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Journal of Virology, April 2000, p. 3548-3554, Vol. 74, No. 8
0022-538X/00/$04.00+0
Genetic Evidence for an Interaction between Human
Immunodeficiency Virus Type 1 Matrix and 
-Helix 2 of the gp41
Cytoplasmic Tail
Tsutomu
Murakami and
Eric O.
Freed*
Laboratory of Molecular Microbiology,
National Institute of Allergy and Infectious Diseases, National
Institutes of Health, Bethesda, Maryland 20892-0460
Received 14 December 1999/Accepted 26 January 2000
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ABSTRACT |
The incorporation of envelope (Env) glycoproteins into virions is
an essential step in the retroviral replication cycle. Lentiviruses, including human immunodeficiency virus type 1 (HIV-1), encode Env
glycoproteins with unusually long cytoplasmic tails, the functions of
which have not been fully elucidated. In this study, we examine the
effects on virus replication of a number of mutations in a helical
motif (
-helix 2) located near the center of the HIV-1 gp41
cytoplasmic tail. We find that, in T-cell lines, small deletions in
this domain disrupt the incorporation of Env glycoproteins into virions
and markedly impair virus infectivity. Through the analysis of viral
revertants, we demonstrate that a single amino acid change (34VI) in
the matrix domain of Gag reverses the Env incorporation and infectivity
defect imposed by a small deletion near the C terminus of -helix 2. These results provide genetic evidence, in the context of infected T
cells, for an interaction between HIV-1 matrix and the gp41
cytoplasmic tail and identify domains of both proteins involved in this
putative interaction.
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INTRODUCTION |
Retroviral envelope (Env)
glycoproteins are synthesized in the endoplasmic reticulum as precursor
proteins that are proteolytically cleaved by a cellular protease during
their transport to the cell surface (11, 39). Cleavage of
the Env precursor generates the two components of the mature Env
glycoprotein complex: the surface (SU) and transmembrane (TM) Env
glycoprotein subunits. In the case of human immunodeficiency virus type
1 (HIV-1), the precursor, SU, and TM Env glycoproteins have been
designated gp160, gp120, and gp41, respectively. After reaching the
plasma membrane, the Env complex is incorporated into budding virions
by a process whose details remain to be elucidated.
A striking feature of lentiviruses is that they encode TM Env
glycoproteins with cytoplasmic tails (CTs) that are much longer than
those of other retroviruses. The HIV-1 and HIV-2 TM CTs, for example,
are generally around 150 residues in length, more than five times
longer than those of the avian and murine oncoretroviruses. Previous
studies have observed diverse effects of HIV-1 gp41 CT mutations,
including defective Env incorporation (6, 9, 46), impaired
virus infectivity (6, 9, 13), reduced gp160 processing and
Env stability (13), disrupted basolateral targeting of virus
release (2, 25), and slower Env internalization from the
cell surface (3, 33, 36). The structure of the gp41 CT has
not been determined; however, several regions within the tail are
likely to adopt a helical folding (8, 40). One of these,
termed -helix 1, is located at the C terminus of gp41; another,
referred to as -helix 2, is located near the center of the CT
(9). These helical motifs have also been referred to as
lentivirus lytic peptides due to their ability to associate with and
disrupt lipid bilayers (20, 28, 29, 38). The periodic
spacing of Leu residues in -helix 2 suggests that it may form a Leu
zipper (23).
