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Journal of Virology, May 1999, p. 4136-4144, Vol. 73, No. 5
0022-538X/99/$04.00+0
Binding of Human Immunodeficiency Virus Type 1 Gag
to Membrane: Role of the Matrix Amino Terminus
Akira
Ono and
Eric O.
Freed*
Laboratory of Molecular Microbiology,
National Institute of Allergy and Infectious Diseases, National
Institutes of Health, Bethesda, Maryland 20892-0460
Received 9 November 1998/Accepted 5 February 1999
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ABSTRACT |
Binding of the human immunodeficiency virus type 1 (HIV-1) Gag
protein precursor, Pr55Gag, to membrane is an indispensable
step in virus assembly. Previously, we reported that a matrix (MA)
residue 6 substitution (6VR) imposed a virus assembly defect similar to
that observed with myristylation-defective mutants, suggesting that the
6VR change impaired membrane binding. Intriguingly, the 6VR mutation
had no effect on Gag myristylation. The defective phenotype imposed
by 6VR was reversed by changes at other positions in MA, including
residue 97. In this study, we use several biochemical methods to
demonstrate that the residue 6 mutation, as well as additional
substitutions in MA amino acids 7 and 8, reduce membrane binding
without affecting N-terminal myristylation. This effect is observed in
the context of Pr55Gag, a truncated Gag containing only MA
and CA, and in MA itself. The membrane binding defect imposed by the
6VR mutation is reversed by second-site changes in MA residues 20 and
97, both of which, when present alone, increase membrane binding to
levels greater than those for the wild type. Both reduced and enhanced
membrane binding imposed by the MA substitutions depend upon the
presence of the N-terminal myristate. The results support the myristyl switch model recently proposed for the regulation of Gag membrane binding, according to which membrane binding is determined by the
degree of exposure or sequestration of the N-terminal myristate moiety.
Alternatively, insertion of the myristate into the lipid bilayer might
be a prerequisite event for the function of other distinct MA-encoded
membrane binding domains.
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INTRODUCTION |
The human immunodeficiency virus
type 1 (HIV-1) Gag polyprotein precursor, like those of other
retroviruses, is sufficient to promote the assembly and release of
immature virus-like particles in the absence of other viral proteins
(for reviews, see references 44 and
46). Retroviral Gag proteins contain several
functional domains critical for efficient virus assembly and release
(for a review, see reference 11). These domains,
which drive Gag membrane binding, Gag-Gag interactions, and late
budding functions, have been referred to as M, I, and L, respectively
(35). During or immediately after virus budding,
Pr55Gag is cleaved by the viral protease (PR) to produce
the mature Gag proteins p17 (MA), p24 (CA), p7 (NC), and p6; this
proteolytic processing triggers a major conformational and
morphological change in the virus particle, leading to core
condensation and virion maturation.
HIV-1 MA has been implicated in both early and late phases of the virus
life cycle. Based on the analysis of MA mutants which display defects
in virus production, MA has been demonstrated to play a major role in
the binding of Pr55Gag to membrane. The observation that
large deletions (10, 17) and single amino acid changes
(16) in MA cause a redirection of assembly to cytoplasmic
compartments indicates that MA plays a role not only in promoting
membrane binding in general but also in the targeting of Gag to the
plasma membrane in particular. Deletions (9, 48, 52) and
single amino acid substitutions (13, 15, 33) in MA can block
HIV-1 envelope glycoprotein incorporation into virus particles, and
HIV-1 MA has been implicated in early events postinfection (for a
review, see reference 11).
During Pr55Gag synthesis, the N-terminal Gly residue of the
MA domain is modified by the covalent attachment of a myristic acid moiety. The importance of N-terminal myristylation in Gag membrane binding and virus assembly has been definitively established (4, 8, 19, 23, 39, 41, 43, 49); however, the contribution of other MA
domains to membrane binding is less well defined. A highly basic
sequence located between HIV-1 MA residues 17 and 31 has been
implicated in Gag membrane binding. It has been proposed that basic
residues within this domain and elsewhere in MA form a positively
charged surface which interacts with negatively charged phospholipids
on the inner face of the lipid bilayer (21, 29, 54, 55).
Data in support of a direct role for MA basic residues in membrane
binding are mixed. A contribution of the basic domain is supported by
mutational (12, 53, 54) and structural (for a review, see
reference 7) data. In contrast, other studies observed that a basic domain deletion actually increased virus production (52), and large deletion mutants lacking all or
most of MA but possessing a myristylation site are competent to produce virus particles in some studies (26, 38, 48).
It has been suggested, based on its relatively low hydrophobicity
compared with other (longer) fatty acids, that myristate is used to
promote the membrane binding of proteins which must interact with
membranes in a reversible manner (45). In the case of the
retinal rod calcium sensor protein recoverin, calcium binding causes a
conformational change that exposes the myristate moiety, which in the
absence of calcium is sequestered within the protein (2).
According to this myristyl switch model, the calcium-triggered exposure
of myristate induces the binding of recoverin to membrane
(2). Based on the observation that Pr55Gag binds
membrane more tightly than MA itself, it has been hypothesized that
cleavage of Pr55Gag might cause a refolding of the MA
domain, a sequestration of the N-terminal myristate, and a reduction in
membrane binding potential (55). This model is supported by
the findings that deletion of portions of MA which may be responsible
for sequestration of myristate increased membrane binding (42,
55).
