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Journal of Virology, March 2000, p. 2855-2866, Vol. 74, No. 6
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Role of the Gag Matrix Domain in Targeting Human
Immunodeficiency Virus Type 1 Assembly
Akira
Ono,1
Jan
M.
Orenstein,2 and
Eric O.
Freed1,*
Laboratory of Molecular Microbiology,
National Institute of Allergy and Infectious Diseases, National
Institutes of Health, Bethesda, Maryland
20892-0460,1 and Department of
Pathology, George Washington University Medical Center, Washington,
D.C. 200372
Received 27 October 1999/Accepted 22 December 1999
 |
ABSTRACT |
Human immunodeficiency virus type 1 (HIV-1) particle formation and
the subsequent initiation of protease-mediated maturation occur
predominantly on the plasma membrane. However, the mechanism by which
HIV-1 assembly is targeted specifically to the plasma membrane versus
intracellular membranes is largely unknown. Previously, we observed
that mutations between residues 84 and 88 of the matrix (MA) domain of
HIV-1 Gag cause a retargeting of virus particle formation to an
intracellular site. In this study, we demonstrate that the mutant virus
assembly occurs in the Golgi or in post-Golgi vesicles. These particles
undergo core condensation in a protease-dependent manner, indicating
that virus maturation can occur not only on the plasma membrane but
also in the Golgi or post-Golgi vesicles. The intracellular assembly of
mutant particles is dependent on Gag myristylation but is not
influenced by p6Gag or envelope glycoprotein expression.
Previous characterization of viral revertants suggested a functional
relationship between the highly basic domain of MA (amino acids 17 to
31) and residues 84 to 88. We now demonstrate that mutations in the
highly basic domain also retarget virus particle formation to the Golgi
or post-Golgi vesicles. Although the basic domain has been implicated in Gag membrane binding, no correlation was observed between the impact
of mutations on membrane binding and Gag targeting, indicating that
these two functions of MA are genetically separable. Plasma membrane
targeting of Gag proteins with mutations in either the basic domain or
between residues 84 and 88 was rescued by coexpression with wild-type
Gag; however, the two groups of MA mutants could not rescue each other.
We propose that the highly basic domain of MA contains a major
determinant of HIV-1 Gag plasma membrane targeting and that mutations
between residues 84 and 88 disrupt plasma membrane targeting through an
effect on the basic domain.
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INTRODUCTION |
Assembly of type C retroviruses and
lentiviruses takes place predominantly at the plasma membrane of
infected cells. This process involves multiple steps mediated by the
viral Gag proteins, which are both necessary and sufficient for the
assembly and release of noninfectious, immature virus-like particles
(VLPs). Retroviral Gag proteins are synthesized as polyprotein
precursors; in the case of human immunodeficiency virus type 1 (HIV-1),
the Gag precursor, Pr55Gag, is composed of matrix (MA),
capsid (CA), nucleocapsid (NC), and p6 domains as well as p2 and p1
spacer peptides (reviewed in reference 12). During
or immediately after virus particle release, Pr55Gag is
cleaved by the viral protease (PR) to generate the mature Gag proteins
p17 (MA), p24 (CA), p7 (NC), and p6. The processing of
Pr55Gag causes a major transformation in virion
morphology; this process, known as maturation, gives rise to
virions with condensed, conical cores characteristic of
infectious HIV-1 virions.
MA plays a key role in several steps in virus replication, including
the binding of Pr55Gag to membrane, the incorporation of
Env glycoproteins into budding virions, and early, postentry events.
The covalent attachment of myristate to the N terminus of the MA domain
of Pr55Gag is crucial for the binding of Gag to membrane
and is thus required for virus assembly (4, 18, 23, 51). A
highly basic region spanning MA residues 17 to 31 has also been
implicated in Gag membrane binding. Structural studies of HIV-1 MA
(28, 42) and MA of other retroviruses (for a review, see
reference 8) have suggested that basic amino acids
in the highly basic domain and at more C-terminal positions form a
positively charged surface that may facilitate binding of Gag to
membrane by promoting an electrostatic interaction with acidic
phospholipids in the inner leaflet of the membrane (42, 70).
In support of this hypothesis, in vitro membrane binding assays
demonstrated that the N-terminal 31 amino acids of MA could confer
membrane binding ability upon otherwise soluble proteins
(70). We observed recently that mutation of a nonbasic
residue within the basic domain increased the binding of Gag to
membrane (33, 34, 45). However, an 11-amino-acid deletion in
the MA basic domain was shown to have no impact on virus particle
production (68) or the binding of MA to membrane (61). Moreover, deletion of large portions of MA, including the basic domain, did not significantly impair virus assembly and
release (36, 54, 63, 64).
In addition to membrane binding, MA has been implicated in the
targeting of virus assembly. Large deletions in HIV-1 MA cause either
promiscuous virus assembly both on the plasma membrane and at
intracellular sites (36, 54, 63) or a redirection of
assembly to intracellular locations (11, 17). Small
deletions and amino acid substitutions in MA can also cause defects in
virus production by inducing intracellular accumulation of Gag
(69) or retargeted VLP assembly (5, 16).
Interestingly, some of these mutations involved basic amino acids
within (69) or C terminal to (5) the highly basic
domain. The relationship between Gag targeting and Gag membrane binding
for these mutants was not determined. Intracellular VLPs observed in
cells expressing large HIV-1 MA deletion mutants displayed an immature
morphology by electron microscopy (EM) (11, 17, 54).
Conversely, redirection of intracisternal A-type particles from the
endoplasmic reticulum (ER) to the plasma membrane reportedly induced
both Gag processing and particle maturation (65). These
observations led to the hypothesis that retroviral Gag processing
and/or virus particle maturation can occur only at the plasma membrane.