Mixed results have been reported concerning whether or not the
incorporation of lentiviral Env glycoproteins into virions requires a direct interaction with the viral Gag proteins during assembly. Evidence for a direct Gag-Env interaction includes the findings that (i) mutations in the HIV-1 MA can block HIV-1 Env incorporation (5, 9, 12, 45) (this incorporation defect can
be reversed by pseudotyping virions with heterologous Env glycoproteins
containing short CTs or by removing the gp41 CT [9, 12,
26]), (ii) HIV-1 Env directs basolateral budding of Gag in
polarized epithelial cells (25), (iii) a direct binding between HIV-1 MA and gp41 CT peptides has been reported in an in vitro
system (4), and (iv) the Gag and Env proteins of simian immunodeficiency virus can be coimmunoprecipitated in virus-expressing cells (41). In contrast, several observations support a more passive mode of Env incorporation: heterologous Env proteins (e.g., those of murine leukemia virus, human T-cell leukemia virus, and vesicular stomatitis virus [VSV]) can be incorporated into HIV-1 virions (22, 26), and in some cases the gp41 CT is
dispensable for HIV-1 Env incorporation (9, 12, 13, 42). A
limitation of previous studies is that the cell types used in the
biochemical analysis of Env incorporation have generally been those
that are readily transfectable, rather than those that naturally
support productive, spreading HIV-1 infections. We recently
reported that truncation of the gp41 CT markedly impaired Env
incorporation when virus was produced in most T-cell lines and primary
monocyte-derived macrophages but had only a modest effect when
virus was derived from HeLa and MT-4 cells (31).
We previously determined that -helix 2 of the gp41 CT forms the
boundary between truncation mutants whose incorporation is blocked by a
single amino acid change in HIV-1 MA and truncated Env glycoproteins
whose incorporation is independent of MA mutation (9).
Furthermore, we observed that truncations that fell within -helix 2 had profound effects on Env incorporation and virus infectivity
(9). These results suggested that -helix 2 might play a
critical role in gp41 CT function. In this report, we examine the
effects of a number of -helix 2 mutations on virus infectivity and
Env incorporation. Biochemical analysis of Env incorporation in T-cell
lines capable of sustaining a productive HIV-1 infection is made
possible by the use of a high-level, transient HIV-1 expression system
based on pseudotyping with the VSV G glycoprotein (VSV-G) (31). Through the isolation and characterization of viral
revertants which appear spontaneously in infected T-cell line cultures,
we demonstrate that a single amino acid change in MA can reverse the Env incorporation defect imposed by a small deletion near the C
terminus of -helix 2. These results provide genetic evidence, in the
context of infected T-cell lines, for an interaction between MA and
-helix 2 of the gp41 CT.
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MATERIALS AND METHODS |
Cells, viruses, and plasmids.
CEM (12D-7), H9, HeLa,
and MAGI cells were maintained as described previously (18).
Human peripheral blood mononuclear cells (PBMC) were stimulated with 1 µg of phytohemagglutinin (PHA) per ml for 3 days and maintained in
RPMI 1640 medium supplemented with 10% fetal bovine serum (FBS), 2 mM
glutamine, antibiotics, and 20 U of recombinant human interleukin-2
(Roche Molecular Biochemicals) per ml. For infection of T-cell lines
and PBMC, virus was obtained by transfecting HeLa cells with the
T-cell-line-tropic molecular clone pNL4-3 (1) or derivatives
containing mutations in -helix 2 of the gp41 CT. VSV-G was expressed
using the plasmid pHCMV-G (44) (kindly provided by J. Burns).
Mutagenesis of the gp41 CT -helix 2.
A template for
oligonucleotide-directed mutagenesis was constructed by cloning the
BamHI-KpnI fragment from pNL4-3 (nucleotides [nt] 8465 to 9005) into M13mp18. Mutations in -helix 2 were
introduced by site-directed mutagenesis using methods described by
Kunkel et al. (21). The mutagenized fragments were then
recloned into pNL4-3 using the unique BamHI (nt 8465) and
XhoI (nt 8887) restriction sites and were sequenced in their
entireties. -Helix 2 of the gp41 CT overlaps with the rev
open reading frame. Certain mutations (not used in this study) near the
N terminus of -helix 2 caused marked Rev defects (unpublished data).
In contrast, the mutations reported here had no significant effect on
levels of Gag and Env expression, indicating normal Rev function.
Molecular cloning of viral revertants.
