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Journal of Virology, January 2000, p. 1051-1056, Vol. 74, No. 2
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Evaluation of VP22 Spread in Tissue
Culture
Neil
Brewis,
Anne
Phelan,
Jeanette
Webb,
Jeff
Drew,
Gill
Elliott, and
Peter
O'Hare*
Marie Curie Research Institute, The Chart,
Oxted, Surrey RH8 0TL, United Kingdom
Received 30 July 1999/Accepted 7 October 1999
 |
ABSTRACT |
We compare methods of detection of intercellular transport of the
herpes simplex virus protein VP22 and of a green fluorescent protein
(GFP)-VP22 fusion protein. Spread of both proteins was observed by
immunofluorescence (IF) using organic fixatives. Spread of both
proteins was also detected by IF after paraformaldehyde (PFA) fixation
and detergent permeabilization, albeit at reduced levels. However,
while spread of GFP-VP22 was observed by examining intrinsic GFP
fluorescence after methanol fixation, little spread was observed after
PFA fixation, suggesting that the levels of the fusion protein in
recipient cells were below the detection limits of
intrinsic-fluorescence or that PFA fixation quenches the fluorescence
of GFP-VP22. We further considered whether elution of VP22 from
methanol-fixed cells and postfixation binding to surrounding cells
contributed to the increased detection of spread observed after
methanol fixation. The results show that while this could occur, it
appeared to be a minor effect not accounting for the observed VP22
cell-to-cell spread in culture.
| |
TEXT |
VP22, the product of the UL49 gene
of herpes simplex virus (8), is a major structural component
of the virion. The protein is 301 residues in length, basic, and
subject to a number of posttranslational modifications including
phosphorylation (7) and nucleotidylylation (2).
We previously reported that VP22 exhibits the unusual property of
transport between cells (5). Transport was observed after
introduction of the VP22 gene by several routes, including transfection
or microinjection of the isolated gene in plasmid constructs or by
infection with a nonreplicating herpesvirus encoding the native VP22
gene. One of the features of transport was that in cells actively
synthesizing the protein, VP22 was located predominantly in the
cytoplasm, where it could be observed in filamentous arrays colocalizing with bundled microtubules (4), while in the
surrounding cells, VP22 was observed mainly in the nucleus, where it
could also be observed colocalizing with chromatin in mitotic cells. A
short C-terminal deletion mutant of VP22 lacking 34 residues was
expressed normally and exhibited unaltered cytoplasmic localization in
the primary cells expressing VP22 but failed to spread to the surrounding cells. Spread of VP22 was also sensitive to treatment of
cells with cytochalasin D (5). In addition, we found that this transport activity was retained in a fusion protein consisting of
VP22 linked to green fluorescent protein (GFP) which behaved essentially like the native protein with respect to expression, localization, and spread (5).
We subsequently reported that trafficking of the GFP-VP22 fusion
protein could not be readily observed in living cells (6), in agreement with the results of Fang and colleagues (9),
but was detected in methanol-fixed cells either by examining intrinsic GFP fluorescence or by immunofluorescence (IF) analysis with anti-GFP antibodies (6). More recently, other laboratories have
observed spread of a VP22-GFP fusion protein in fixed but not living
cells (1), while the spread of VP22-GFP in living cells was
reported by fluorescence-activated cell sorting analysis
(14). Here we compare methods of fixation and detection in
the attempt to reconcile the observations on spread of VP22 and of
GFP-VP22 in live cells. We specifically wished to examine whether
detection of the GFP fusion protein by intrinsic GFP fluorescence was
as sensitive as detection by IF using antibodies, whether the fixation
methods influenced sensitivity, and whether fixation itself contributed to spread. The results indicate that while VP22 spread was observed by
IF following several different fixation methods, the method of fixation
influenced detection. Fixation with organic solvents allowed the most
sensitive detection of spread. We further examined whether any
postfixation extraction of VP22 could account for enhanced detection of
spread in methanol-fixed cells and found evidence for some weak
leaching of the protein from VP22-expressing cells to mock-transfected
cells. However, this effect did not appear to account for the extent of
spread observed in transfected-cell monolayers, which was also observed
in paraformaldehyde (PFA)-fixed cells. As with native VP22, spread of
the GFP-VP22 fusion protein was also detected in PFA-fixed cells but
required a period of rehydration for detection by intrinsic GFP
fluorescence analysis.