We previously reported that mutations in the N terminus of HIV-1 MA
induced defects in virus assembly and release (16). Substitutions in the N-terminal five residues blocked or impaired Gag
myristylation (32, 33); intriguingly, however, mutation of
residue 6 from Val to Arg (6VR) caused virus assembly and release defects without affecting Gag myristylation (33). Because of the phenotypic similarities between the 6VR mutation and those affecting N-terminal myristylation (i.e., defective Gag processing and
reduced virus production), we postulated that the 6VR substitution may
impair binding of Gag to membrane (11, 33). Similar
phenotypes were reported for N-terminal mutations in the MA of Moloney
murine leukemia virus (20) and simian immunodeficiency virus
(18). In the latter case, it was proposed that the effect of
the N-terminal MA mutations was attributable to decreased hydrophobicity.
In our previous studies, we observed that the 6VR mutant, which
replicated with markedly delayed kinetics in T cells (16) reverted in culture (33). The revertant viruses maintained
the 6VR mutation but acquired second-site changes at several downstream positions in MA, including residue 97 (97KE). A 6VR/97KE double mutant
displayed a complete reversal of the impaired virus production and
delayed replication kinetics observed with 6VR.
Our goals in this study were severalfold: (i) to determine whether the
domain of HIV-1 MA immediately downstream of the N-myristyl transferase recognition sequence (Gly-X-X-X-Ser/Thr) (45) is involved in Gag membrane binding, (ii) to biochemically characterize the basis for the ability of downstream MA mutations to overcome the
virus assembly and replication defects imposed by the 6VR mutation, and
(iii) to assess the role of Gag sequences downstream of MA on the
membrane binding ability of wild-type and MA-mutant Gag by using assays
which clearly distinguish membrane-bound Gag from assembled or
aggregated complexes. Using three biochemical assays, we demonstrate
that MA residues 6 to 8 play a critical role in membrane binding. This
function is evident in the context of Pr55Gag, a truncated
Gag containing only MA and CA, and MA itself. Mutations in residues 20 and 97 increase binding of Gag to membrane and as a result can reverse
the membrane binding defect caused by the 6VR substitution. The
contribution of MA residue 6 and 20 to membrane binding requires
N-terminal myristylation.
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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 molecular clone pNL4-3 (1)
containing MA amino acid changes 1GA, 4AD, 5SI, 6VR, 20LK, 97KE, and
6VR/97KE has been described previously (16, 33). The pNL4-3
derivative pNL4-3/PR
, which contains a PR active site
mutation (Asp
Asn change at PR amino acid 25), has been described
previously (22). PR versions of MA mutant
molecular clones were constructed by cloning the PR-containing
SphI-EcoRI fragment (nucleotides 1443 to 5743) from pNL4-3/PR into MA-mutant pNL4-3 derivatives.
Substitutions at MA amino acids 7 and 8 (7LV, 7LE, 8SA, and 8SE) and
double mutations 1GA/6VR, 1GA/20LK, and 6VR/20LK were introduced into
pNL4-3 by oligonucleotide-directed mutagenesis by using methods
detailed previously (16). The molecular clone expressing p17
(MA) (pNL4-3/MAstop) was constructed by introducing stop codons at CA
amino acid positions 1 and 2 by the same strategy used for MA
mutagenesis (16). Introduction of 1GA and 6VR changes into
pNL4-3/MAstop was performed as described above by using a 1.6-kbp
StuI-SphI fragment of pNL4-3/MAstop subcloned
into M13mp19 as a template for mutagenesis.
To construct the plasmid pNL4-3/p41stop, which expresses p41 (MA-CA), a
stop codon was introduced at residue 1 of the p2 spacer
peptide.
Oligonucleotide-directed mutagenesis was performed by
using an M13mp18
subclone harboring the
SphI-
PstI (1.4 kbp)
fragment
from pNL4-3 as a template and oligonucleotide
5'-AAGAGTTTTGTAAGAAGCAATGA-3'.
After mutagenesis, the
M13mp18-derived
SphI-
PstI fragment containing
the
stop codon was introduced into pNL4-3 and sequenced in its
entirety.
The same fragment was cloned into pNL4-3/1GA and pNL4-3/6VR
to
generate p41stop versions of these MA
mutants.
Metabolic labeling and immunoprecipitation.
Metabolic
labeling of transfected HeLa cells with either [35S]Cys,
[35S]Met, or [3H]myristic acid was
performed as previously described (14, 15, 33). Preparation
of cell lysates, pelleting of labeled virions in the ultracentrifuge,
and immunoprecipitation of cell- and virion-associated proteins with
sera from patients with AIDS (National Institutes of Health AIDS
Research and Reference Reagent Program, catalog no. 1983 and 1984) have
been detailed previously (15, 50). For immunoprecipitation
of labeled p17 (MA) from fractions of equilibrium flotation
centrifugation assays (see below), 1.2 ml of fractionated samples was
mixed with 0.3 ml of 5× triton lysis buffer (250 mM Tris-HCl [pH
7.5], 2.5% Triton X-100, 1.5 M NaCl, 50 mM iodoacetoamide, 1 mM
phenylmethylsulfonyl fluoride, and 1 mg of leupeptin/ml), and
precleared with recombinant protein G-agarose (GIBCO BRL, Gaithersburg,
Md.). Subsequently, precleared samples were subjected to
immunoprecipitation with mouse monoclonal anti-HIV-1 p17 antibody
(Advanced Biotechnologies, Inc., Columbia, Md.) and immobilized on
protein G-agarose, and precipitated proteins were analyzed as
previously described (50).