Virus supernatant was
harvested at the peak of virus replication from CEM (12D-7) or H9
cultures infected with mutant d5, d7, or
d8. Virus stocks were normalized for reverse transcriptase (RT) activity and used to infect fresh CEM (12D-7) or H9 cells in
parallel with the wild-type (wt) virus. At the peak of virus replication in the infected cultures, total DNA was purified using a
QIAamp blood kit (Qiagen). A 0.98-kbp fragment spanning the gp41 coding
region was PCR amplified from the extracted DNA. The primers used were
as follows: (+), 5'-GGAATGCTAGTTGGAGTAA-3', and (
),
5'-TGCCTTGTAAGTCATTGGT-3'. The plus-sense and minus-sense primers bound in the vicinity of pNL4-3 nt positions 8040 and 9020, respectively. For analysis of the d8 revertant, a 1.2-kbp fragment spanning the MA coding region was also PCR amplified as
described previously (9). Amplified DNA was purified and sequenced. The PCR products were digested with BamHI and
KpnI (nt 8465 and 9005) and cloned into pUC19. Following
resequencing, BamHI-XhoI fragments from the pUC19
clones were exchanged for the BamHI-XhoI fragment
(nt 8465 to 8887) of pNL4-3 to generate the pNL4-3/275LP/d5
and pNL4-3/271IN/d7 double mutants. To generate pNL4-3/d8/34VI, both pNL4-3/34VI (9) and
pNL4-3/d8 were digested with BssHII (nt 711) and
EcoRI (nt 5743) and the 5-kbp fragment from pNL4-3/34VI was
ligated with the 10-kbp fragment from pNL4-3/d8.
Transfections and infections.
Virus stocks of NL4-3,
-helix 2 mutants, and VSV-G pseudotypes were obtained by
transfecting HeLa cells using the calcium phosphate precipitation
method (14, 16). Transfected cell supernatants were
harvested, filtered (0.45-µm-pore-size filter), normalized for RT
activity, and used in infections as described below. Infections of
T-cell lines and PBMC were performed as previously described (12,
18). RT assays were performed as reported previously (12). CEM (12D-7) cells (5 × 106) were
infected with 1 ml of VSV-G-pseudotyped HIV-1. To block subsequent
spread of virions bearing the HIV-1 Env glycoprotein following
VSV-G-mediated infection, the CXCR4 inhibitor T22 (32) was
added to the infected cultures.
Metabolic labeling and radioimmunoprecipitation.
One day
following infection, infected cells were plated in 5 ml of Cys-free
RPMI medium supplemented with 10% FBS and 1 µM T22 in
25-cm2 flasks. After addition of [35S]Cys
(500 µCi), the cultures were incubated for 16 h at 37°C. Preparation of cell and viral lysates and immunoprecipitation of cell-
and virion-associated proteins with AIDS patient sera (HIV-1
neutralizing sera; obtained from the National Institutes of Health AIDS
Research and Reference Reagent Program; catalog no. 1983 and 1984) have
been described previously (10). Quantitative analysis of
bands visualized by radioimmunoprecipitation was performed with a FujiX
BAS2000 Bio-Image analyzer.
Western blot analysis.
Cell lysates prepared from HeLa or
CEM (12D-7) cells that were infected with VSV-G-pseudotyped HIV-1 were
separated by sodium dodecylsulfate-10% polyacrylamide gel
electrophoresis and transferred to polyvinylidene difluoride membranes
(Millipore) using a semidry blotter. Membranes were incubated with the
anti-gp41 monoclonal antibody T32 (7) (a kind gift of P. Earl) or AIDS patient sera. Subsequently, membranes were incubated with
horseradish peroxidase-conjugated secondary antibodies (Amersham
Pharmacia), and the antibody-bound proteins were detected by enhanced
chemiluminescence (Amersham Pharmacia).
Flow cytometric analysis of HIV-1 Env surface expression.