To examine spread of VP22 and VP22-GFP fusion proteins, COS-1 cells
(2 × 105 cells) (on glass coverslips in six-well
chambers) were plated in standard culture medium (Dulbecco's modified
minimal essential medium containing 10% newborn calf serum) and
transfected with expression plasmids for VP22 or GFP-VP22 as previously
described (5). For native VP22, plasmids pUL49ep
(10) and pAP85H were used as indicated. These vectors
contain the VP22 gene driven by the cytomegalovirus (CMV)
immediate-early enhancer/promoter and flanked at the C terminus by
different epitope tags; pUL49ep (kindly provided by J. McLauchlan)
contains the CMV UL83 tag, detected by the monoclonal antibody
CMV-018-48151 (Capricorn Products Ltd., Scarborough, Maine), while
pAP85H contains VP22 in the background of the commercial vector
pcDNA1/Amp (Invitrogen), flanked by the tag from the influenza virus
hemagglutinin (HA), enabling detection by the anti-HA monoclonal
antibody (Cambridge Biosciences). pEGFPC1 (Clontech) was the parent
plasmid for the VP22 fusion pGE155 (GFP-VP22) constructed as described
previously (5) except in this case GFP was fused to the N
terminus of VP22.
For analysis by indirect IF, transfected cells (approximately 40 h
after transfection) were rinsed with phosphate-buffered saline (PBS),
fixed in 100% methanol or 100% acetone for 10 min, and then washed in
PBS. Alternatively, cells were fixed in 4% PFA in PBS for 10 min,
washed in PBS, and then permeabilized in PBS containing 0.5% Triton
X-100 (TX-100) for 10 min before a final wash in PBS. The cells were
examined by intrinsic GFP fluorescence where appropriate or processed
for IF with either AGV30, a rabbit anti-VP22 polyclonal antibody
(5), the anti-HA monoclonal antibody, or an anti-GFP
polyclonal antibody (Clontech Laboratories). Secondary antibodies were
fluorescein isothiocyanate (FITC) (Vector Laboratories) conjugated or
tetramethyl rhodamine isocyanate (TRITC) (Sigma) conjugated and used at
the recommended dilutions. Confocal microscopy was performed with a
Zeiss LSM410 system attached to an inverted Axiovert 135 microscope.
Fields were examined by illumination with the 488-nm-wavelength laser
at 1:30 or 1:100 attenuation or with the 543-nm-wavelength laser at 1:3
or 1:10 attenuation, using 63× and 40× objectives.
Fixation methods affect detection of VP22-GFP.
In the first
series of experiments, we examined detection of VP22 spread by IF
analysis using different fixation methods. Plasmids expressing VP22
were transfected into COS-1 cells, and 40 h after transfection,
the cells were fixed with either 100% methanol, 100% acetone, or 4%
PFA followed by permeabilization with 0.5% TX-100. Transfected and
control monolayers were subsequently stained with anti-VP22 polyclonal
antibody. For methanol fixation, the results were as expected from
previous analysis, with cells displaying intense cytoplasmic
fluorescence surrounded by numerous cells with the VP22 protein mainly
in the nucleus (Fig. 1, VP22, MeOH). Very
similar results were obtained with acetone fixation, although we noted
somewhat greater cytoplasmic staining of VP22 together with the nuclear
accumulation in the cells surrounding the intensely staining central
cells (Fig. 1, VP22, acetone). Spread of VP22 was also observed using
PFA fixation and detergent permeabilization (Fig. 1, VP22, PFA), but
generally staining was less intense and fewer positive cells were
observed surrounding the more-intense central cells.
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FIG. 1.