Western blotting.
Western blotting of fractionated samples
was performed as previously described (25). The following
primary antibodies were used: sera from patients with AIDS, rabbit
anti-gp41 serum (Fitzgerald Industries International, Inc., Concord,
Mass.), and mouse monoclonal anticalnexin antibody (Affinity
Bioreagent, Inc., Golden, Colo.). Horseradish peroxidase-conjugated
antihuman immunoglobulin (Ig), antirabbit Ig, and antimouse Ig (all
obtained from Amersham) were used as secondary antibodies. Quantitation
of Western blotting data was performed by densitometry scanning.
Membrane binding analyses.
Cell fractionation and
equilibrium sucrose density gradient centrifugation assays were
performed as detailed previously (25) but with some
modifications. Briefly, transfected HeLa cells were rinsed with
ice-cold phosphate-buffered saline and collected by scraping 2 days
posttransfection. Cells were washed once with 10 mM Tris-HCl (pH 7.5)
containing 1 mM EDTA and 1 mM EGTA and suspended in 10 mM Tris-HCl
containing 1 mM EDTA, 6% (wt/vol) sucrose, and Complete protease
inhibitor cocktail (Boehringer Mannheim). Cell suspensions were
subjected to sonication (15 s, twice) in ice water to achieve
disruption of more than 90% of cells. After low-speed centrifugation,
postnuclear supernatants were not adjusted (no salt) or adjusted to 1 M
NaCl (high salt) and centrifuged at 100,000 × g for
1 h in a Beckman SW55Ti rotor. The resulting pellet and
supernatant fractions were subjected to Western blotting as described
above. For equilibrium sucrose density gradient centrifugation,
postnuclear supernatants adjusted to 1 M NaCl as described above were
loaded onto gradients composed of 20, 30, 40, 50, and 60% (wt/vol)
sucrose in 10 mM Tris-HCl (pH 7.5) containing 1 mM EDTA (TE) and
centrifuged at 100,000 × g for 16 h at 4°C in a
Beckman SW55Ti rotor. Eleven fractions (480 µl each) were collected
from the top of the gradients and were subjected to Western blotting analysis.
Our methods for equilibrium flotation centrifugation were modified from
those reported by Spearman et al. (
42). HeLa cells
collected
and washed as described above were resuspended in 10
mM Tris-HCl
containing 1 mM EDTA, 10% (wt/vol) sucrose, and Complete
protease
inhibitor cocktail. Postnuclear supernatants were obtained
after
sonication of cell suspensions as described above. Then,
250 µl of
postnuclear supernatants was mixed with 1.25 ml of 85.5%
(wt/vol)
sucrose in TE and placed on the bottom of a centrifuge
tube. On top of
this postnuclear-supernatant-containing 73% (wt/vol)
sucrose mixture
was layered 7 ml of 65% (wt/vol) sucrose in TE
and 3.25 ml of 10%
(wt/vol) sucrose in TE. The gradients were
centrifuged at
100,000 ×
g for 18 h at 4°C in a Beckman SW41
rotor.
Ten 1.2-ml fractions were collected from the top of the
centrifuge
tube for Western blotting or radioimmunoprecipitation as
described
above. For analysis of p17 (MA), postnuclear supernatants
were
obtained from [
35S]Cys-labeled cells, and fractions
were immunoprecipitated with
anti-p17 antibody as described
above.
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RESULTS |
Mutations near the N terminus of MA impair virus assembly and
release without affecting myristylation.
We previously reported
that the Val-to-Arg substitution at MA amino acid 6 (6VR) markedly
reduced virus assembly and release without affecting Gag myristylation
(33). This finding suggested an unidentified role for
residue 6 in the late stages of the virus life cycle. Since single
amino acid changes at residues 9 (GlyGlu), 10 (GlyArg), and 12 (LeuGlu) had no effect on virus particle production (15, 16,
33), we sought to map the putative N-terminal assembly domain by
determining whether mutation of other residues immediately following
the N-myristyl transferase recognition sequence would affect
virus particle production. Accordingly, we introduced additional single
amino acid mutations in this region as follows: LeuVal and LeuGlu
at amino acid 7 (7LV and 7LE, respectively) and SerAla and SerGlu
at amino acid 8 (8SA and 8SE, respectively) (Fig.
1). Following site-directed mutagenesis,
these changes were introduced into the infectious molecular clone
pNL4-3 (1). HeLa cells were transfected with wild-type or MA
N-terminal mutant molecular clones and were metabolically labeled with
[35S]Cys. Cell and virion lysates were prepared and
subjected to immunoprecipitation analysis (Fig.
2). Consistent with our previous findings
(16, 33), the 1GA, 4AD, 5SI, and 6VR mutations caused a
marked reduction in virion release (Fig. 2, right panel). These mutations also reduced the efficiency of processing of cell-associated Gag and Gag-Pol precursors, as evidenced by the accumulation of Pr55Gag and Pr160Gag-Pol (Fig. 2, left panel).
In addition, all the mutants with amino acid changes at residues 7 and
8 showed significantly reduced virus production (Fig. 2, right panel).