CEM (12D-7) cells (106) that were uninfected or infected
with VSV-G-pseudotyped wt or mutant HIV-1 were incubated for 1 h
at 4°C with 12.5 µg of the T32 anti-gp41 monoclonal antibody per ml
in phosphate-buffered saline (PBS) supplemented with 1% FBS. The cells
were then washed twice with PBS supplemented with 1% FBS and incubated
with fluorescein isothiocyanate-conjugated goat anti-mouse
immunoglobulin G for 30 min at 4°C. Cells were then washed once with
PBS supplemented with 1% FBS and once with PBS and resuspended in 1%
formaldehyde in PBS. Cell surface Env expression was analyzed with a
FACScan flow cytometer (Becton Dickinson).
Cell surface biotinylation.
Cell surface proteins on
VSV-G-pseudotype-infected CEM (12D-7) cells were biotinylated
essentially as described previously (37) using 0.25 mg of
sulfo-N-hydroxysuccinimide-biotin (Pierce). Biotinylated
cell lysates were immunoprecipitated with AIDS patient sera (to detect
total intracellular Env expression) or precipitated with
neutravidin-agarose beads (Pierce) (to detect cell surface Env) and
subjected to Western blotting with rabbit anti-gp120 polyclonal
antibody as described above. Brefeldin A treatment was performed for
4 h prior to biotinylation with 5 µg of brefeldin A (Sigma) per ml.
Single-cycle MAGI infectivity assay.
Single-cycle
infectivity of HeLa-derived virus was determined by transfecting HeLa
cells with wt or mutant molecular clones, harvesting virus stocks,
normalizing them for RT activity, and infecting the MAGI cell line
(19). To measure the infectivity of T-cell-line-derived
virus, HeLa cells were cotransfected with wt or mutant molecular clones
and a VSV-G expression vector. HeLa-derived stocks were
normalized for RT activity and used to infect CEM (12D-7) cells. Two
days postinfection, virus-containing supernatants were harvested from
the CEM (12D-7) cells, normalized for RT activity, and used to infect
the MAGI cell line. Infected MAGI cells were fixed, stained, and scored
2 days postinfection essentially as described previously
(19).
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RESULTS |
Small deletions in -helix 2 of the gp41 CT markedly
impair virus replication in T-cell lines.
To determine the role of
the -helix 2 domain of the gp41 CT in HIV-1 replication, we
introduced a number of single and double amino acid substitutions, and
several small deletions, into this region (Fig.
1). These mutations were designed
primarily to reduce the predicted helical nature of this sequence or to
disrupt its ability to form a leucine zipper. We first examined the
effect of these changes on virus replication kinetics in the CEM
(12D-7) and H9 T-cell lines. In general, single and double amino acid changes produced minor to moderate effects: 261LW, 273EP, 275LR, and
281EP replicated with near-wt kinetics; 259HP, 260RP, 263DP, 289LR, and
275LR/289LR replicated with a delay of 4 to 6 days relative to wt
NL4-3; 263DP/273EP and 263DP/281EP were delayed 8 and 12 days,
respectively, relative to wt (data not shown). In CEM (12D-7) cells,
the d7 and d8 deletion mutants replicated with
40- and 14-day delays, respectively, whereas d5 failed to replicate (Fig. 2A). In H9 cells,
d5, d7, and d8 replicated with delays
of 20, 10, and 32 days, respectively, relative to wt (Fig. 2B). In both
CEM (12D-7) and H9 cells, the d6 deletion mutant failed to produce any detectable RT activity. We also examined replication of the deletion mutants in PHA-stimulated human PBMC. No replication was observed for any of the mutants (data not shown). Thus, small deletions in gp41 -helix 2 markedly impaired virus replication in both T-cell lines and primary PBMC.
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FIG. 1.
Mutagenesis of -helix 2 of the gp41 CT. A linear
representation of the gp41 CT is shown at the top; the shaded area
represents the membrane-spanning domain of gp41 (MSD). Two predicted
helical domains within the CT (-helix 1 and 2) and gp41 amino acid
positions are indicated. The wt sequence is shown; residues which could
form a Leu zipper are boxed. Below the wt sequence are indicated the
positions of the -helix 2 mutations. Dashes denote amino acid
identity with wt; dots represent deleted residues.
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FIG. 2.