COS-1 cells were transfected with expression vectors for
VP22 (pUL49ep [500 ng]) and GFP-VP22 (pGE155 [200 ng]) or mock
transfected as indicated. Forty hours after transfection, the cells
were fixed as indicated and stained with AGV30 rabbit anti-VP22
antiserum (Mock and VP22) or examined for intrinsic GFP fluorescence
(GFP-VP22) with 63× objective. MeOH, methanol.
|
|
Analysis of the GFP-VP22 fusion protein was assessed by intrinsic GFP
fluorescence without antibody staining. As for native
VP22, we observed
spread of the GFP-VP22 fusion protein (Fig.
1) with either methanol or
acetone fixation, although the increased
cytoplasmic staining after
acetone fixation, seen for native VP22
by anti-VP22 IF analysis, was
not readily apparent for GFP-VP22.
Surprisingly, for PFA fixation,
while spread was clearly detected
for native VP22 by IF, it was not
observed for the GFP-VP22 by
intrinsic GFP fluorescence, with the
fusion protein being detected
in isolated single or double cells (Fig.
1, GFP-VP22).
To explain these results, we considered the possibility that the
GFP-VP22 fusion protein was present in the surrounding cells
but that
the levels were below those required for detection by
intrinsic GFP
fluorescence. Methanol fixation may then result
in concentration or
dequenching of the fluorescence, for example,
by facilitating refolding
of denatured protein, while this would
not have occurred with PFA
fixation and cross-linking. Moreover,
PFA fixation may have somehow
actively quenched the intrinsic
GFP fluorescence of the VP22 fusion
protein. We therefore next
examined localization of the GFP-VP22 fusion
protein in cells
fixed with PFA and permeabilized with detergent, using
anti-GFP
antibody. The results (Fig.
2)
show that the fusion protein could
now be detected not only in the more
intensely staining central
cells but also in surrounding cells where it
appeared mainly nuclear
(Fig.
2a). However, we further noted that after
staining with
anti-GFP antibody, the GFP-VP22 fusion protein could now
be detected
in surrounding cells by intrinsic GFP fluorescence (Fig.
2b),
although detection by IF remained the more sensitive (compare
Fig.
2a and b). This result indicated that a period of rehydration
may
facilitate recovery of GFP fluorescence of the fusion protein
in
surrounding cells. To examine this, transfected cells were
fixed with
PFA and TX-100 as before, incubated in PBS with or
without blocking
serum, and then examined by intrinsic GFP fluorescence.
In the latter
case, foci of cells could now be observed by direct
GFP fluorescence,
with the fusion protein detected in the nuclei
of cells surrounding the
brightly expressing cells (Fig.
2c).
Interestingly, this was not
observed after rehydration in PBS
alone (Fig.
2d). The results are
consistent with the proposal
that intrinsic fluorescence of the fusion
protein may have been
abrogated in recipient cells, and regained by
rehydration and/or
refolding.
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FIG. 2.
COS-1 cells were transfected with the GFP-VP22
expression vector (200 ng), fixed with 4% PFA, permeabilized with
0.5% TX-100, and subsequently stained with anti-GFP antibody followed
by TRITC-coupled secondary antibody. The same field is shown for
anti-GFP IF (a) and intrinsic GFP fluorescence (b). In parallel,
transfected cells were fixed as described above for panels a and b, and
subsequently incubated in PBS plus blocking serum (c) or PBS alone (d).
These panels were examined for intrinsic GFP fluorescence with 40×
objective.
|
|
PFA quenches fluorescence of the GFP fusion protein.
We
further reasoned that if PFA fixation was affecting GFP fluorescence of
the fusion protein, this might be directly demonstrated by testing the
ability of PFA to quench the intrinsic GFP fluorescence that is
otherwise be observed in methanol-fixed cells. Cells transfected with
the GFP-VP22 construct were therefore fixed with methanol as normal,
while parallel coverslips were fixed with PFA immediately after removal
of the methanol. Both coverslips were then examined by direct GFP
fluorescence. Compared to methanol fixation alone (Fig.