Accumulation of Gag and Gag-Pol precursors in cell-associated material
was also observed with the residue 7 and 8 mutants (Fig. 2, left
panel), indicating a reduced efficiency of Gag precursor processing.
These results suggest that MA amino acid residues 6 to 8 play a role in
virus assembly and release.
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FIG. 1.
HIV-1 MA mutations analyzed for their effect on Gag
membrane binding. At the top is indicated the linear organization of
the Gag precursor Pr55Gag showing MA, CA, NC, and p6
domains. MA mutations were analyzed in the contexts of full-length
Pr55Gag, a truncated Gag containing MA-CA (p41stop), and MA
alone (MAstop). The locations of the five major  -helices in MA (H1
to H5) are indicated; the N terminus of MA and the sequences
surrounding residues 20 and 97 are enlarged. The positions of the
mutations are indicated. Dashes denote sequence identity with wild type
(w.t.). The myristylation consensus sequence is underlined.
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FIG. 2.
Effect of N-terminal MA mutations on Gag processing and
virus production. HeLa cells transfected with wild-type (WT) pNL4-3 or
derivatives containing the indicated MA mutations were metabolically
labeled with [35S]Cys. Virions were pelleted in an
ultracentrifuge. Cell (left panel)- and virion (right panel)-associated
material was immunoprecipitated with sera from patients with AIDS
(Materials and Methods). The relative levels of virion-associated p24
(normalized for cell-associated gp120) are indicated under each lane of
the virion panel. The positions of the Pr160Gag-Pol (Pr160)
and Pr55Gag (Pr55) precursors, the Env precursor gp160, the
mature surface Env glycoprotein gp120, the Gag processing intermediates
p41 and p39, and p24 (CA) and p17 (MA) are shown.
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Mutations which block or impair HIV-1 Gag myristylation have been
reported to disrupt virus assembly and reduce the efficiency
of Gag
processing (
4,
16,
19,
27,
34). We previously
demonstrated
that the 6VR mutation did not impair Gag myristylation
(
33).
However, since mutations at amino acids 7 and 8 are located
close to
the myristylation signal, we next examined whether these
changes
affected Gag myristylation. To eliminate differences in
Pr55
Gag levels resulting from differential rates of Gag
processing observed
with these mutants (Fig.
2), we analyzed the MA
N-terminal mutants
in the context of a PR
molecular clone
(Materials and Methods). HeLa cells transfected
with these mutants were
metabolically labeled with [
35S]Met or
[
3H]myristic acid, and cell-associated material was
immunoprecipitated
(Fig.
3). Consistent
with our previous results (
33), the 1GA
and 4AD mutants
showed no myristylation (1GA) or significantly
impaired myristylation
(4AD), whereas 6VR showed a wild-type level
of
3H
incorporation (Fig.
3). These results confirm that, unlike the
1GA and
4AD mutations, the 6VR change does not affect attachment
of the
N-terminal myristic acid moiety. Gag proteins with single
amino acid
changes at residues 7 and 8 also showed levels of myristylation
at
least as high as wild-type levels (Fig.
3). These results indicate
that
the defects in virus assembly and release caused by the mutations
in MA
residues 6 to 8 are not the result of disrupted Gag myristylation.
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FIG. 3.
Effect of N-terminal MA mutations on Gag myristylation.
HeLa cells were transfected with pNL4-3/PR or derivatives
containing the indicated MA mutations. Cells were metabolically labeled
with either [35S]Met (top panel) or [3H]Myr
(lower panel). Cell lysates were prepared and immunoprecipitated with
sera from patients with AIDS. The Pr55Gag band is shown.
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The N-terminal MA mutants display impaired membrane binding by
several biochemical assays.
Although mutations in MA residues 6 to
8 do not impair myristylation (Fig. 3), the possibility remained that
these changes might disrupt membrane binding. Thus, we next determined
the membrane binding ability of Gag proteins with single amino acid
changes at residues 6, 7, and 8, using several biochemical procedures.
First, we performed cell fractionation assays commonly used to assess
membrane binding (Materials and Methods) (Fig.
4). Approximately
70% of wild-type
Pr55
Gag was distributed in the pellet fraction under both
no-salt and
high-salt conditions. The 1GA mutant showed a marked
decrease
in pelleted Gag compared to that of the wild type. As we
demonstrated
previously (
25), the 20LK change increased the
percentage of
Pr55
Gag in the pellet fraction in the
presence or absence of high-salt
conditions. The 6VR, 7LE, and 8SA
mutations decreased the amount
of pelleted Gag, suggesting that Gag
membrane binding is impaired
by these changes. The transmembrane Env
glycoprotein gp41, which
is found almost exclusively in the pellet,
serves as a fractionation
control.
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FIG. 4.
Cell fractionation of MA-mutant Pr55Gag.
HeLa cells were transfected with pNL4-3/PR or derivatives
containing the indicated MA mutations. Postnuclear supernatants were
treated with no salt (top panel) or high salt (1 M NaCl; lower panel)
and fractionated (Materials and Methods). Pr55Gag and the
transmembrane Env glycoprotein gp41 were detected by Western blotting.
The percentage of Pr55Gag in the pellet fraction,
normalized to the wild-type (WT) value, is indicated under each lane.
Approximately 70% of wild-type Pr55Gag was detected in the
pellet under either no- or high-salt conditions.