A role for MA in the targeting of virus assembly is also suggested by
studies in other retroviral systems. Redirection of murine leukemia
virus Gag proteins from the plasma membrane to intracellular
compartments was observed for several mutants (27, 31, 60),
including some with amino acid substitutions in the highly basic domain of murine leukemia virus MA (60). In the case of the type D Mason-Pfizer monkey virus, it was demonstrated that a single amino acid
substitution in a cytoplasmic targeting/retention signal redirects
virus assembly from the cytosol to the plasma membrane (7,
56).
In an effort to characterize the role of MA in HIV-1 replication and to
map functional domains within this protein, we have previously used
site-directed mutagenesis to introduce over 80 single and double amino
acid substitutions in MA and have analyzed the effects on a variety of
aspects of the virus life cycle (for a review, see reference
12). Most of the mutants showed wild-type (WT)
levels of virus assembly and release, but substantial defects in virus
production were caused by mutations in several domains. For example,
mutations between MA amino acids 84 and 88 caused a reduction in
extracellular virus release due to retargeting of virus assembly to an
intracellular compartment (16). MA amino acids 84 to 88 are
located within a central buried helix within the globular core of the
protein (42). In clear contrast to the phenotype observed
for large MA deletion mutants (11, 17, 54), the VLPs which
assembled intracellularly contained condensed cores (16).
The defective phenotype of one of these mutants was reversed by
second-site compensatory changes in MA which arose naturally in
infected T-cell line cultures (46). Interestingly, one such
second-site mutation was located within the highly basic domain,
suggesting a functional relationship between the basic domain and amino
acids 84 to 88. Consistent with this interpretation, we have observed
that single and double amino acid substitutions in the basic domain
caused reductions in extracellular virus production (13).
To understand further the mechanism by which virus formation is
targeted to the plasma membrane, we performed a detailed study of MA
mutants with amino acid changes in the highly basic domain and between
residues 84 and 88. We focused on three aspects of targeting: (i) the
connection between virus maturation and the site of assembly, (ii) the
nature of the targeting signal in MA, and (iii) the relationship
between Gag targeting and membrane binding. EM and confocal microscopy
data demonstrate that Gag processing and virus maturation can occur not
only on the plasma membrane but also in the Golgi or Golgi-derived
vesicles. We provide evidence that the basic domain functions as a
plasma membrane targeting signal independent of its potential
involvement in Gag membrane binding. Furthermore, we show that the
plasma membrane targeting signal can be provided to mutant Gag proteins
in trans by coexpression with WT Gag.
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MATERIALS AND METHODS |
Cell culture and transfection.
HeLa cells were maintained as
previously described (14). Transfection of HeLa cells was
performed by the calcium phosphate precipitation method as reported
previously (16).
Plasmids, mutagenesis, and DNA cloning.
Construction of
derivatives of the HIV-1 proviral molecular clone pNL4-3 (1)
containing MA amino acid changes 1GA, 85YG, and 87VE, as well as the
double mutation 29KT/31KT, has been described previously (13,
16). The pNL4-3 derivatives pNL4-3/PR
, which
contains a protease (PR) active site mutation (Asp
Asn change at PR
amino acid 25), and pNL4-3/p6, which contains a stop
codon at p6 amino acid 1, have been described previously
(30). The pNL4-3 derivative pNL4-3/KFS has been reported previously (15); this clone contains a frameshift mutation
at nucleotide (nt) 6343, which eliminates Env expression.
Double mutations 1GA/85YG, 18IK/20LK, 18IE/20LE, and 29KE/31KE were
introduced into pNL4-3 by oligonucleotide-directed mutagenesis using
methods detailed previously (16). Molecular clones
expressing Pr55Gag tagged with hemagglutinin (HA) or FLAG
epitopes (pNL4-3-55HA and pNL4-3-55FLAG, respectively) were constructed
as follows. (i) A molecular clone (pNL4-3/55X) was made by substituting
the Pr55Gag stop codon with a sequence encoding the
XbaI restriction site. This was accomplished by
oligonucleotide-directed mutagenesis with an M13mp18 subclone harboring
the 1.4-kbp SphI-PstI fragment from pNL4-3 (nt
1443 to 2839) as a template and oligonucleotide 5'-GTCACAATCTAGATAGGG-3'. (ii) Short oligonucleotide
duplexes (for HA, 5'-CTAGCTACCCATACGATGTTCCAGATTACGCTTAG-3'
hybridized to 5'-CTAGCTAAGCGTAATCTGGAACATCGTATGGGTAG-3';
for FLAG, 5'-CTAGCGATTATAAAGACGATGACGACAAGTAG-3' hybridized to 5'-CTAGCTACTTGTCGTCATCGTCTTTATAATCG-3')
encoding the HA (YPYDVPDYA) and FLAG (DYKDDDDK) epitope
sequences, respectively, followed by stop codons, were inserted
into the XbaI site of pNL4-3/55X. These insertions also
introduce stop codons in the pol coding region so that
no pol-encoded viral enzymes are expressed.
PR
, p6
, 55HA, and 55FLAG versions of MA
mutant molecular clones were constructed by introducing the
SphI-
EcoRI fragments (nt
1443 to 5743) from
pNL4-3/PR
, pNL4-3/p6
, pNL4-3-55HA, and
pNL4-3-55FLAG, respectively, into MA mutant
pNL4-3
derivatives.
Antibodies and reagents.
