blocked by mannose
6-phosphate. Following cotransfection, both gI and gE were retrieved to
the TGN from the plasma membrane in 26.7% of cells, neither gI nor gE
was internalized in 18.3%, and gE was retrieved to the TGN while gI
remained at the plasma membrane in 55%. We suggest that the
T338 of its endodomain is necessary to retain gI in the
TGN; moreover, because gI and gE interact, the signaling sequences of
each glycoprotein reinforce one another in ensuring that both
glycoproteins are concentrated in the TGN yet remain on the cell surface.
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INTRODUCTION |
Envelopment of varicella-zoster
virus (VZV) has been proposed to be a two-step process that is
completed in the trans-Golgi networks (TGN) of infected
cells (8). According to this hypothesis, nucleocapsids
assemble in the nucleus and acquire a primary envelope by budding
through the inner nuclear membrane. Budding delivers the temporarily
enveloped virions to the perinuclear cisterna, which is continuous with
the rough endoplasmic reticulum (RER). Fusion of the primary envelope
with the membranes of the RER enables the nucleocapsids to gain access
to the cytosol, though which they are translocated to the TGN. The VZV
glycoproteins (gps) are synthesized on attached polyribosomes and are
transported as integral or peripheral membrane proteins from the RER
via the Golgi apparatus to the TGN, where they are concentrated for
incorporation into the final viral envelope. Tegument proteins lack
signal sequences (6) and must thus be synthesized on free
polyribosomes in the cytosol; nevertheless, there is evidence that
tegument proteins that are included in assembled virions also
concentrate in the region of the TGN, where they are associated with
the cytosolic domains (endodomains) of integral membrane gps
(8). Envelopment within the TGN is thought to involve the
restriction of gps to the concave surface of flattened sacs that wrap
around nucleocapsids (Fig. 1). Tegument
is trapped by the wrapping process and so becomes included in the final
virion. A process of fusion of membranes with subsequent fission
converts the enveloping sac into an inner viral envelope and an outer
transport vesicle. In cells that contain a lysosomal pathway, the
transport vesicle membrane is rich in the large cation-independent
mannose 6-phosphate receptor (MPR). Perhaps for this reason, virions
are directed in tissue culture cells to acidic post-Golgi vacuoles that
have been identified as late endosomes (7, 8). Virions
appear to be inactivated in these vacuoles, accounting for the strict
cell association of VZV when propagated in tissue culture.
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FIG. 1.
Heuristic model depicting the envelopment of VZV. Viral
gps are synthesized in the RER and transported through the
cis-Golgi network (CGN) and Golgi stack to the TGN, where
they concentrate. Step 1: curvilinear vacuoles appear in the TGN.
Tegument is bound to the concave face of these vacuoles, while their
convex face is smooth. The gps are concentrated in the tegument-coated
membrane of the concave face. Capsids adhere to the tegument. The lips
of the curvilinear vacuole wrap around a capsid (arrows). Step 2: the
extending lips of the curvilinear vacuole fuse, trapping a capsid and
the tegument that surrounds it within a cavity delimited by the concave
membrane. Step 3: subsequent fission of the fused lips of the vesicle
creates two separate membrane-enclosed structures, an inner virion and
an outer transport vesicle. The original, tegument-lined concave face
becomes the viral envelope, while the smooth convex face becomes a
transport vesicle that carries the enveloped virion to post-Golgi
destinations.
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The hypothesis that the final site of VZV envelopment is the TGN
requires that all of the components of the final virion be targeted to
this organelle. For the integral membrane gps, targeting could involve
signal sequences or patches in the primary structure of the proteins.
Alternatively, gps that lack such targeting information (passenger gps)
could still be sorted to the TGN if they were to form complexes with
gps that do contain targeting sequences (navigator gps). Previous data
has indicated that gE, the most abundant gp of VZV (9), is
targeted to the TGN as a result of the presence in its endodomain of a
targeting sequence, AYRV, and a signal patch rich in acidic amino acids
(2, 46). These signaling regions resemble those which have
been found in the endodomains of the endogenous TGN proteins furin
(12, 39) and TGN38 (3, 11, 25, 27, 38, 40). The
targeting of gE to the TGN is an indirect process that includes its
endocytosis from the plasma membrane, followed by selective retrieval
to the TGN (2, 45). In keeping with this route of transport,
there is an endocytosis signal in the endodomain of gE (21).
The mechanism by which gI is concentrated in the TGN is less clear than
that for gE. Since the N-terminal domain of gI forms a complex with gE
in the RER (14, 42), gI might be expected to be simply a
passenger gp and follow the itinerary navigated by gE. If this were to
be the case, then gI would not be targeted to the TGN in transfected
cells that express gI by itself. Targeting of gI to the TGN would only
occur in cells that express both gI and gE. There is evidence that gI
is recycled from the plasma membrane by endocytosis when it is
expressed by itself in HeLa cells (19); however, a contrary
study reports that HeLa cells that express gI restrict it to the plasma
membrane and do not reinternalize gI (1). This latter report
also maintains that gI is not targeted to the TGN unless it is
coexpressed in HeLa cells together with gE. In contrast, gI has been
found to be targeted to the TGN when expressed by itself in transfected
Cos-7 cells (36). Conceivably, foreign proteins could be
transported differently in different types of cell. To be transported,
a foreign protein would have to contain a signaling domain, but the
cell would also have to express an endogenous receptor capable of
responding to the signal sequence or patch in the protein. The
successful targeting of gI to the TGN of Cos-7 cells indicates that TGN
targeting information is present in the primary sequence of gI, which
can be recognized by at least some types of cell. That phenomenon is
significant, because there is no reason to believe that Cos-7 cells are
unique. The cellular machinery that enables Cos-7 cells to respond to signaling information in the primary sequence of gI is thus likely also
to be present in additional cell types.