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In the cell fractionation approach described above, the pellets likely
contain non-membrane-bound material such as large protein
complexes
(
28), misfolded protein aggregates, and cytoskeleton-bound
protein in addition to authentic membrane-bound material. Thus,
we
cannot definitely assess the extent of Gag membrane binding
by using
this technique. To more accurately separate membrane-bound
Gag from
pelletable but non-membrane-bound material, we next examined
Gag
distribution by equilibrium sucrose density gradient centrifugation
(data not shown). Postnuclear supernatants of transfected HeLa
cells,
prepared as in Fig.
4, were layered onto 20 to 60% (wt/vol)
sucrose
gradients, which were spun at 100,000 ×
g for 16 h. Under
high-salt conditions, most wild-type Pr55
Gag was
recovered in two peaks: the lighter peak, sedimenting to
fractions 1 to
3 (1.06 to 1.10 g/cm
3 density), and the heavier peak,
sedimenting to fractions 6 to
9 (1.15 to 1.20 g/cm
3
density). An internal marker for cellular membranes, gp41, partially
overlapped with the denser Pr55
Gag peak. The 1GA mutant
displayed increased Pr55
Gag in fractions 1 to 3 and reduced
Gag in fractions 6 to 9 compared
to the wild type. These observations
suggested that membrane-bound
Pr55
Gag was recovered mainly
from fractions 6 to 9, whereas cytosolic
Gag was distributed primarily
in fractions 1 to 3. The 6VR mutant
showed a distribution similar to
1GA: a decreased amount of Pr55
Gag in membrane-containing
fractions and an increased amount in cytosolic
fractions compared to
the wild
type.
The fractionation and sucrose gradient results presented above suggest
that mutations in MA residues 6 to 8 decrease the binding
of
Pr55
Gag to membrane. However, we considered it necessary to
assess the
membrane binding of Pr55
Gag in an assay that can
definitively distinguish membrane-bound
Gag from non-membrane-bound
complexes. To this end, we analyzed
the distribution of Gag, using
equilibrium flotation centrifugation.
This approach has been used
successfully to study membrane binding
of the vesicular stomatitis
virus M protein (
3,
5,
6)
and has also been applied to the
analysis of HIV-1 MA membrane
binding (
42). Postnuclear
supernatants from transfected HeLa
cell homogenates were adjusted to
73% (wt/vol) sucrose, placed
at the bottom of centrifuge tubes,
overlaid with 65% (wt/vol)
and 10% (wt/vol) sucrose, and centrifuged
for 18 h at 100,000
×
g (Materials and Methods).
Fractions were collected from the
top of the gradient and were analyzed
by Western blotting with
sera from patients with AIDS or with anti-gp41
antibody. As shown
in Fig.
5, gp41 was recovered almost exclusively in
fractions
3 and 4, which correspond to the boundary between 10 and 65%
sucrose.
The flotation of gp41 to fractions 3 and 4 was eliminated by
treatment
with 1% Triton X-100 prior to ultracentrifugation (data not
shown).
Calnexin, an endoplasmic reticulum-resident transmembrane
protein
(
47), was also recovered predominantly in these
fractions (data
not shown). Consistent with membrane flotation data
obtained by
other investigators (
3,
5,
6,
42), these results
suggest
that most of the plasma membrane, as well as other cellular
membranes,
float to the 10%-65% sucrose interface. Under these
conditions,
35% of wt Pr55
Gag was detected in fractions 3 and 4 (Fig.
5). The flotation of
Pr55
Gag was largely abolished when postnuclear supernatants
were treated
with 1% Triton X-100 (data not shown), indicating that
detergent-resistant
protein complexes that are not membrane bound
(
28) could not
float. The percentage of 1GA
Pr55
Gag that was recovered in fractions 3 and 4, normalized
for the wild
type, was reduced to 2%, while the remainder stayed in
the bottom
fractions (i.e., 0.8% of total 1GA Pr55
Gag was
present in fractions 3 and 4). The 20LK mutant displayed
an increase,
relative to wild type, in the percentage of Gag present
in the floated
fractions. 6VR Pr55
Gag showed a clear reduction in membrane
binding, with a distribution
intermediate between wild type and 1GA.
The amount of 7LE and
8SA Pr55
Gag in the floated fractions
was also reduced relative to wild type.
The 6VR, 7LE, 8SA, and 20LK
mutants showed 5.5%, 23.5%, 19.9%,
and 89.2%, respectively, of
Pr55
Gag in membrane-containing fractions (3 and 4). Similar
data were
obtained for wild-type, 1GA, and 6VR by flotation assays
performed
in the presence of high salt (1 M NaCl) (data not shown).
These
results, together with those obtained by the cell fractionation
and sucrose gradient methods, suggest that the N-terminal amino
acids
immediately following the MA myristylation recognition signal
are
involved in Gag membrane binding.
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FIG. 5.
Analysis of MA mutants by membrane flotation
centrifugation. HeLa cells were transfected with
pNL4-3/PR or derivatives containing the indicated MA
mutations. Postnuclear supernatants were prepared and subjected to
membrane flotation centrifugation (Materials and Methods), during which
membrane-bound material floats to the interface between 10 and 65%
sucrose (fractions 3 and 4). The transmembrane Env glycoprotein gp41,
which is found almost exclusively in fractions 3 and 4, serves as a
control membrane-bound protein. Pr55Gag and gp41 were
detected by Western blotting.