The following reagents were
obtained from the indicated sources: mouse monoclonal antibody which
recognizes p17 (MA) but not Pr55Gag, Advanced
Biotechnologies (Columbia, Md.); mouse monoclonal antibodies which
recognize both Pr55Gag and p17 (MA), Cellular Products
(Buffalo, N.Y.) and Capricorn Products (Scarborough, Maine); rabbit
polyclonal anti-calreticulin antibody, Affinity Bioreagents (Golden,
Colo.); rabbit polyclonal anti-Rab1B and anti-HA antibodies, Zymed
Laboratories (South San Francisco, Calif.); rabbit anti-FLAG antibody
(OctA-Probe), Santa Cruz Biotechnology (Santa Cruz, Calif.); AIDS
patient sera, the National Institutes of Health AIDS Research and
Reference Reagent Program (catalog no. 1983 and 1984); anti-human
immunoglobulin and anti-rabbit immunoglobulin antibodies conjugated
with horseradish peroxidase, Amersham; Texas red-conjugated anti-mouse
immunoglobulin G antibody and fluorescein isothiocyanate
(FITC)-conjugated anti-rabbit immunoglobulin G antibody, Jackson
Immunoresearch Laboratories (West Glove, Pa.); FITC-labeled
Ricinus communis agglutinin 60 (RCA60), Sigma; and
fluorescein-conjugated wheat germ agglutinin (WGA), Molecular Probes
(Eugene, Oreg.).
Metabolic labeling, immunoprecipitation, and Western
blotting.
Metabolic labeling of transfected HeLa cells with
[35S]Cys was performed as previously described
(16). Preparation of cell lysates, pelleting of virions in
the ultracentrifuge, and immunoprecipitation of cell- and
virion-associated proteins with AIDS patient sera have been detailed
previously (16, 66). Cell and virion lysates prepared from
nonlabeled, transfected HeLa cells were analyzed by Western blotting as
previously described (33).
Membrane binding assay.
Equilibrium flotation centrifugation
was performed as detailed previously (45). Briefly, HeLa
cells were collected in phosphate-buffered saline (PBS), washed once
with 10 mM Tris-HCl (pH 7.5) containing 1 mM EDTA and 1 mM EGTA, and
resuspended in 10 mM Tris-HCl containing 1 mM EDTA, 6% (wt/vol)
sucrose, and Complete protease inhibitor cocktail. Postnuclear
supernatants obtained after sonication of cell suspensions were mixed
with 85.5% (wt/vol) sucrose in Tris-EDTA (TE) and placed on the bottom
of a centrifuge tube. On top of this postnuclear supernatant-containing
73% (wt/vol) sucrose mixture was layered TE containing 65% (wt/vol)
sucrose and 10% (wt/vol) sucrose, respectively. The gradients were
centrifuged at 100,000 × g for 18 h at 4°C in a
Beckman SW41 rotor. Ten fractions were collected from the top of the
centrifuge tube. Fractionated samples were analyzed by Western blotting
as previously described (33). Quantitation of Western
blotting data was performed by densitometry scanning.
EM.
Fixation of cells, preparation of samples and EM were
performed as described previously (16).
Fluorescent staining and confocal microscopy.
Fluorescent
staining of transfected HeLa cells with antibodies and lectins was
performed as described previously (47), with some
modifications. Briefly, cells were grown in chamber slides (Nunc) and
transfected by the calcium phosphate precipitation method as described
above but without glycerol shock. Twenty-four hours later, cells were
washed once with Dulbecco modified Eagle medium supplemented with 5%
fetal bovine serum. After another 24 h, cells were rinsed once
with PBS and fixed with 3.7% formaldehyde in 100 mM sodium phosphate
buffer (pH 7.2) for 20 min at room temperature (r.t.) (all the
procedures were carried out at r.t. unless otherwise noted). After
being washed four times with PBS, cells were permeabilized either with
PBS containing 0.1% Triton X-100 for 2 min at r.t. followed by washing
with PBS three times or with methanol for 4 min at 
20°C followed by
air drying. Subsequently, cells were incubated with 0.1 M glycine in
PBS for 10 min and blocked with 3% bovine serum albumin in PBS
(BSA-PBS) for 30 min. Cells were then incubated with primary antibodies
diluted appropriately in BSA-PBS for 1 h, washed with PBS three
times, and incubated with secondary antibodies appropriately diluted in
BSA-PBS for 30 min. For double staining with FITC-conjugated lectins,
after removal of antibody solution by washing with PBS three times, cells were incubated with respective lectins diluted appropriately in
PBS for 30 min. After being washed with PBS three times, cells were
mounted with Fluoromount G (Virotech International, Rockville, Md.) and
examined with a Zeiss LSM410 laser scanning microscope.
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RESULTS |
Mutations between HIV-1 MA amino acids 84 and 88 redirect
assembly and PR-mediated maturation to intracellular vesicles.
To
determine whether the core condensation observed within intracellularly
assembled VLPs produced by Gag mutants containing substitutions between
MA amino acids 84 and 88 (16) was the result of HIV-1 PR
activity, we constructed double mutants containing either the 85YG or
the 87VE substitution and an inactivating mutation in the PR active
site (PR). As determined previously with this PR mutation
(30, 33, 45), immunoprecipitation analysis confirmed that
the processing of Gag expressed by the
pNL4-3/85YG/PR and pNL4-3/87VE/PR
clones was blocked (data not shown). HeLa cells transfected with pNL4-3, pNL4-3/85YG, pNL4-3/87VE, pNL4-3/85YG/PR,
and pNL4-3/87VE/PR were examined by EM.
pNL4-3-transfected cells showed particles budding exclusively from the
plasma membrane; many of these particles contained condensed cores
(Fig. 1A).