The current experiments were undertaken to identify and characterize
the signaling domain that is responsible for the ability of Cos-7 cells
to target gI to the TGN. An additional goal was to compare the routes
to the TGN followed by transported gI and gE. Because gI and gE form a
complex (13, 41, 42), the sorting of these proteins was
analyzed in cells in which they were expressed individually and also in
those in which they were coexpressed. The data confirm that gI is
targeted to the TGN when expressed by itself in Cos-7 cells, the
responsible targeting signal resides in the endodomain of gI, and
T338 is critical for targeting. In contrast to gE, the
independent targeting of gI does not involve retrieval from the plasma
membrane but retention of gI in the TGN during intracellular transport. Truncation of the C-terminal domain of gI, including the transmembrane region, causes the mutant protein to be secreted. Nontransfected cells
take up the secreted protein by an endocytic mechanism that is
inhibited by mannose 6-phosphate (Man 6-P).
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MATERIALS AND METHODS |
Cells and antibodies.
Cos-7 cells were grown in Dulbecco's
modified Eagle's medium containing 10% heat-inactivated fetal bovine
serum, 100 U of penicillin per ml, and 100 U of streptomycin per ml.
Cultures were maintained at 37°C with 5% CO2. Monoclonal
antibodies to gE and gI were purchased from Viro Research Inc.
(Rockford, Ill.). Rabbit polyclonal antibodies to recombinant gE and
gI, raised in our laboratory and characterized as previously described,
were also used (36). Antibodies to detect the adaptin
protein complex AP-1 (monoclonal anti-
-adaptin clone 100/3) were
obtained from Sigma Chemical Co. (St. Louis, Mo.) (2, 29).
Antibodies to the human interleukin-2 receptor (tac) were purchased
from Biodesign International (Kennebunk, Maine).
PCR cloning.
DNA encoding gI and gE was cloned from VZV
(Ellen strain) genomic DNA (36, 46). For both gps, reaction
mixtures were initially incubated for 3 min at 94°C and then
subjected to 35 cycles of 1 min at 94°C, 1 min at 58°C, and 3 min
at 72°C. For gI, Vent polymerase (New England Biolabs) was employed
for amplification, and the resulting products were cloned into pZErO-2
(Invitrogen, Carlsbad, Calif.). The cloned DNA was digested with
EcoRI and XbaI and gel purified. For gE,
Taq polymerase was used for amplification (46).
The PCR products were digested with Asp718 and
XbaI and gel purified. The resulting DNA encoding gI or gE
was cloned into the multiple cloning sites of the eucaryotic expression
vector pSVK3 (Pharmacia, Piscataway, N.J.). The primers used to clone gI were 5'-CCCGAATTCTCATTTAATCGCGATGTT-3' and
5'-CCCTCTAGATAATTAGTTCTATTTAAC-3'. The primers used to clone
gE were 5'-CCCGGTACCGAGGGTCGCCTGTAATAT-3' and
5'-CCCTCTAGATGCCCCGGTTCGGTGATCA-3'. The primers employed
to produce truncated and mutated gI constructs are shown in Table 1. Chimeric cDNA constructs encoding
chimeric proteins in which the transmembrane and endodomains of
gI were fused to the extracellular domain of tac were prepared
(10, 30). Essentially, the terminal primers amplified two
overlapping DNA fragments and overlapping internal primers that
encompassed the desired mutant. Gel-purified products of the first step
of amplification were employed for a second round of PCR amplification
in which only the terminal primers were used. The terminal 5' tac
primer was 5'-CCCGGTACCAAGGGTCAGGAAGATGGA-3'. This amplimer
was paired with the upstream internal primer
5'-ATCATTAAGGGATGTTGTAAATATGGAGGT-3', the downstream
internal primer 5'-TTTACAACATCCCTTAATGATCCTCCA-3', and an
appropriate gI wild-type (gIwt) or mutant 3' amplimer
(Table 1). The authenticity of all constructs was verified by
sequencing.
Transfection and culture of cells.
For transfection, cells
were grown on glass coverslips in two- or eight-well chambers. Cells
were transfected with cDNA constructs using Lipofectin (Life
Technologies, GIBCO, Grand Island, N.Y.) according to the
manufacturer's directions. Cells were incubated at 37°C in an
atmosphere of 5% CO2. The medium was changed after 12 h, and incubation was continued for another 48 h. In most
experiments the cells were then fixed with 2% formaldehyde (freshly
prepared from paraformaldehyde) in phosphate-buffered saline (PBS) at
pH 7.4 for 2 h at room temperature. In the remaining experiments, endocytosis of expressed proteins was studied. For this purpose, polyclonal antibodies to gI or gE (5 ng/ml) were added to cells that
had been transfected with cDNA encoding gIwt or
gEwt. Cells were incubated for 30 min in the presence of
the added antibodies and were then fixed as described above.
Immunocytochemistry.
Fixed cells were washed with PBS and
permeabilized with 0.1% Triton X-100 in PBS containing bovine serum
albumin (BSA) (2.0 mg/ml). Primary antibodies were then applied for
2 h at room temperature. To visualize the sites of primary
antibody binding, the cells were thoroughly washed, and appropriate
affinity-purified secondary antibodies coupled to contrasting
fluorophores were applied for 1 h at room temperature. In initial
experiments, the secondary antibodies were goat anti-rabbit or
anti-mouse immunoglobulin G labeled with fluorescein isothiocyanate
(Kirkegaard & Perry, Gaithersburg, Md.) or cyanine-3 (Jackson
Immunoresearch Laboratories, Inc., West Grove, Pa.). In subsequent
studies, the secondary antibodies were coupled to Alexa fluor-488 or
Alexa-594 (Molecular Probes Inc., Eugene, Oreg.), because of the
brighter fluorescence of the newer fluorophores and the lack of overlap
in their emission spectra. All secondary antibodies were applied in a
dilution of 1:80 in PBS with BSA (2 mg/ml). Slides were mounted in
glycerol-PBS (8:1) containing 
-nitrophenol to minimize fading. When
only proteins at the cell surface were examined by immunocytochemistry,
cells were processed in the same way except that the permeabilization step was omitted. For the experiments on endocytosis of antibodies, fixed cells were permeabilized but probed only with an appropriate secondary antibody. The lipid
N-(
-7-nitrobenz-2-oxa-1,3-diazo-4-yl-aminocaproyl)-D-erythro-sphingosine (C6-NBD-ceramide) was used as a marker to locate the TGN
(23). The TGN was also marked in transfected cells by its
ability to recruit the adapter complex AP-1, which was visualized with
antibodies to -adaptin (see above) (2, 29).