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N-terminal MA mutations reduce membrane binding independently of
the Gag NC domain.
It has been suggested that a sequence located
near the N terminus of NC, which has been referred to as the
interaction, or I, domain (35), is involved in enhancing the
binding of Pr55Gag to membrane (37, 40). It
seemed possible that the impaired membrane binding imposed by mutations
in MA residues 6 to 8 could result from an indirect effect involving
the NC domain, perhaps via a global change in Pr55Gag
conformation which might destabilize the association of Gag with membrane. To examine this possibility, we introduced a stop codon immediately after the CA domain in pNL4-3 to generate the molecular clone pNL4-3/p41stop (Fig. 1). We then introduced several of the MA
mutations described above into pNL4-3/p41stop; this enabled us to
analyze the effects of these mutations on membrane binding in the
context of a p41 (MA-CA) Gag protein. Membrane flotation analysis (Fig.
6A) indicated that 25% of wild-type p41
was recovered in fractions 3 and 4, whereas only 0.6% of 1GA p41 and
4.5% of 6VR p41 was detected in the membrane-containing fractions.
These results indicate that the effect of the MA N-terminal mutations on membrane binding is independent of Gag sequences C terminal to CA,
including the NC domain.
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FIG. 6.
Membrane flotation centrifugation with p41 (MA-CA) and
p17 (MA). HeLa cells were transfected with pNL4-3/p41stop (which
expresses a truncated Gag protein lacking sequences C-terminal to CA;
panel A) or pNL4-3/MAstop (which expresses MA; panel B) or derivatives
containing the 1GA or 6VR MA mutations. Postnuclear supernatants were
prepared and subjected to membrane flotation centrifugation; p41
(MA-CA) was detected by Western blotting, and p17 (MA) was detected by
immunoprecipitation (Materials and Methods).
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To directly compare membrane binding of Pr55
Gag and p41
(MA-CA), we performed the following experiment. Cells expressing
wild-type
Pr55
Gag or p41 were mixed and disrupted by
sonication, and postnuclear
supernatants were subjected to membrane
flotation centrifugation.
We then assessed the levels of
Pr55
Gag and p41 in each fraction by Western blotting. This
approach enabled
us to eliminate any sample-to-sample variability in
the assay.
The results indicated that p41 (MA-CA) membrane binding was
decreased
from that of Pr55
Gag; the percentages of
Pr55
Gag and p41 (MA-CA) present in membrane-containing
fractions were
approximately 32 and 14%, respectively. Similar results
were obtained
when postnuclear supernatants were prepared separately
from Pr55
Gag- and p41 (MA-CA)-expressing cells; in this
case, the percentages
of Pr55
Gag and p41 (MA-CA) present in
membrane-containing fractions were
32 and 23%,
respectively.
The 6VR mutation reduces membrane binding of p17 (MA).
It has
been proposed that following Pr55Gag cleavage by the viral
PR, MA undergoes a conformation change which results in the masking or
sequestration of the myristic acid moiety (55). p17 (MA)
thus displays a significantly reduced affinity for membrane compared
with Pr55Gag (42, 55). To determine whether the
6VR change influences membrane binding in the context of p17 (MA), we
introduced a stop codon immediately after the MA coding region in
pNL4-3 to generate pNL4-3/MAstop (Fig. 1). We then constructed 1GA and
6VR mutant derivatives of this molecular clone. Since it has been
reported that MA forms complexes that might pellet in a fractionation
assay even if not bound to membrane (31, 42), we performed
membrane flotation centrifugation to directly assess the effect of the 1GA and 6VR mutations on membrane binding (Fig. 6B). Approximately 9%
of wild-type p17 (MA) was detected in the membrane-containing fractions. We observed that both 1GA and 6VR mutations caused marked
reductions in the amount of p17 (MA) present in the membrane fractions,
indicating that both mutations reduce membrane binding in the context
of p17 (MA).
The 6VR-induced membrane binding defect can be reversed by
second-site changes in MA.
We previously isolated and
characterized a set of viral revertants obtained by passaging the 6VR
mutant in a T-cell line (33). One of these revertants
contained a second-site change at MA residue 97 (97KE) which fully
reversed the defects in virus replication and assembly caused by 6VR.
These results, together with the findings described above, suggest that
the 97KE change may reverse the 6VR phenotype by increasing Gag
membrane binding. To examine whether the 97KE substitution increases
Pr55Gag membrane binding in the presence or absence of the
6VR change, we transfected HeLa cells with pNL4-3/PR
molecular clones containing the 97KE or 6VR/97KE mutations and performed membrane flotation centrifugation (Fig.
7). Relative to wild type, the 97KE
mutant showed an increase in membrane-bound Pr55Gag.
Similarly, the 6VR/97KE double mutant showed an increased amount of floated Pr55Gag compared to the 6VR single mutant. These
results indicate that the 97KE substitution increases Gag membrane
binding both in the presence and absence of the 6VR change, thereby
elucidating the biochemical mechanism by which the 97KE change reverses
the 6VR-imposed defects in virus replication and assembly.
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[in a new window]
|
FIG. 7.
Opposing effect of MA mutations on membrane binding.
HeLa cells were transfected with pNL4-3/PR or derivatives
containing the indicated MA mutations. Postnuclear supernatants were
prepared and subjected to membrane flotation centrifugation (Materials
and Methods). The amount of Gag in each fraction was determined by
Western blotting.
|
|
We also investigated whether another mutation (20LK), which we
demonstrated to increase membrane binding (Fig.