Cells expressing the 85YG and 87VE
mutants contained numerous intracytoplasmic VLPs, many of which
contained condensed cores (Fig. 1B); similar data were obtained for
both 85YG and 87VE mutants (16; data not shown). In
the absence of an active PR (i.e., in cells transfected with pNL4-3/85YG/PR and pNL4-3/87VE/PR) we
detected budding structures and immature VLPs but no particles with
condensed cores (Fig. 1C; data not shown). These results indicate that
core condensation resulting from PR activity can occur at an
intracellular site.
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FIG. 1.
Evaluation of mutant virus targeting and maturation by
EM. HeLa cells transfected with the following molecular clones were
fixed and analyzed by EM 2 days posttransfection. Arrows and arrowheads
indicate VLPs with condensed cores and budding structures,
respectively. (A) WT pNL4-3, showing a cluster of typical mature
particles on the cell surface. Magnification, ×83,520. (B)
pNL4-3/85YG. Magnification, ×72,210. (C) pNL4-3/87VE/PR.
Magnification, ×95,700. (D) pNL4-3KFS/85YG. Magnification,
×89,250. (E) pNL4-3/85YG/p6. Magnification, ×89,250.
(F) pNL4-3/29KE/31KE. Magnification, ×94,600. (G)
pNL4-3/29KT/31KT. Magnification, ×93,500.
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Intracellular assembly, budding, and maturation of mutant virions
require Gag myristylation but are independent of Env and p6.
A
mutation in Mason-Pfizer monkey virus Gag that blocks myristylation
(and hence membrane binding) does not affect assembly itself, but
rather prevents assembled capsids from migrating from the cytosol to
the plasma membrane (55). The HIV-1 MA mutants with changes
between amino acids 84 and 88 analyzed here show clear evidence of
membrane association; however, it is uncertain whether membrane binding
is critical to the observed intracellular assembly. To examine this
issue, we constructed a double mutant which has, in addition to the
85YG mutation, a GlyAla change at MA amino acid 1 (1GA)
(16). This mutation abolishes Pr55Gag
myristylation and severely impairs Gag membrane binding (4, 45,
61, 71). In the presence of the 1GA mutation, no discernible particles were observed, suggesting that assembly of the MA mutants with changes between amino acids 84 and 88 is dependent upon Gag membrane binding.
Interaction between Env and Gag proteins is thought to play a role in
the ER-directed assembly and budding of the spumaretroviruses
(
19,
20), and in several other retroviral systems, including
HIV-1,
Env directs virus budding to the basolateral surface of
polarized
epithelial cells (
39,
40,
49). To explore the
possibility
that Env may play a role in the intracellular budding
of the MA mutants
under study here, we introduced the 85YG mutation
into the
env-minus HIV-1 molecular clone pNL4-3KFS (
15).
EM
analysis of HeLa cells transfected with this molecular clone showed
that the absence of Env did not affect the intracellular assembly,
budding, or subsequent core condensation observed with the
Env-expressing
pNL4-3/85YG clone (compare Fig.
1B and D). Thus, in this
system,
the Env glycoprotein is not involved in the retargeting of
virus
assembly.
The HIV-1 p6
Gag protein functions late in the assembly
process by stimulating particle release from virus-expressing cells
(
22,
30); in some systems, introduction of a stop codon
at p6 amino
acid 1 (p6
) causes an accumulation of
immature particles at the plasma membrane
and a nearly complete block
of virus release (
22,
30). To
investigate whether p6
deletion might likewise result in the accumulation
of immature VLPs at
intracellular membranes, we constructed an
85YG/p6
double
mutant and examined its assembly, budding, and maturation
properties by
EM. Interestingly, p6 mutation did not affect the
85YG phenotype (Fig.
1E), suggesting that neither the apparent
release of 85YG particles
into intracellular vesicles nor the
maturation of these particles
requires a functional
p6.
The 85YG MA mutation redirects assembly to the Golgi complex and/or
Golgi-derived vesicles but not to the ER.
To identify the
intracellular site to which VLP assembly is redirected, we used
confocal microscopy to examine pNL4-3- and pNL4-3/85YG-transfected HeLa
cells stained with several organelle markers as well as anti-Gag
antibodies. Gag was detected with two anti-MA monoclonal antibodies.
One recognizes the mature p17 (MA) but not the MA domain of the
unprocessed Gag precursor Pr55Gag (anti-p17)
(71; A. Ono and E. O. Freed, unpublished
results); this antibody allowed us to specifically detect mature MA
generated upon PR-mediated Gag cleavage. The second antibody recognizes both mature p17 and the MA domain of Pr55Gag (anti-p17/55).
When singly stained with anti-p17 antibody, WT-transfected HeLa cells
showed a punctate staining pattern on the cell surface, whereas in
85YG-transfected cells we observed an accumulation of punctate signal
in the perinuclear region (Fig.
2A and
B). As expected, cells transfected with pNL4-3/PR showed
no signal (data not shown), since the anti-p17 antibody does not bind
unprocessed Gag. When stained with the anti-p17/55 antibody, WT Gag
showed a diffuse cytoplasmic signal in addition to the surface punctate
pattern; 85YG also showed a diffuse cytoplasmic staining superimposed
on the perinuclear localization pattern (Fig. 2C and D). The hazy
staining may represent cytosolic Gag not associated with membrane.
Using the anti-p17/55 antibody, cells transfected with the
PR and 85YG/PR clones displayed a staining
pattern similar to those of WT pNL4-3 and pNL4-3/85YG, respectively
(data not shown).
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FIG. 2.