3a), methanol fixation followed directly
by PFA fixation (Fig. 3b) resulted in substantial quenching of the
fluorescence in the recipient cells. A period of rehydration before PFA
application resulted in the partial restoration of fluorescence in
recipient cells (Fig. 3c and d). While it is not clearly visible from
Fig. 3a and b, a separate experiment demonstrated that this reduction in fluorescence was also observed in the producer cell population. Thus, cells were transfected on coverslips with grids to enable analysis of identical individual cells at all stages. Images were collected of the live producer cells before fixation. The cells were
then fixed in PFA and imaged immediately or after a period of
rehydration. The results show that the direct fluorescence from the
live producer cell (Fig. 3e) was substantially reduced immediately
after PFA fixation (Fig. 3f), and although recovery of fluorescence was
observed after a period of rehydration in PBS, it was incomplete (Fig.
3g).
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FIG. 3.
COS-1 cells were transfected with the expression vector
for GFP-VP22 (200 ng). Forty hours after transfection, the cells were
fixed with methanol (MeOH) and washed in PBS as normal (a), fixed in
methanol followed immediately by fixation in 4% PFA (b), or fixed in
methanol and rehydrated in PBS for 5 min (5') (c) and 30 min (30') (d)
before fixation in PFA. Cells were then examined for spread of GFP-VP22
by intrinsic GFP fluorescence. In a separate experiment transfected
cells on coverslips with grids were first examined live by intrinsic
fluorescence (e) and then fixed in PFA, and identical cells were
examined immediately (f) or after 15 min of rehydration in PBS (g). The
panel shows typical results. All images were analyzed at the same
attenuation settings.
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|
An explanation consistent with these results taken together is that
spread of the GFP-VP22 fusion protein is not detected
by intrinsic GFP
fluorescence in live recipient cells because
it is below the detection
limit, that PFA fixation and cross-linking
may quench intrinsic
fluorescence of the fusion protein which
can be partially reversed
during rehydration, and that methanol
fixation allows detection more
readily, possibly by dequenching
or renaturation following the
rehydration
step.
Limited leaching of VP22 from fixed cells.
We also considered
a possible alternative explanation to account for both the lower
detection of the spread of native VP22 by IF after PFA versus methanol
fixation and the lack of detection of the spread of GFP-VP22 by
intrinsic GFP fluorescence. Although unlikely, it was possible that
spread appeared greater in methanol-fixed cells due to some
postfixation extraction of VP22 from cells expressing VP2 and
subsequent binding to the fixed surrounding cells. Such a possibility
has also been considered in a recent study examining VP22 localization
by IF in virus-infected cells (12). To examine this
possibility, we designed the following experiment. Immediately prior to
fixation and processing, a square coverslip of transfected cells was
placed directly adjacent to and abutting the edge of a confluent
coverslip of mock-transfected cells. With their edges closely abutted,
any significant leaching of VP22 during processing from the transfected
cells should result in its appearance in the nuclei of naïve
cells on the untransfected control coverslip. The results are shown in
Fig. 4a, where panel 1 shows the
transfected cells, panel 2 shows a typical field in the abutted control
coverslip immediately adjacent to the transfected cells, and panels 3 and 4 show fields from the control coverslip moving progressively inward, away from the transfected cells. All the fields were examined in parallel under the same microscopy conditions and laser attenuation. In panel 1 of Fig. 4a, the typical pattern of VP22 spread was observed
with intensely staining cells surrounded by cells with the protein
present largely in the nucleus. Surprisingly, in panel 2, the
mock-transfected cells immediately adjacent to the transfected cells, a
weak nuclear pattern was observed. Since this pattern gradually
diminished the further the field was from the transfected cells (panels
3 and 4) and was above the background level of mock-transfected cells
processed completely separately, we believe this represents a certain
amount of postfixation extraction of VP22 from the transfected cells to
the adjacent cells. A similar experiment is shown in Fig. 4b, where the
edges of the coverslips, shown by the straight edge of cells, in the
abutted transfected and mock-transfected cells can be clearly seen.