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RESULTS |
A signal in its endodomain is sufficient to target gI to the
TGN.
Constructs encoding gIwt or truncated mutant
forms of gI lacking all or part of its endodomain (Fig.
2, Table 1) were transfected into Cos-7
cells. The expressed proteins were then localized
immunocytochemically using polyclonal and/or monoclonal
antibodies to gI. The TGN was identified by simultaneously localizing
the immunoreactivity of -adaptin (AP-1) (2, 29) and
intracellular sites of concentration of C6-NBD-ceramide
(23). Expressed gI (Fig. 3A
and C) was found to be transported to the plasma membrane but also to
be concentrated in the TGN, where it colocalized with -adaptin
immunoreactivity (Fig. 3B) and with C6-NBD-ceramide (Fig.
3D).
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FIG. 2.
Domains of the full-length gIwt and
mutations made at sites within the sequence of the putative endodomain
of gI. The nomenclature used to refer to each construct is shown to the
left of its sequence. The sequence of the putative endodomain is shown
beginning at the deduced transmembrane region. Also shown (to the right
of each construct), is whether or not the corresponding expressed
protein was found to be concentrated in the TGN of transfected cells.
In addition to the transport of these membrane-anchored forms of gI, a
truncated soluble protein, consisting only of the gI ectodomain (not
illustrated), was also expressed in transfected cells. This protein was
found in the TGN due to secretion and reuptake into endosomes (see
text).
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FIG. 3.
Immunoreactivity of gI colocalizes with TGN markers in
transfected cells. (A and B) The immunoreactivity of gI (A) is
coincident with that of -adaptin, used as a marker for the AP-1
adapter complex. (C and D) The immunoreactivity of gI (C) is coincident
with the fluorescence of C6-NBD-ceramide, a lipid
fluorophore that concentrates in membranes of the TGN (8,
23). Coincident concentration of gI immunoreactivity with the TGN
markers in the TGN region of the transfected cells is indicated by the
arrows. Bars, 10 µm.
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To test the hypothesis that gI is targeted to the TGN because of a
signal in its endodomain, the targeting of expressed protein was
analyzed in cells that had been transfected with constructs encoding
truncated mutants of gI (Fig. 2, Table 1). Again,
gIwt was found to be targeted to the TGN (Fig.
4A); however, when the endodomain of gI was entirely lacking, the expressed protein, gI
7, did not reach the TGN (Fig. 4K). Instead, the
pattern of immunoreactivity suggested that gI7 remained
in the RER. All of the mutant constructs that, like gIwt,
gave rise to expressed proteins that were targeted to the TGN,
gI1 (Fig. 4B), gI2 (Fig. 4C),
gI3 (Fig. 4D), gIKK (Fig. 4E), and
gI3R
E (Fig. 4F), had in common the presence of
T338.
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FIG. 4.
Signal in the endodomain of gI encompassing
T338 is necessary for targeting expressed protein to the
TGN. The nomenclature and corresponding sequences of the gI mutant
constructs used to transfect Cos-7 cells are depicted in Fig. 2. The
arrows indicate fluorescence in the TGN region of transfected cells.
(A) Expressed gIwt is concentrated in the TGN and plasma
membrane. (B) Expressed gI1 (lacking the five C-terminal
amino acids of gIwt) is still targeted to the TGN and
plasma membrane. (C and D) Expressed gI2 (lacking the
nine C-terminal amino acids of gIwt) and gI3
(lacking the 12 C-terminal amino acids of gIwt) are still
targeted to the TGN and plasma membrane. (E) Expressed
gI2KK (E341 to K341 and
E342 to K342) is targeted to the TGN and plasma
membrane. This mutation destroys a consensus casein kinase II site. (F)
Expressed gIRE (R340 to E340;
also lacking the 12 C-terminal amino acids of gIwt) is
targeted to the TGN and plasma membrane. R340 is thus not a
component of a TGN targeting signal. (G) Expressed
gI3tA (T338 to A338; also
lacking the 12 C-terminal amino acids of gIwt) is not
targeted to the TGN or plasma membrane. The pattern of immunoreactivity
suggests that the expressed gI3tA may be retained in
the RER. The same results are obtained when T338 is mutated
to S338 or D338 (not illustrated).
T338 is thus required for TGN targeting. (H to K) Expressed
gI4, gI5, gI6, and
gI7, respectively (which lack, respectively, the 17, 19, 36, and 59 [entire endodomain] C-terminal amino acids of
gIwt and thus the critical T338), are not
targeted to the TGN or plasma membrane. Note that gI5
contains all of the amino acids N-terminal to T338. (L)
Expressed gIcd+tm is concentrated in the TGN. Note that
gIcd+tm differs from gI7 (K), which lacks
the endodomain of gIwt, in that the transmembrane domain of
gIwt is also deleted in gIcd+tm. Bars, 10 µm.