Accumulation of processed mutant Gag in the Golgi and/or
post-Golgi vesicles. HeLa cells were transfected with WT pNL4-3 (A and
C) or with pNL4-3/85YG (B, D, and E through J) and fixed 2 days
posttransfection. After permeabilization, cells were stained with
either mouse monoclonal anti-p17 antibody (A and B) or mouse monoclonal
anti-p17/55 antibody (C and D) or costained with mouse monoclonal
anti-p17 antibody (E, G, and I) and organelle marker rabbit
anti-calreticulin antibody (F), RCA60 (H), or WGA (J) and analyzed by
confocal microscopy. The same fields are shown for panels E and F, G
and H, and I and J. In panels G and H, some vesicles which show
double staining for both p17 (MA) and RCA60 are indicated with arrows.
Panel I shows 85YG p17 (MA) staining in red and panel J shows WGA
staining in green. An overlay of the p17 (MA) and Golgi staining is
presented in Panel K; red (MA) and green (Golgi) overlap is visualized
as yellow.
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The perinuclear staining of 85YG Gag evident with the anti-p17 antibody
colocalized neither with calreticulin (Fig.
2E and
F), which is an ER
luminal protein (
35,
44), nor with Rab1B
(data not shown),
which localizes to the cytoplasmic surface of
the
ER/
cis-Golgi intermediate compartment and/or
cis-Golgi (
25,
52,
58). In contrast, 85YG p17
(MA) staining substantially
colocalized with the region stained by
fluoroscein-labeled RCA60
(Fig.
2G and H) and WGA (Fig.
2I to K). RCA60
and WGA have been
used as medial/
trans- and
trans-Golgi markers, respectively (
9,
21,
24,
26,
62,
67). These results suggest that VLP
assembly of the 85YG mutant
is retargeted to the medial Golgi,
trans-Golgi, and/or
post-Golgi vesicles but not to the ER. Together
with the EM results,
these observations indicate that core condensation
triggered by
PR-mediated Gag processing can occur in the Golgi
as well as at the
plasma
membrane.
Highly basic region of MA is functionally related to the domain of
MA spanning amino acids 84 to 88.
In a previous report, we
observed that one of the mutants with a single amino acid change
between MA amino acids 84 and 88 (86CS) reverted in culture
(46). A second-site, compensatory mutation (27QK) was
identified in the highly basic domain of MA. These findings prompted us
to examine the possibility that the highly basic domain and the MA
domain spanning amino acids 84 to 88 might be functionally related. We
characterized several basic domain mutants for virus production, Gag
localization, and membrane binding. To assess the impact of changes in
the basic domain, we introduced double amino acid mutations that
altered the charge of this region. Thus, neutral-to-basic (18IK/20LK), neutral-to-acidic (18IE/20LE), basic-to-neutral (29KT/31KT), and basic-to-acidic (29KE/31KE) substitutions were introduced. One of these
mutants (29KT/31KT) was previously shown to cause a threefold reduction
in virus particle production (13). HeLa cells were transfected with pNL4-3 or the basic domain mutants and were
metabolically labeled. Cell- and virion-associated material was
immunoprecipitated with AIDS patient sera and subjected to sodium
dodecyl sulfate-polyacrylamide gel electrophoresis followed
by autoradiography (Fig. 3). The basic
domain changes all caused a decrease in virus particle production, although the severity of this defect varied widely among the mutants. When normalized for cell-associated gp120, the amount of
virion-associated p24 released from cells transfected with
18IK/20LK, 18IE/20LE, 29KT/31KT, and 29KE/31KE mutants was 72, 14, 37, and 7% of the WT amount, respectively. Similar effects on
virus release were also observed by measuring the production of
virion-associated gp120, p66 (RT), or p32 (IN) (data not shown). Levels
of cell-associated Pr55Gag detected by immunoprecipitation
were significantly reduced by several of the basic domain mutations.
This latter observation could be the result of several factors: (i)
reduced immunoreactivity previously described for amino acid 20 substitutions (33) and for other MA mutants (6,
10), (ii) Pr55Gag instability, and (iii) increased
rate of Pr55Gag processing, also observed previously for
residue 20 mutants (33, 34). All of these factors may be
operative, since Western blotting revealed less of a reduction in
Pr55Gag levels than did the immunoprecipitation analysis;
these differences were particularly small but were still present in the
absence of a functional PR (data not shown).
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FIG. 3.
WT and mutant virus production. HeLa cells transfected
with WT pNL4-3 (WT) or its derivatives containing the indicated MA
mutations were metabolically labeled with [35S]Cys.
Virions were pelleted by ultracentrifugation. Cell- and
virion-associated material was immunoprecipitated with AIDS patient
sera and analyzed by sodium dodecyl sulfate-polyacrylamide gel
electrophoresis followed by fluorography. The positions of the Env
precursor gp160, the mature surface Env glycoprotein gp120, the Gag
precursor Pr55Gag, and p24 (CA) are shown.
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HeLa cells transfected with the basic domain mutants were also analyzed
by confocal microscopy following immunostaining with
the anti-p17
antibody. All four double mutants exhibited substantial
amounts of
perinuclear staining (Fig.
4); the extent
of Gag relocalization
correlated with the severity of the defect in
assembly or release
(Fig.
3). Consistent with these confocal microscopy
data, EM analysis
of HeLa cells transfected with these mutants showed
virus budding
into intracellular vesicles (Fig.
1F and G). These
results demonstrate
that, as observed for mutations between MA residues
84 and 88,
alteration of the highly basic domain causes retargeting of
Gag
to intracellular compartments. Costaining for Gag and cellular
markers was performed by confocal microscopy, as described above
for
85YG. Again, mutant Gag colocalized with Golgi and post-Golgi
markers,
but not with the ER-specific calreticulin (data not shown).
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FIG. 4.
Accumulation of processed Gag in the Golgi
and/or post-Golgi vesicles caused by mutations in the MA basic domain.