(Note that the cell edges were immediately adjacent during fixation and
processing and were slightly separated only to achieve well-resolved
images during microscopy). Again the results show a level of nuclear
staining and some chromatin association in the abutted mock-transfected
cell coverslip (Fig. 4b, panel 2) which was above the background level
of a control coverslip processed separately (panel 3). However,
compared to the nuclear staining of the cells in the transfected-cell
monolayer, the intensity of staining in the adjacent mock-transfected
cells appeared to be a very minor effect, not accounting for spread in
the transfected-cell monolayer.
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FIG. 4.
COS-1 cells, plated on square coverslips, were
transfected with the expression vector for native VP22 (600 ng). Forty
hours after transfection, the coverslip was transferred to a fresh
culture dish and a coverslip of control, untransfected cells was placed
directly adjacent to it. The abutted coverslips were then fixed with
methanol, washed in PBS, and processed for detection of VP22 by
staining with AGV30. The coverslips remained directly abutted during
all steps of processing. Panel 1 shows a typical field of view of the
edge of the transfected coverslip nearest the abutted coverslip, while
panel 2 shows a typical field of view of the edge of the untransfected
coverslip directly abutting the transfected cells. Panels 3 and 4 are
fields taken progressively towards the center of the untransfected
coverslip, away from the transfected cells. (b) Panels 1 and 2 are as
described above showing the abutted edges of the transfected and
untransfected coverslips, respectively. Panel 3 shows the background
from an untransfected coverslip processed separately.
|
|
In summary, VP22 spread could be observed by IF using any of a series
of standard processing protocols, including PFA fixation.
The
efficiency of spread detected with PFA fixation was lower
than that
assessed with methanol fixation, and we sought to determine
whether
this was due to PFA fixation affecting antibody detection,
for which
there is much precedent, or whether methanol fixation
resulted in some
artificial leaching of VP22 protein from the
cells expressing VP22 to
surrounding cells. While we found evidence
for this, it appeared to be
a minor effect, insufficient to account
for the extent of VP22 spread
seen in transfected-cell monolayers.
Moreover, if spread was accounted
for by such an effect, then
it would also have had to occur in
PFA-fixed, cross-linked cells,
which seems unlikely. Spread of VP22 is
also consistent with the
enhanced biological activity of VP22-p53 and
VP22-TK fusion proteins
(
3,
10). However, particularly in
the case of thymidine kinase
(TK), activity of the fusion protein in
promoting ganciclovir-induced
cell death was much more restricted than
would have been predicted
from the spread observed by IF with methanol
fixation. It may
be that the more limited spread observed by PFA
fixation gives
a more accurate estimate of spread of functional
protein.
With regard to the GFP fusion proteins, the failure to observe the
spread of a GFP-VP22 in living cells may be explained by
the limits of
sensitivity of intrinsic GFP fluorescence, and indeed
there is
precedent for the detection of GFP fusion proteins by
IF when none
could be detected by intrinsic-fluorescence analysis
(
11).
It has been estimated (
13) that even for enhanced GFP,
between 10
5 and 10
6 molecules of GFP may be
required to detect GFP in living cells
with any sensitivity above
background autofluorescence. Protein
turnover together with unfolding
or some form of quenching during
transport of the GFP-VP22 fusion
protein, e.g., related to pH
of cell compartments, may also contribute
to the lack of detection,
and it is possible that in some way fixation
with methanol concentrates
and/or allows refolding or dequenching of
the GFP in the fusion
protein in a way that PFA does not. Therefore, as
for VP22, detection
and localization of certain proteins may not be
accurately reflected
by intrinsic GFP fluorescence of the corresponding
fusion
proteins.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Marie Curie
Research Institute, The Chart, Oxted, Surrey RH8 0TL, United Kingdom.
Phone: 44(0)1883 722306. Fax: 44(0)1883 714375. E-mail:
P.O'Hare{at}mcri.ac.uk.
| |
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Journal of Virology, January 2000, p. 1051-1056, Vol. 74, No. 2
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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