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The fact that mutation of E341 and E342 to
K341 (Fig. 4E) did not affect sorting to the TGN suggests
that acidic amino acids at these locations are not part of a TGN
targeting sequence. Similarly, the lack of effect on TGN
targeting of mutating R340 to E340 (Fig. 4F)
suggests that a basic amino acid is not required at this site. In
contrast, the mutation of T338 to A338,
S338, or D338 eliminated TGN targeting and
resulted in apparent retention of the expressed protein in the RER
(Fig. 4G). These observations imply that T338 is critical
for the targeting of gI to the TGN. The E341 and
E342 to K341 and K342 mutation
eliminates a consensus site for phosphorylation by casein kinase II
(X-S/TP-X-X-E-X). If TGN targeting of gI requires the
phosphorylation of T338, casein kinase II is probably not
the responsible enzyme. Mutations of T338 to
S338 and D338 were generated to test the
possibility that phosphorylation of T338 by any
serine/threonine protein kinase contributes to TGN targeting. An
asparagine residue often behaves as if it were a constitutively phosphorylated threonine (5, 33). The failure of
S338 and D338 to substitute for
T338 thus does not suggest that the phosphorylation of
T338 by a serine/threonine protein kinase plays a role in
the targeting of gI to the TGN.
A gI mutant lacking both cytosolic and membrane domains is
concentrated in the TGN and endosomes and is secreted.
Surprisingly, when both the transmembrane and endodomains of gI
(gIcd+tm) were deleted, the expressed protein was again
concentrated in the Golgi region of the cells or the TGN (Fig. 4L).
This observation was unexpected, because deletion of the endodomain of
gI abolished TGN targeting when the transmembrane domain was retained.
In addition to the Golgi/TGN, expressed gIcd+tm protein
was also found in small cytosolic vesicles (Fig. 4L and 4A), which were
not seen in cells transfected with constructs encoding either
gIwt or any of the other mutants that contained a
transmembrane domain but lacked elements of the endodomain.
Since the small vesicles that contained gI immunoreactivity in cells
transfected with cDNA encoding gIcd+tm resembled endosomes, experiments were done to test the hypothesis that
gIcd+tm is partially sorted to endosomes. Cells that
were transfected with constructs encoding gIcd+tm were
incubated for 30 min with an endosomal tracer, Lysotracker, prior to
fixation. Lysotracker, which is fluorescent, is taken up by endocytosis and thus marks the endocytic compartment of cells that have taken it
up. The 30-min time of incubation is not sufficient for Lysotracker to
be transferred from endosomes to lysosomes. Following fixation of the
cells, the immunoreactivity of gI was demonstrated simultaneously with
the fluorescence of Lysotracker. A partially coincident localization of
gI immunoreactivity (Fig. 5A) with
Lysotracker (Fig. 5B) was observed, confirming that a subpopulation of
endosomes contains gIcd+tm. These observations indicate
that gIcd+tm is sorted to endosomes as well as to the
TGN.
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FIG. 5.
Subset of the cytoplasmic vesicles of transfected cells
that contain gIcd+tm are endosomes. Transfected cells
were incubated with the fluorescent endosomal tracer Lysotracker in
order to determine whether the expressed mutant construct enters the
endosomal pathway. A coincident localization of gI immunoreactivity and
Lysotracker fluorescence was found in many of the cytoplasmic vesicles
of transfected cells expressing gIcd+tm (arrows). These
observations suggest that gIcd+tm gains access to the
endosomal pathway. Bars, 10 µm.
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Since gIcd+tm contains a signal sequence but no
transmembrane domain, the protein would be expected to be translocated to the lumen of the RER. A similar truncated form of gE is secreted (45). The appearance of gIcd+tm in endosomes
could be explained if gIcd+tm were similarly to be
secreted and then taken up by endocytosis. The protein could then be
transported to the TGN within endocytic vesicles. To determine whether
this postulated process occurs, medium conditioned by the growth of Cos-7 cells expressing gIcd+tm was collected and
transferred to fresh cultures of nontransfected Cos-7 cells. As a
control, conditioned medium was also collected from cultures of cells
expressing gIwt and similarly transferred to cultures of
nontransfected cells. The transferred medium was rendered cell-free
prior to transfer by centrifugation at 1,000 × g and
passage through a 0.2-µm filter. gI immunoreactivity was found in a
Golgi pattern and small vesicles in nontransfected Cos-7 cells exposed
to medium from cells transfected with gIcd+tm (Fig.
6A), but no such immunoreactivity appeared in cells exposed to medium from cells transfected with gIwt (Fig. 6B). These observations suggest that transfected
cells that express gIcd+tm secrete the protein into the
medium and that secreted gIcd+tm can be taken up by
nontransfected cells.
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FIG. 6.
Expressed gIcd+tm is secreted and taken
up by a Man 6-P-dependent mechanism. Cells were transfected with either
gIcd+tm or gIwt (control). Medium was
collected, rendered cell-free, and passed to recipient cultures of
nontransfected Cos-7 cells. (A) The immunofluorescence of gI is
concentrated in some cytoplasmic vesicles and in the TGN (arrows) of
recipient cells exposed to medium conditioned by cells transfected with
gIcd+tm. (B) No gI immunofluorescence is found in the
TGN of recipient cells exposed to medium conditioned by cells
transfected with gIwt. (C) Addition of Man 6-P (20 µM) to
the medium prevents the appearance of gI immunofluorescence in
recipient cells exposed to medium conditioned by cells transfected with
gIcd+tm. (D) Addition of Man 6-P (20 µM) to the medium
does not alter the appearance of recipient cells exposed to medium
conditioned by cells transfected with gIwt. There is no
recognizable gI immunofluorescence. Bars, 10 µm.