HeLa cells were transfected with WT pNL4-3 (A), pNL4-3/85YG (B),
pNL4-3/18IK/20LK (C), pNL4-3/18IE/20LE (D), pNL4-3/29KT/31KT (E), or
pNL4-3/29KE/31KE (F). Two days posttransfection, cells were fixed,
permeabilized, stained with monoclonal anti-p17 antibody, and analyzed
by confocal microscopy.
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Retargeting of virus assembly is not caused by altered Gag membrane
binding.
It is possible that an increased affinity for membrane
might induce a promiscuous binding of Gag to intracellular membranes, and, as a consequence, a retargeting of virus assembly. To investigate this possibility, we measured the membrane binding ability of 85YG Gag
by equilibrium flotation centrifugation. This technique separates
membrane-bound Gag from non-membrane-bound Gag complexes, and thus
represents a significant improvement over traditional cell
fractionation approaches. We focused on Pr55Gag membrane
binding by utilizing PR constructs. HeLa cells
transfected with pNL4-3/PR and
pNL4-3/85YG/PR were sonicated, and postnuclear
supernatants of cell homogenates were subjected to equilibrium
flotation centrifugation. Membrane-bound material was recovered in
fractions 3 and 4, whereas non-membrane-bound Gag remained in the
bottom two fractions (45). Consistent with previous studies
performed with HeLa cells (45, 50), approximately 40% of WT
Pr55Gag was recovered in the membrane-bound fraction (Fig.
5A). The nonmyristylated, 1GA mutant
displayed an almost complete block in membrane binding (Fig. 5B). 85YG
mutant Pr55Gag showed a behavior essentially identical to
that of the WT (Fig. 5A), suggesting that the 85YG mutation does not
alter Gag binding to membrane. We emphasize that this assay does not
distinguish between plasma and intracellular membrane binding.
View larger version (48K):
[in this window]
[in a new window]
|
FIG. 5.
Effects of MA mutations on Gag membrane binding. HeLa
cells were transfected with pNL4-3/PR (WT) or its
derivatives containing the indicated MA mutations. Postnuclear
supernatants were prepared and subjected to equilibrium flotation
centrifugation (see Materials and Methods), during which membrane-bound
(memb.-bound) materials float to the interface between 10 and 65%
sucrose (fractions 3 and 4). Pr55Gag detected by Western
blotting is shown. In panel B, the percentage of total
Pr55Gag that is membrane bound is indicated on the right.
|
|
We performed similar equilibrium flotation centrifugation assays to
determine the membrane binding properties of the basic
domain mutants
(Fig.
5B). The two mutants with changes at residues
18 and 20 showed an
increased percentage of membrane-bound Pr55
Gag relative to
WT (18IK/20LK, 76%; 18IE/20LE, 56%). In contrast,
the two mutants
with changes at residues 29 and 31 showed either
unchanged (29KT/31KT,
45%) or decreased (29KE/31KE, 23%) membrane
binding relative to that
of the WT. These results suggest that,
as with the 85YG mutation, the
retargeting of assembly observed
with the basic domain mutants does not
correlate with altered
membrane
binding.
Targeting defect imposed by 29KE/31KE and 85YG mutants can be
reversed by coexpression with WT but not by coexpression with each
other.
To understand further the nature of the targeting signal
affected by the 85YG and basic domain mutants, we asked whether WT Pr55Gag could rescue mutant Gag into extracellular
particles by providing a plasma membrane targeting signal in
trans. To distinguish WT from mutant
Pr55Gag, we constructed molecular clones which
express Pr55Gag containing either HA or FLAG
C-terminal epitope tags. HeLa cells were cotransfected with various
combinations of clones expressing tagged versions of WT and MA mutant
Gag. Cell and virion lysates were analyzed by Western blotting with
rabbit anti-HA or anti-FLAG antiserum. Consistent with our observations
using untagged Pr55Gag, 85YG Gag tagged with the HA or FLAG
epitope produced virion-associated material from transfected HeLa cells
with an efficiency that was markedly reduced relative to that of HA- or
FLAG-tagged WT Gag (Fig. 6, compare lanes
13 and 14 or lanes 16 and 17). When HA-tagged 85YG Gag was coexpressed
with FLAG-tagged WT Gag, the amount of released 85YG Gag increased
substantially (Fig. 6, compare lanes 22 and 14). Similar results were
obtained when FLAG-tagged 85YG and HA-tagged WT Gag were coexpressed
(Fig. 6, compare lanes 19 and 17). Similarly, the release of 29KE/31KE
Gag was also increased when it was coexpressed with WT Gag (Fig. 6,
compare lanes 15 and 23 or lanes 18 and 20). These results indicate
that 85YG and 29KE/31KE mutant Pr55Gag proteins can be
rescued into virions by coexpression with WT Gag and imply that a
plasma membrane targeting signal can be provided to 85YG and 29KE/31KE
Gag by oligomerization with WT Gag.
View larger version (53K):
[in this window]
[in a new window]
|
FIG. 6.
Coexpression of WT and mutant Gag proteins. HeLa cells
were transfected at a ratio of 1:1 with various combinations of
molecular clones expressing WT, 85YG, or 29KE/31KE Gag tagged with
either the HA or the FLAG epitope. Virions were pelleted by
ultracentrifugation. Cell and virion lysates were analyzed by Western
blotting with anti-HA or anti-FLAG antibodies. Epitope-tagged
Pr55Gag is shown.
|
|
The ability of a basic domain substitution (27QK) to reverse the
phenotype of a mutation between MA residues 84 and 88 (86CS)
(
46) suggests that these two domains are in the same
functional
complementation group. To test this hypothesis, we
coexpressed
85YG and 29KE/31KE Gag proteins tagged with either the HA
or the
FLAG epitope and the release of both Gag species was monitored
as above. The results indicated that cells coexpressing 85YG and
29KE/31KE Gag showed no increase in virus-associated Gag release
(Fig.