5) (
25),
could reverse the virus assembly and release defect imposed by
6VR. A
derivative of pNL4-3/PR
was constructed which expressed a
6VR/20LK double mutant and
was analyzed by membrane flotation
centrifugation (Fig.
7). The
percentage of 6VR/20LK Pr55
Gag
found in fractions 3 and 4 was significantly increased compared
to that
of 6VR Pr55
Gag, indicating that the 6VR-imposed defect in
membrane binding is
reversed by the 20LK change. These results
demonstrate a functional
relationship between the MA N-terminal domain
and downstream sequences
in promoting efficient binding of Gag to
membrane.
The effect of the 6VR and 20LK changes on membrane binding is
dependent on Gag myristylation.
Although the mutations in residues
6 to 8 do not impair the covalent attachment of myristic acid to the
N-terminal Gly of MA (Fig. 3), these changes could affect the ability
of the myristate group to function effectively in membrane binding.
Alternatively, the N-terminal domain could promote membrane binding in
a manner independent of the myristate moiety. To explore these
possibilities, we investigated whether the 6VR change would decrease
membrane binding in the absence of N-terminal myristylation. We
constructed a 1GA/6VR double mutant and compared its membrane binding
properties with those of 1GA in membrane flotation assays (Fig.
8). As we showed above, even in the
absence of myristylation, a small amount of Pr55Gag is
recovered in the floated fractions (Fig. 5 and 8; 1GA). Analysis in the
same experiment indicated that the amount of 1GA/6VR Gag in
membrane-containing fractions was not less than that observed with 1GA
Gag (Fig. 8), suggesting that the 6VR phenotype is dependent upon
N-terminal myristylation.
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[in a new window]
|
FIG. 8.
Membrane flotation centrifugation of 1GA/6VR and
1GA/20LK double mutants. HeLa cells were transfected with
pNL4-3/PR or derivatives containing the indicated MA
mutations. Postnuclear supernatants were prepared and subjected to
membrane flotation centrifugation (Materials and Methods). The amount
of Gag in each fraction was determined by Western blotting.
|
|
We also investigated whether the increase in membrane binding induced
by the 20LK change was similarly dependent upon myristylation.
We
constructed a 1GA/20LK double mutant and compared its Gag membrane
binding ability with that of 1GA. 1GA and 1GA/20LK Pr55
Gag
showed similar distributions in membrane flotation assays (Fig.
8).
These results suggest that N-terminal Gag myristylation is
prerequisite
for the 20LK-induced enhancement of Gag membrane
binding.
| |
DISCUSSION |
HIV-1 MA has been shown to contain functional domains involved in
several steps in virus particle assembly and release, including membrane binding of Pr55Gag (for a review, see reference
11). In this study, we determined that a sequence
near the N terminus of MA (residues 6 to 8) plays a critical role in
HIV-1 Gag membrane binding. Single amino acid changes in this region
impaired virus production and reduced the efficiency of
Pr55Gag processing (Fig. 2). Despite wild-type levels of
N-myristylation (Fig. 3), these mutants displayed significantly
impaired Pr55Gag membrane binding, as determined by cell
fractionation, equilibrium sucrose density gradient, and equilibrium
flotation centrifugation assays (Fig. 4 and 5). This N-terminal MA
sequence also reduced membrane binding of both p41 (MA-CA) (Fig. 6A)
and p17 (MA) (Fig. 6B). Analysis of double mutants showed that
decreased membrane binding imposed by amino acid changes at residue 6 (6VR) was reversed by second-site amino acid changes in other regions
of MA (i.e., residues 20 and 97). Introduced singly into
Pr55Gag, the amino acid 20 (20LK) and 97 (97KE) changes
resulted in a mutant Pr55Gag which bound membrane more
efficiently than did the wild type (Fig. 7). Finally, the ability of
6VR to decrease and 20LK to increase membrane binding was not
observed in the absence of N-terminal Gag myristylation (Fig. 8).
MA residues 6 to 8 may contribute to Gag membrane binding
by several possible mechanisms. (i) The somewhat hydrophobic
nature of the MA N terminus may promote a direct interaction with the lipid bilayer. Although results obtained with a mutation near the N
terminus of the simian immunodeficiency virus MA support this
hypothesis (18), we observed membrane binding defects with the 8SA mutation, which increases local hydrophobicity. Furthermore, the conservative 7LV change also impaired virus assembly and release, and substitution of the residue 9 Gly for Glu had no significant effect
on virus assembly or replication kinetics (16). These findings argue that the overall hydrophobicity of the MA N terminus is
insufficient to account for its role in membrane binding. The 7LE
mutation may induce defects in addition to the impaired membrane binding, since its impact on virus release is as severe as that of 6VR
(Fig. 2), yet it has a less marked effect on membrane binding (Fig. 5).
(ii) In accordance with the myristyl switch model (see introduction),
mutations in MA residues 6 to 8 could prevent the exposure of the
myristate group, whereas substitutions at amino acids 20 and 97 could
increase myristate exposure. Our observation that the residue 20 mutation has no effect on membrane binding in the absence of MA
myristylation (i.e., 1GA/20LK; Fig. 8) supports this hypothesis. We
also observed that the 6VR mutation failed to decrease membrane binding
of Gag in the absence of the N-terminal myristate (i.e., 1GA/6VR; Fig.