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The ectodomains of gI and other VZV gps are known to contain Man 6-P
groups (7). Lysosomal enzymes and other proteins that contain Man 6-P groups are known to be taken up by receptor-mediated endocytosis following their binding to plasmalemmal MPRs (37, 44). Since uptake mediated by an MPR would be inhibited by Man 6-P, the ability of Man 6-P to antagonize the uptake of
gIcd+tm was explored. Addition of exogenous Man 6-P (20 mM) completely prevented the uptake of gIcd+tm from the
transferred conditioned medium (Fig. 6C). Man 6-P (20 mM) did not
affect the appearance of cells exposed to medium from cells expressing
gIwt (Fig. 6D). These observations support the idea that
cell surface MPRs mediate the uptake of secreted
gIcd+tm.
A fusion protein containing the transmembrane and endodomains
of gI and the ectodomain of tac is targeted to the TGN.
To confirm
whether the endodomain of gI contains TGN targeting information,
chimeric proteins were constructed in which the ectodomain of tac was
fused to the transmembrane and endodomains of gI
(tac-gIcd+tm). Cos-7 cells that are transfected with cDNA encoding the full-length tac target the expressed protein only to
the plasma membrane (45, 46). Cos-7 cells transfected with
the tac-gIcd+tm construct were found to target the
expressed protein to both the plasma membrane and the TGN (Fig.
7A and C). The location
of the TGN marker C6-NBD-ceramide (Fig. 7B) coincided with that
of the protein expressed within the same cells transfected with the
tac-gIcd+tm construct (Fig. 7A), confirming that the tac-gIcd+tm fusion protein is targeted to the TGN. The localization of tac-gIcd+tm is thus essentially the same as
that seen in cells that express the full-length gIwt
(compare Fig. 3A and C with Fig. 4A).
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FIG. 7.
Signal in the endodomain of gI can target the tac
ectodomain to the TGN. Constructs were prepared encoding proteins in
which the ectodomain of tac was fused to the cytosolic and
transmembrane domains of gI. In some of these constructs the endodomain
of gI was mutated. These mutations were designed to correspond to those
shown in Fig. 2. The location of the expressed fusion proteins in
transfected cells, demonstrated by tac immunofluorescence, can be
compared to the gI immunoreactivity of the corresponding gI mutants
shown in Fig. 4. (A and B) The immunoreactivity of tac is coincident
with the fluorescence of the TGN marker
C6-NBD-ceramide in cells expressing
tac-gIcd+tm. The arrows indicate coincident concentration
of tac immunoreactivity with C6-NBD-ceramide in the transfected cells.
(C) Expressed tac-gIcd+tm is concentrated in the TGN
(arrow). (D to F) Expressed tac-gI4 (D),
tac-gI5 (E), and tac-gI6 (F) (which lack,
respectively, the 17, 19, and 36 C-terminal amino acids of the
endodomain of gIwt and thus the critical T338)
are concentrated in cytoplasmic vesicles but not in the TGN. Although
these vesicles are often numerous in the Golgi region of transfected
cells (D), the immunofluorescence is not distinctly localized to the
TGN itself (compare D [vesicles] with C [TGN]). (G and H)
Transfected cells were incubated with Lysotracker in order to determine
whether the expressed mutant construct enters the endosomal pathway. A
coincident localization of tac immunoreactivity and Lysotracker
fluorescence was found in many of the cytoplasmic vesicles of
transfected cells expressing tac-gI4 (arrows). Similar
results were obtained with tac-gI5 and
tac-gI6 (not illustrated). These observations suggest
that chimeric proteins in which the tac ectodomain is fused to the
transmembrane and elements of the endodomain of gI that lack
T338 gain access to the endosomal pathway. Bars, 10 µm.
|
|
Mutations were made in the endodomains of the tac-gIcd+tm
construct so that the resulting mutations corresponded to those in the
endodomain of gI illustrated in Fig. 2 that were used to investigate gI
sorting. Mutations that eliminated the threonine corresponding to
T338 of gI all abolished the TGN targeting of the tac-gI
proteins expressed by transfected cells (Fig. 7D to F). The expressed
chimeric proteins, however, did not remain in the RER, as did the gI
mutants. Instead, the chimeric proteins lacking T338 became
concentrated in large cytoplasmic vacuoles. This localization is
identical to that of fusion proteins expressed by cells transfected with constructs encoding the ectodomain of tac fused to the endodomain of gE from which the TGN targeting signal was deleted (46). Thus, constructs that contain the cytosolic domain of gI, which lack
T338, are not targeted to the TGN even if they escape from
the RER.
Lysotracker was used to determine whether the vacuoles containing the
expressed tac-gI proteins lacking T338 were endosomes (Fig.
7G and H). Coincident localization was found in vesicles between the
fluorescence of Lysotracker and that due to tac immunoreactivity. This
observation suggests that gI-tac chimeric proteins lacking
T338 are sorted to endosomes. The inclusion of
T338 evidently prevents the chimeric proteins from leaving
the TGN in endosomes.
Plasmalemmal gI does not recycle to the TGN.
The targeting of
gE to the TGN involves its endocytotic retrieval from the plasma
membrane and subsequent transport in endosomes (2, 45) (Fig.
8). This transport depends on a
tyrosine-containing sequence (AYRV) and a patch of acidic amino acids
containing a casein kinase II phosphorylation site in the endodomain of
gE. Identical determinants cannot be recognized in the endodomain of
gI. Experiments were thus carried out to compare the transport of gI to
the TGN with that of gE. Transfected cells expressing gI were
incubated, while alive, with polyclonal antibodies to gI. These
antibodies can bind to the exposed extracellular domains of
plasmalemmal gI, but the antibodies cannot permeate the plasma membrane. Internalization of the polyclonal antibodies to gI thus requires uptake by endocytosis. The incubated cells were fixed, permeabilized, and immunostained with monoclonal antibodies to gI. In
contrast to the polyclonal antibodies to gI, which had access only to
gI at the cell surface, the monoclonal antibodies, which were applied
to cells after fixation and permeabilization, had access to the entire
universe of gI molecules within the cells. By determining the location
of the polyclonal antibodies following incubation, the endocytic uptake
of gI from the cell surface could be analyzed (Fig. 8). Double labeling
with species-specific secondary antibodies enabled gI molecules labeled
with polyclonal and monoclonal antibodies to be distinguished from one
another. Examination of immunofluorescence by both standard and
laser-scanning confocal microscopy ensured that internal and
plasmalemmal immunoreactivity could be distinguished (Fig.