6, lanes 21 and 24) compared with singly expressing cells
(Fig.
6,
lanes 14, 15, 17, and 18). Thus, both 85YG and 29KE/31KE
changes may
alter the same targeting
signal.
| |
DISCUSSION |
We previously demonstrated that HIV-1 particle assembly can be
retargeted from the plasma membrane to an intracellular site by
introducing single amino acid changes between MA amino acids 84 and 88 (16) (Fig. 1). Interestingly, these particles appeared to
have a mature-particle-like morphology with a condensed core. In this
report, we further characterize the intracellular particles by
demonstrating that the core condensation in intracellular mutant virus
particles is driven by the viral PR (Fig. 1). Confocal microscopy utilizing a monoclonal antibody which specifically recognizes the p17
(MA) Gag cleavage product indicates that the mutant MA colocalizes with
Golgi or post-Golgi markers but not with the ER marker calreticulin
(Fig. 2). Since the majority of HIV-1 PR activity is associated with
Pr55Gag assembly and particle release (32),
these results suggest that these MA mutants undergo VLP formation and
subsequent PR-mediated maturation in the Golgi or post-Golgi vesicles
but not in the ER. It was reported previously that deletion of MA amino
acids 16 to 99 caused intracellular budding of mutant virus in the ER; in contrast to that of our mutants (Fig. 1), the morphology of these
virus particles was exclusively immature (11). Collectively, these results suggest that PR-mediated maturation of HIV-1 can occur
not only at the plasma membrane but also in Golgi or post-Golgi compartments but that perhaps it cannot take place in the ER. However,
we cannot exclude the possibility that the differences in maturation
observed between these studies might relate to the use of different
mutants and cell types.
It has been demonstrated that elimination of p6 or mutation of the
Pro-Thr-Ala-Pro-Pro sequence near the N terminus of p6 causes a defect
late in the budding process (22, 30). As a consequence of
such mutations, large numbers of immature particles are observed to be
tethered to the plasma membrane and virus release is markedly impaired
(22, 30). In the case of the retargeted mutants analyzed
here, however, the lack of p6 affected neither the apparent release of
VLPs into intracellular vesicles nor subsequent core condensation (Fig.
1E). These results indicate that virus assembly and maturation at
intracellular vesicles does not require p6. Likewise, mutational
inactivation of the env gene did not alter intracellular
assembly (Fig. 1D), indicating that this phenomenon is not influenced
by Env glycoprotein expression. This is in contrast to the situation
observed with the intracellular assembly carried out by the
spumaretroviruses; in this system an ER retention signal in the
cytoplasmic tail of the transmembrane Env protein reportedly promotes
ER-directed virus budding (19, 20).
Relationship between Gag membrane binding and targeting.
The
observation that the replication-defective phenotype of a mutant
containing a substitution at MA residue 86 (86CS) could be reversed by
a second-site change in the MA highly basic domain (46)
suggested the existence of a functional relationship between the highly
basic domain and amino acids 84 to 88 (see below). Consistent with this
hypothesis, we demonstrate that mutations in the highly basic domain
and between residues 84 and 88 induce similar phenotypes, i.e., reduced
extracellular virus production due to retargeting of virus assembly to
intracellular vesicles (Fig. 3 and 4). Based on the crystal and nuclear
magnetic resonance structures of the nonmyristylated HIV-1 MA (28,
42) and in vitro membrane binding assays (70) it was
proposed that the highly basic domain, along with basic amino acids in
other regions of MA, forms a positively charged patch that promotes
membrane binding of Gag through electrostatic interaction with acidic
phospholipids in the inner leaflet of membranes (70). Thus,
it was of interest to determine whether membrane binding and plasma
membrane targeting of Gag are interrelated functions of MA. For the
mutants analyzed here, this is not the case; the 85YG mutant displays
WT membrane binding properties despite the fact that its targeting is
markedly affected. Moreover, the basic domain mutations all induce Gag retargeting, yet membrane binding is variably affected: the 18IK/20LK and 18IE/20LE mutations increase membrane binding, the 29KT/31KT mutant
behaves like the WT Gag in flotation assays, and the 29KE/31KE changes
decrease membrane binding. The 20LK mutation described previously
(33) increases membrane binding but does not induce Gag
retargeting (A. Ono and E. O. Freed, unpublished results). Taken
together, these results indicate that the roles of MA in membrane
binding and Gag targeting are genetically separable, although both are
influenced by the basic domain.
It has been suggested that Gag mutants containing large MA deletions
might display an enhanced membrane binding ability as
a result of
increased exposure of the N-terminal myristate moiety
(
54).
This increase in membrane binding could potentially enable
Gag to
override its selectivity for the plasma membrane and cause
a
promiscuous binding of Gag to both intracellular and plasma
membranes.
This model clearly does not apply to the mutants analyzed
here, since,
as discussed above, we observed no direct correlation
between effects
on Gag membrane binding and targeting. In addition,
the intracellular
localization of mutant Pr55
Gag and the site of retargeted
assembly were specific for the Golgi
or post-Golgi vesicles.
Localization of Gag to the ER was not
detected, even though the ER
membrane is the most abundant intracellular
membrane (
41).
These results are most consistent with the idea
that the intracellular
virus assembly observed with the MA mutants
studied here is due not to
promiscuous assembly but rather to
a specific
retargeting.
Possible mechanisms for targeting of virus assembly.
Several
mechanisms could explain the retargeting of MA mutant virus formation.