8). (iii) MA residues 6 to 8 could interact directly with the lipid
bilayer or with a component of the membrane. This model can be
rationalized with the 1GA/6VR data by considering that the binding of
this N-terminal domain might occur only after initial interaction of
the myristate moiety with the bilayer. It is interesting to consider
the possibility that Gag might interact with a proteinaceous component
of the plasma membrane (i.e., a Gag receptor). The interaction of other myristylated proteins, for example v-Src and MARCKS, is thought to
involve protein-protein contacts (30). Although the
existence of a Gag receptor has been postulated (51), to
date no such molecule has been identified.
We urge caution in interpreting the impact of MA mutations on membrane
binding based only on their effects on myristate exposure. Although
myristate might be a prerequisite for efficient membrane binding, a
variety of considerations argue against the myristate moiety being the
only factor involved in the binding of authentic HIV-1 Gag to membrane.
(i) It has been proposed that the Gibbs free energy of binding
(
Gu) contributed by the myristate group, which has been
estimated for small peptides at approximately 8 kcal/mol, is
insufficient for stable attachment of a myristylated protein to
cellular membrane (36). (ii) The N-terminal 31 amino acid
sequence of HIV-1 MA, which includes the highly basic domain, confers
membrane binding ability upon heterologous proteins; some binding
occurs even in the absence of myristylation (54). (iii) In
this study, we observed a reduced but still detectable amount of 1GA
Gag in membrane fractions in membrane flotation assays, implying that
nonmyristylated Gag still retains some ability to bind membrane.
However, we cannot rule out the possibility that the 1GA Gag recovered
in membrane-containing fractions might represent a population of
molecules which does not bind membrane directly but, rather, interacts
with other membrane-bound components. (iv) In the three-dimensional
structure of HIV-1 MA (21, 29), a number of basic amino
acids, including several in the highly basic domain, are clustered on
one side of MA such that they could contribute membrane binding energy
by interacting with negatively charged phospholipids on the inner face
of the lipid bilayer. The orientation of basic residues on the
predicted membrane binding face appears to be a highly conserved
feature of retroviral MA protein structure (for review, see reference
7). (v) The MA domains of several retroviruses,
including Rous sarcoma virus and equine infectious anemia virus, are
not myristylated yet possess the ability to direct Gag binding to membrane.
In this study, we utilized three different methods to examine Gag
membrane binding. Although these assays all demonstrated that the
N-terminal MA mutants display reduced membrane binding compared with
that of the wild type, only the membrane flotation assay can separate
membrane-bound material from non-membrane-bound protein complexes such
as the recently described detergent-resistant Gag complex
(28). This point is illustrated clearly by comparing the
effect of the 1GA mutation by the three methods; in fractionation assays and sucrose gradient analyses the effect of the 1GA mutation was
fairly modest, while in membrane flotation assays its impact was
profound (Fig. 4 and 5). These observations suggest that much of the
Gag observed in the pellet in fractionation assays and in
membrane-containing fractions in the sucrose gradient analyses represents non-membrane-bound Gag complexes. This supposition is
supported by the finding that treatment of postnuclear supernatants with Triton X-100 before fractionation shifted the Env glycoproteins to
the supernatant fraction but had little effect on the distribution of
Pr55Gag. In contrast, the same treatment before membrane
flotation centrifugation largely abolished the migration of both Gag
and gp41 to membrane-containing fractions (32). Taken
together, these results are consistent with the notion that a
significant amount of Gag multimerization precedes the binding of Gag
to membrane. Although the contribution of NC to membrane binding
observed in our study was considerably smaller than reported previously
(40), the reduced membrane binding observed with p41 (MA-CA)
versus Pr55Gag suggests that NC sequences enhance membrane
binding. This effect may be mediated by the ability of NC to promote
Gag-Gag interactions (for review, see reference 11).
By carefully defining the advantages and limitations of each assay, we
can utilize combinations of cell fractionation, sucrose gradient, and
membrane flotation assays to gain additional insights into membrane
binding and virus assembly.
Our studies suggest that the affinity of MA for membrane must be
precisely balanced to enable Gag to function appropriately in early and
late phases of the HIV-1 life cycle. The 20LK and 97KE changes, both of
which increase Gag membrane binding (25) (Fig. 5 and 7),
cause an early postentry defect in virus infectivity (24,
25). Decreased membrane binding reduces the efficiency of virus
assembly and release, as observed in this and previous studies, whereas
increased membrane binding may cause retention of MA at the membrane
and consequently destabilization of the core/preintegration complex
early postentry (25). Natural emergence of the 97KE
substitution as a compensatory second-site change during replication of
the 6VR mutant (33) is consistent with this hypothesis.
Efforts are currently under way to further elucidate the role of
membrane binding in HIV-1 replication.
| |
ACKNOWLEDGMENTS |
We thank R. Kiernan, T. Murakami, M. Martin, and R. Willey for
helpful suggestions and critical review of the manuscript. Sera from
patients with AIDS were obtained through the NIH AIDS Research
Reference and Reagent Program (from L. Vujcic).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Bldg. 4, Rm.
307, NIAID, NIH, Bethesda, MD 20892. Phone: (301) 402-3215. Fax: (301) 402-0226. E-mail: EFreed{at}nih.gov.
| |
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Abstract
Introduction