Replication kinetics of -helix 2 deletion mutants.
Virus stocks, obtained by transfection of HeLa cells with the indicated
molecular clones, were normalized for RT activity and used to infect
the CEM (12D-7) (A) and H9 (B) T-cell lines. mock, mock infected.
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Characterization of -helix 2 deletion mutants in HeLa
cells.
We next tested the infectivity of virus stocks obtained by
transfecting HeLa cells with wt or mutant molecular clones in the single-cycle MAGI assay (19). Relative infectivities of
d5, d6, d7, and d8,
normalized for the RT activity of each input inoculum, were 27 ± 20, 20 ± 19, 89 ± 32, and 51% ± 24% of the wt value (average of at least four assays, ± standard deviation). To examine the effect of the -helix 2 deletions on Env incorporation, we transfected HeLa cells in parallel with wt or mutant molecular clones,
metabolically labeled the transfected cells with
[35S]Cys, and immunoprecipitated cell- and
virion-associated proteins with AIDS patient sera. The results
indicated that the deletion mutations had no significant effect on Env
incorporation when virus was produced in HeLa cells; in a typical
assay, the amount of gp120 in d5, d6,
d7, and d8 virions (normalized for virion p24)
was 160, 106, 93, and 83% of that of the wt. These results demonstrated that the deletion mutations, particularly d5
and d6, significantly impaired virus infectivity in the MAGI
assay even in the absence of a reduction in Env incorporation.
The -helix 2 deletion mutants show Env incorporation defects in
a T-cell line.
We recently observed (31) that
truncation of the gp41 CT had little effect on Env incorporation when
virus was produced from HeLa cells but drastically reduced levels of
virion gp120 and gp41 when virus was produced by most T-cell lines. We
were therefore interested in determining the effect of the
d5 to d8 deletions on Env incorporation in T-cell
lines. Since levels of virus expression suitable for biochemical
analyses are generally not observed immediately following transfection
of T-cell lines, we utilized a high-level, transient HIV-1 expression
system based on pseudotyping with VSV-G (31). HeLa cells
were cotransfected with a VSV-G expression vector (44) and
either wt pNL4-3 or derivatives expressing the gp41 mutants.
VSV-G-pseudotyped virus stocks were harvested and used to infect CEM
(12D-7) cells. One day postinfection, cells were metabolically labeled
overnight with [35S]Cys, virions were pelleted by
ultracentrifugation, and cell and virion lysates were prepared and
immunoprecipitated with AIDS patient sera. Examination of
cell-associated material demonstrated that all mutants showed
essentially wt levels of Env expression and processing (Fig.
3). However, the deletion mutations
significantly reduced Env incorporation; in an average of three
independent assays, virion gp120 levels relative to p24 were reduced to
approximately 35 (d5), 10 (d6), or 20%
(d7 and d8) of those present on wt virions.
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FIG. 3.
Radioimmunoprecipitation analysis of -helix 2 deletion mutants. CEM (12D-7) cells were infected with wt or mutant
NL4-3 virions pseudotyped with VSV-G. Infected cells were metabolically
labeled overnight with [35S]Cys. Virion-associated
material was obtained by pelleting the infected cell supernatant in an
ultracentrifuge; lysates derived from cell- and virion-associated
material were immunoprecipitated with AIDS patient sera (see Materials
and Methods). The positions of the Env precursor gp160, the mature
surface glycoprotein gp120, p66 (RT), the Gag precursor
Pr55Gag, p32 (IN), and p24 (CA) are indicated; the sizes of
molecular mass markers are shown in kilodaltons (K). The results are
representative of two independent experiments.
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The virion gp120 data presented in Fig.
3 demonstrate that the deletion
mutations caused modest (3-fold) to severe (10-fold)
defects in Env
incorporation in the CEM (12D-7) T-cell line. To
investigate whether
this incorporation defect might result from
reduced cell surface Env
expression, the levels of wt and mutant
Env on the cell surface were
measured. Cell surface Env expression
was analyzed by flow cytometry
using CEM (12D-7) cells that were
uninfected or infected with
VSV-G-pseudotyped HIV-1. All mutants
showed essentially wt levels of
Env at the cell surface (Fig.