9). The design of the experiments thus
made it possible to determine whether a proportion of the gI molecules
at any given site of gI concentration within the cells were exposed at
the cell surface during the period of incubation with polyclonal
antibodies to gI.
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FIG. 8.
Diagram depicting the labeling of expressed gE and gI at
the surface of living cells with antibodies in order to test the
hypothesis that their concentration in the TGN depends on retrieval
from the plasma membrane. (Top) Transfected cells expressing gE (left)
or gI (right) are incubated while alive with antibodies that react with
the ectodomains of the molecules. Antibodies to gE are internalized,
while antibodies to gI are not. The internalized gE is routed to the
TGN. In contrast, no antibodies to gI are found in the TGN of
transfected cells. (Bottom) Surviving cells are incubated with
polyclonal antibodies to gI to label the gp at the cell surface.
Following fixation and permeabilization, however, the cells are doubly
immunostained with monoclonal antibodies to gI. Species-specific
secondary antibodies labeled with contrasting fluorophores thus make it
possible to recognize sites reached by molecules of gI that were at the
cell surface during the period of incubation with polyclonal antibodies
from the total universe of intracellular gI. Polyclonal antibodies to
gI label only molecules at the cell surface. The concentration of gI
within the TGN is labeled only with monoclonal antibodies. These
experiments reveal that expressed gE and gI both reach the cell surface
but that gE is retrieved by endocytosis while gI is not. Despite the
failure to be retrieved from the plasma membrane, molecules of gI still
concentrate in the TGN. These molecules of gI do not recycle to the
cell surface. Micrographs illustrating these observations are shown in
Fig. 9.
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FIG. 9.
Expressed gI is found at the cell surface and in the TGN
but does not reach the TGN by retrieval from the plasma membrane. (A
and C) When surviving cells that express gI are incubated with
polyclonal antibodies that react with gI, the immunoreactivity is not
internalized but remains at the cell surface. The cell surface
restriction of immunoreactivity is apparent in both optical sections
through the cells by laser-scanning confocal microscopy (A) and in
images of whole cells examined by conventional vertical fluorescence
microscopy (C). (B and D) Examination of fixed and permeabilized cells
with monoclonal antibodies that react with gI reveals that gI is
present in the TGN as well as at the cell surface. The gI in the TGN
evidently does not cycle to and from the plasma membrane. The presence
of gI immunoreactivity in the TGN is often made clear when cells
are optically sectioned by laser-scanning confocal microscopy (B),
which readily distinguishes internal fluorescence from signal
originating at the cell surface. Still, unless cells are very flat, the
fluorescence of the gI immunoreactivity in the TGN can be distinguished
through that of the overlying cell surface (D). The same cells are
imaged to show polyclonal immunoreactivity in A and B and monoclonal
immunoreactivity in C and D. Bars, 10 µm.
|
|
Labeling of gI by polyclonal antibodies was seen only at the cell
surface (Fig. 8A and C). The polyclonal antibodies to gI were thus not
internalized to a significant degree within the 30-min period of
incubation. In contrast, after fixation and permeabilization, monoclonal antibodies were found to label gI both at the cell surface
and at internal sites (Fig. 8B and D). The cytoplasmic immunostaining
was concentrated in the TGN, within which labeling by the polyclonal
antibodies was never detected. These observations indicate that
although gI is targeted to the TGN, it is not routed to this structure
by retrieval from the plasma membrane. The targeting mechanism that
directs gI to the TGN must therefore be different from that which
directs gE (Fig. 8), which does reach the TGN following retrieval from
the plasma membrane (2, 45).
Complex results were obtained when gE and gI were expressed
simultaneously in the same cell following cotransfection of the respective cDNAs. Again, cells were preincubated with polyclonal antibodies to gI, but in this case, after fixation and permeabilization they were immunostained with monoclonal antibodies to gE. Three different outcomes were observed. In 27% (16 of 60) of cotransfected cells, there was a coincident localization in the TGN of polyclonal antibodies to gI with gE immunoreactivity (Fig.
10A and B). These cells evidently retrieved gI together with gE from the plasma membrane
and targeted the gI-gE complex, like gE, to the TGN. In 18% (11 of 60)
of cotransfected cells, neither gI nor gE immunoreactivity was found in
the TGN, but both were intense at the plasma membrane (Fig. 10C and D).
These data suggest that the gI-gE complex can be targeted in some cells
more like gI than like gE. IN the third and most common, 55% (33 of
60), type of cell, gI immunoreactivity remained localized at the plasma
membrane, but gE immunoreactivity was prominent in the TGN (Fig. 10E
and F). In these cells, a gI-gE complex either did not form or was
split, enabling the two gps to be targeted independently. As a control,
cells were incubated for 30 min with rabbit polyclonal antibodies
directed against gE instead of gI and subsequently immunostained after
fixation and permeabilization with monoclonal antibodies to gI. When
this was done, gI immunoreactivity was found in the TGN, where it
colocalized with internalized anti-gE (Fig. 10G and H). Plasma membrane
immunostaining of gI, which varies in intensity, is apparent in these
cells; very little anti-gE can be detected on the plasma membrane.
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FIG. 10.
Intracellular trafficking of gI and gE may be
influenced by the co-expressed protein in co-transfected cells. In
order to follow the trafficking of gps from the cell surface,
cotransfected cells were incubated while alive with antibodies to gI.