(i) The substitutions reported here could disrupt a plasma
membrane-targeting signal and reveal a weaker but preexisting Golgi-targeting signal. This model could be operative if WT
Pr55Gag is directly targeted to the plasma membrane after
its synthesis or if it first binds an intracellular membrane prior to
plasma membrane transport. It is unclear why HIV-1 Gag would have
evolved a cryptic Golgi-targeting signal; however, it has been reported that in certain cell types (e.g., primary human macrophages) the Golgi
or post-Golgi vesicles are the primary site of virus assembly (48). Thus, a cryptic Golgi-targeting signal, revealed by
these MA mutations, might be dominant in some cases of natural HIV-1 infection. (ii) The MA mutations described here could create a Golgi-targeting signal. This seems somewhat unlikely given the diversity of changes that lead to the retargeting phenotype. (iii) WT
Pr55Gag may bind a variety of intracellular membranes
during its transport, but assembly may be suppressed until Gag reaches
the plasma membrane. In this case, the MA mutations may alter the
regulation of virus assembly, leading to premature assembly of VLPs in
the Golgi.
Coexpression of WT Gag rescued both 29KE/31KE and 85YG mutant Gag into
extracellular virus particles (Fig.
6), indicating
that the plasma
membrane-targeting signal can be provided in
trans.
This
result, which confirms a similar finding obtained with a
MA basic
domain deletion mutant (
69), suggests that the WT and
mutant
Gag proteins share at least part of their transport pathways,
allowing
them to interact. In cells coexpressing WT and mutant
Pr55
Gag, both Gag proteins may bind an intracellular
membrane, oligomerize,
and then traffic to the plasma membrane.
Alternatively, these
two species may oligomerize with each other in the
cytosol and
then traffic together to the plasma membrane. This latter
possibility
is consistent with reports indicating that HIV-1 Gag can
form
large, non-membrane-bound oligomeric complexes in virus-expressing
cells (
37,
38).
Although WT Gag could efficiently rescue the retargeted mutants into
virus particles, 85YG and 29KE/31KE could not complement
each other
(Fig.
6). It has been reported that two Gag mutants
which belong to
different phenotypic groups can complement each
other when coexpressed
(
29). The lack of complementation observed
here is
consistent with mutations in the MA basic domain and between
amino acid
84 and 88 affecting the same targeting signal. However,
we cannot rule
out the possibility that the 85YG and 29KE/31KE
mutants may be unable
to interact with each other, or that one
may exert a
trans-dominant-negative effect upon the
other.
Structural data obtained for both simian immunodeficiency virus and
HIV-1 MA (
28,
42,
43,
53) suggest that MA amino
acids 84 to
88 are in an
-helical domain located in the center
of the tightly
packed globular core of MA, whereas the highly
basic domain is exposed
on the surface of the molecule. Although
it is not yet established that
the currently available MA structures
reflect the folding of the
myristylated MA domain of Pr55
Gag, it is likely that the
basic domain, rather than amino acids
84 to 88, is directly involved in
plasma membrane targeting. Mutations
between amino acids 84 and 88 may
cause a conformational change
which, in turn, may affect the function
of the basic domain. Alternatively,
mutations in the basic domain and
MA amino acids 84 to 88 may
affect a third domain which directly
promotes Gag trafficking
to the plasma
membrane.
To understand the mechanism by which WT HIV-1 assembly occurs
selectively at the plasma membrane, it is important to identify
not
only the targeting signal in Gag but also the element of the
plasma
membrane to which Gag is transported. It has been suggested
that the
basic residues of the highly basic domain may interact
with acidic
phospholipids on the inner leaflet of the plasma membrane
(
70). However, we observed some retargeting even for a
mutation
which increased the positive charge of the basic domain
(18IK/20LK)
(Fig.
4). Thus, although the putative interaction
between basic
amino acids and acidic phospholipids may promote membrane
binding,
it is unlikely to be responsible for the specificity of Gag
targeting.
Still, it is possible that a certain kind of lipid which
specifically
resides on the plasma membrane may interact with Gag to
direct
plasma membrane targeting. Plasma membrane microdomains, which
consist of specific sets of lipids and proteins, have been the
focus of
much interest in recent years. One such microdomain,
or raft, is rich
in sphingolipids and cholesterol (
3,
59).
Interestingly, the
lipid bilayer of the HIV-1 envelope is reportedly
enriched for
cholesterol and sphingolipids relative to the host
cell plasma membrane
(
2), raising the possibility that rafts
or similar lipid
microdomains might be involved in HIV-1 assembly.
A proteinaceous Gag
receptor could also provide a site on the
plasma membrane to which Gag
is
targeted.
We and others have observed that WT retroviral Gag proteins display a
punctate staining pattern on the surface of Gag-expressing
cells (Fig.
2 and
4) (
27,
31,
57). These sites of intense
Gag
localization presumably represent active centers of virus
assembly.
Characterization of such sites will provide additional
insights into
the mechanism of Gag trafficking and virus
assembly.
| |
ACKNOWLEDGMENTS |
We thank D. Demirov, T. Murakami, and R. Willey for helpful
suggestions and critical review of the manuscript. The following reagent was obtained through the NIH AIDS Research and Reference Reagent Program: HIV-1 patient (neutralizing) serum (from L. Vujcic).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Bldg. 4, Rm.
307, NIAID, NIH, 9000 Rockville Pike, Bethesda, MD 20892-0460. Phone: (301) 402-3215. Fax: (301) 402-0226. E-mail: EFreed{at}nih.gov.
| |
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Journal of Virology, March 2000, p. 2855-2866, Vol. 74, No. 6
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Abstract
Introduction