The cells were then fixed, permeabilized, and immunostained to
demonstrate gE. This experiment thus locates the entire universe of gE
but only the gI that was exposed at the cell surface during the time
the surviving cells were incubated with antibodies to gI. Three
outcomes were observed. (A and B) Surface-labeled gI (A) is colocalized
with gE (B) in the TGN. The coexpression of gE has thus led to the
internalization of gI and its retrieval to the TGN (compare with the
trafficking of gI expressed by itself in Fig. 9). (C and D) Both
surface-labeled gI (C) and gE immunoreactivities are confined to the
cell surface. There is no apparent internalization of gE and no
labeling of either gp in the TGN. The coexpressed gI evidently
interfered with the internalization and trafficking of gE to the TGN.
(E and F) Surface-labeled gI remains at the cell surface (E), but gE is
concentrated in the TGN (F). Despite the known ability of gI and gE to
form a complex, the two gps evidently can, in some cotransfected cells,
traffic independently. Note the resemblance of the localization of
surface-labeled gI in these cotransfected cells to that of
surface-labeled gI in transfected cells that express only this gp (Fig.
9). Bars, 10 µm.
|
|
| |
DISCUSSION |
Observations made in the current study suggest that Cos-7 cells
target gI to the TGN as well as to the cell surface. Thus, the
intracellular location of expressed gIwt was found to be
coincident with that of the TGN markers AP-1 and C6-NBD-ceramide and
was also identical to that of expressed gE, which is known to be
targeted to the TGN (2, 45, 46). The information that causes
gI to be targeted to the TGN must therefore reside in a sequence within
its primary structure, since the transfected cells express no other
viral proteins. HeLa cells, which do not sort gI to the TGN
(1), may lack the ability to either recognize or respond to
the TGN signaling domain of gI. Three types of evidence suggested that
the endodomain is the region that contains the targeting information
that directs gI to the TGN when gI is expressed as an integral membrane
protein. (i) When the gI endodomain was deleted, intact transmembrane
and ectodomains were not able to direct expressed protein to the TGN.
(ii) Chimeric proteins consisting of the tac ectodomain fused to the
transmembrane and endodomains of gI were targeted to the TGN. (iii)
Specific mutations of the endodomains of gI or tac-gI chimeric
constructs prevented expressed proteins from being sorted to the TGN.
The mechanism by which Cos-7 cells target expressed gI to the TGN was
found to be substantially different from that used by these cells to
target expressed gE to the same organelle. The endodomain of gI
contains neither the tyrosine-based sequence nor the patch rich in
acidic amino acids in the endodomain that target gE to the TGN (2,
46). An analogous tyrosine-based targeting signal and an acidic
cluster of amino acids are also critical in the trafficking to the TGN
of the resident proteins TGN38 (3, 11, 25-27, 38, 40) and
furin (12, 28, 32, 35). Analysis of mutants revealed that gI
constructs that lacked T338 were not targeted to the
TGN and the TGN targeting of gI constructs was lost when
T338 was mutated to A338, S338, or
D338. Instead of the tyrosine-based signal and cluster of
acidic amino acids that target gE, TGN38, and furin to the TGN, the TGN
targeting of gI thus depends on the T338 residue of its endodomain.
The observation that a threonine residue is critical in the targeting
of gI to the TGN raises the possibility that the responsible signal
involves the phosphorylation of T338 by a serine/threonine
protein kinase. This possibility, however, is not supported by the
observations that neither S nor D is able to substitute for T. S would
be expected to be phosphorylated by a serine/threonine protein kinase,
and D often mimics a constitutively phosphorylated T (5,
33). In addition, the substitution of K341
K342 for E341 E342, which
eliminates a casein kinase II consensus site in the endodomain of gI
that might cause T338 to be phosphorylated, fails to affect
the targeting of gI constructs to the TGN. If the viral
serine/threonine protein kinases (ORF47 and ORF66) phosphorylate serine
as well as threonine, then the failure of S and D to substitute for T
would also argue against the participation of viral serine/threonine
protein kinases in the TGN targeting of gI. Since the basic
R340 can also be mutated to an acidic E340,
T338 is unlikely to be a component of a signal sequence
that extends beyond this residue toward the C-terminal end of the
molecule. The efficient trafficking of the resident protein TGN38 from
endosomes to the TGN requires a free hydroxyl group in the amino acid
at position 331 of its endodomain, which, in contrast to the critical T338 of gI, can be provided by either S or T
(27). As is also true of the T338 of gI, the
critical S/T331 of TGN38 cannot be replaced by D. The
observation that an S/T residue is involved in its targeting has been
taken to support the idea that TGN38 undergoes a signal-mediated step
in its passage from endosomes to the TGN. TGN38 (3, 11, 25-27,
38, 40), furin (28, 32, 35), and gE (1, 22,
46) are all targeted to the TGN following their endocytic
retrieval from the plasma membrane. T/S331 is important in
the intracellular trafficking of TGN38 because it is necessary for the
linkage of TGN38 because to the actin cytoskeleton via neurabin F-actin
binding proteins (31). Neither previous studies in HeLa
cells (1, 19) nor the current observations, however, suggest
that the endocytic retrieval of gI, in the absence of coexpressed gE,
directs membrane-anchored gI to the TGN. There is thus reason to
suspect that mechanisms analogous to those that regulate the
trafficking of TGN38, furin, or gE from endosomes to the TGN might not
be operative in the TGN targeting of gI.
In contrast to gE, expressed gI, labeled in living cells at the cell
surface with antibodies, did not appear in the TGN. In some cells, the
coexpression of gE and gI was found to cause surface-labeled gI to be
retrieved to the TGN. This phenomenon, which has also been observed in
prior studies (1, 19), is likely to be due to the formation
of a gE-gI complex. Because it is bound to gE, the surface-labeled gI
is internalized with it and follows the internal itinerary of its gE
partner. In other cells, however, both gE and the surface-labeled gI
remained at the plasma membrane; neither appeared in the TGN. This
phenomenon is also consistent with the formation of a gE-gI complex.
The internalization of gE may be prevented by its binding to gI, which
is retained in the plasma membrane. In a final group of cells gE was
targeted normally to the TGN, while in the same cells, surface-labeled gI remained in the plasma membrane; the gE-gI complex thus either did
not form or was not stable, enabling the two gps to traffic independently.
The TGN is a region of the cell where sorting of membrane and soluble
proteins into different transport vesicles normally occurs
(34). These proteins leave the TGN in a constitutive pathway
of vesicles bound for the cell surface, in a regulated pathway of
secretory vesicles, and in vesicles of the endosomal pathway. Proteins
that contain Man 6-P residues bind to MPRs and become diverted to the
endosomal vesicles, which are clathrin-coated as they form in the TGN
(16). TGN38, furin, and gE therefore have to be sorted in
the TGN to vesicles of the constitutive pathway for delivery and
insertion into the plasma membrane before these proteins can be
internalized by endocytosis and retrieved by the TGN from endosomes. An
alternative mechanism by which gI might become concentrated in
the TGN without retrieval from the plasma membrane would be to prevent
a portion of the newly synthesized gI that enters the TGN from the
Golgi stacks from exiting the TGN via the constitutive pathway
(24). Such a TGN retention mechanism has indeed been found
to occur in targeting a resident protein (vacuolar alkaline
phosphatase) to the TGN of the yeast Saccharomyces
cerevisiae (4). In this case, one signal slows the rate
of exit from the TGN and a second targeting sequence directs retrieval
from a post-Golgi compartment. Since gIwt is not retrieved
from the plasma membrane when it is expressed alone, it seems likely
that the TGN targeting of gIwt is due to its retention in
the organelle, a process for which T338 is evidently
essential. In view of the fact that a gE-gI complex forms in the RER of
infected cells, the retention signal of gI and the retrieval signal of
gE probably function synergistically. The presence of
T338 in gI may help to retain the gE-gI complex in the
TGN, while the tyrosine-based motif and acidic amino acids in gE
help to retrieve the complex from the plasma membrane. The synergism
would be expected to ensure that both gps are well concentrated in the TGN, enabling proper viral envelopment to take place. Similarly, the
presence of gI in the gE-gI complex may slow the internalization of gE
at the plasma membrane so that gE and gI can function in mediating
cell-cell fusion (18) and the display of Fc receptors (17, 19-22, 43).
Conversion of gI from a membrane to a soluble protein by eliminating
its transmembrane domain had a surprising effect on the intracellular
localization of the expressed protein. An analogous truncated form of
gE, which lacks transmembrane and endodomains, is also partially
secreted, but mainly remains in the RER (45). Mutant forms
of gI that lacked either the entire endodomain or its T338
residue also appeared to be retained in the RER. The further elimination of the transmembrane domain of gI, however, caused the
mutant proteins to concentrate in the TGN region of transfected cells
and to reach cytoplasmic vesicles, which were found (with the probe
Lysotracker) to be endosomes. The ectodomain of gI thus appears better
equipped than that of gE to be transported out of the lumen of the RER
to reach the Golgi apparatus and TGN. Within the Golgi/TGN, the soluble
ectodomain of gI could, in theory, be sorted either to secretory
vesicles (of constitutive or regulated pathways) or to endosomes.
Transport to endosomes might cause the expressed gI ectodomain to
concentrate in the TGN region because of the cycling of endosomal
vesicles to and from the TGN. Alternatively, the gI ectodomain could
reach endosomes if it were secreted and subsequently taken up by
endocytosis. Since the ectodomain of gI contains Man 6-P groups
(7), its diversion within the TGN to the endosomal pathway
(15, 16, 34) and its uptake by receptor-mediated endocytosis
(37, 44) would both be anticipated results. The observations
that gI immunoreactivity appeared in the TGN of nontransfected cells
exposed to cell-free medium conditioned by cells expressing the gI
ectodomain and that concentration was antagonized by adding Man 6-P to
the medium support the idea that soluble gI is secreted and taken up by
endocytosis. Exogenous Man 6-P would not be expected to enter cells and
interfere with the sorting of molecules within the TGN. In any case,
these observations indicate that T338 and the endodomain of
gI are only necessary for the TGN targeting of gI when it is an
integral membrane protein.
The efficacy of Man 6-P in preventing the uptake of the secreted
ectodomain of gI is analogous to the similar efficacy of Man 6-P in
preventing infection of target cells by cell-free VZV (7,
8). When a virion becomes attached to the plasma membrane of a
target cell, the ectodomains of the gps in its envelope are apposed to
receptors in the target cell's plasma membrane. As a result, Man 6-P
groups, which are found in the ectodomains of VZV gps, including gI
(7, 8), are positioned so that they can, potentially,
interact with MPRs. It is therefore possible that Man 6-P is able to
prevent both the uptake of the secreted gI ectodomain and the infection
of target cells because it competes with the Man 6-P groups of the
ectodomains of virions for access to MPRs of the plasma membrane. This
hypothesis is supported by the current observations but remains to be confirmed.
| |
ACKNOWLEDGMENTS |
This work was supported by NIH grant AI 12718.
We thank Saul Silverstein for helpful comments on the manuscript.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Pediatrics, Columbia University College of Physicians and Surgeons, 630 West 168th St., New York, NY 10032. Phone: (212) 305-9445. Fax: (212)
342-5218. E-mail: aag1{at}columbia.edu.
Present address: Department of Medicine, Harvard Medical School,
Boston, Mass.
| |
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Journal of Virology, July 2000, p. 6600-6613, Vol. 74, No. 14
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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