4). These
results suggest that the Env incorporation defect imposed
by small
deletions in gp41
-helix 2 does not result from reduced
cell surface
Env expression. This conclusion is supported by the
observation that
the
d8 mutation did not affect the levels of
gp120 detected
in cell surface biotinylation experiments using
infected CEM (12D-7)
cells (see below).
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FIG. 4.
FACS analysis of cell surface Env expression. Cell
surface immunostaining with an anti-gp41 monoclonal antibody (T32) was
performed using CEM (12D-7) cells infected with wt or mutant NL4-3
virions pseudotyped with VSV-G. Averages of duplicate experiments are
presented ± standard deviations. Solid bars represent mean
fluorescence intensities determined by FACScan; open bars indicate
percent Env-positive cells. Approximately 40% of cultures infected
with the wt were Env positive.
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Isolation of revertants of -helix 2 deletion mutants.
To
gain further insights into the mechanism by which the -helix 2 deletion mutations impaired virus replication, we sought to determine
whether the RT peak detected at delayed time points (Fig. 2) was due to
the emergence of viral revertants. Supernatants were harvested at the
peak of virus replication, normalized with wt for RT activity, and used
to reinfect fresh CEM (12D-7) or H9 cells. In all cases, the repassaged
viruses replicated with accelerated kinetics relative to the original
mutant (data not shown), suggesting the presence of viral revertants in
the infected cultures.
To examine the possibility that the putative revertants harbored a
second-site compensatory mutation(s), viral DNA was prepared
from
infected cultures at the peak of RT production and PCR amplification
was performed using primers specific for the gp41 CT coding region.
The
repassaged
d5 contained second-site changes at gp41 amino
acid 205 (S
L) and 275 (L
P); the putative
d7 revertant
acquired
a change at gp41 residue 271 (I
N). Both putative revertants
retained
the original (
d5 and
d7) mutations. By
constructing and analyzing
double mutants containing second-site
changes in combination with
the original deletions, we determined that
the 275LP and 271IN
substitutions were sufficient to repair the virus
replication
defect imposed by the
d5 and
d7
deletions, respectively (data
not
shown).
Sequencing of
d8-derived PCR fragments indicated that no
changes were present in the gp41 CT coding region, apart from the
original
d8 deletion. To assess the possibility that a
d8 compensatory
change might map to MA, we sequenced PCR
products obtained by
amplification of the MA coding region.
Intriguingly, the putative
d8 revertant that emerged
independently in both CEM (12D-7) and
H9 cells acquired the same
second-site change in MA: a V
I substitution
at MA residue
34.
The Env incorporation defect imposed by the d8 deletion
is reversed by the 34VI change in MA.
To evaluate whether the MA
34VI change was responsible for the improved replication kinetics
observed upon repassage of d8, a 34VI/d8 double
mutant was constructed. CEM (12D-7) cells were transfected in parallel
with wt pNL4-3 or derivatives containing the d8 or
34VI/d8 mutation (Fig. 5A). In
the pNL4-3-transfected culture, virus replication peaked on day 8 posttransfection; peak virus production in d8-transfected
cells occurred 12 days later. In contrast, the replication kinetics of
the 34VI/d8 double mutnat were delayed only 4 days relative
to wt. We also observed that the 34VI/d8 mutant showed wt
replication kinetics in H9 cells (Fig. 5B). To examine the effect of
the 34VI change in natural target cells, the replication kinetics of
d8 and 34VI/d8 in PHA-stimulated human PBMC were
examined. As shown in Fig. 5C, the 34VI/d8 double mutant
displayed a marked improvement in replication relative to
d8. These results indicate that the MA 34VI change is
sufficient to largely reverse the replication defect imposed by
d8 in T-cell lines and primary PBMC.
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FIG. 5.
Replication kinetics of wt, d8, 34VI, and
34VI/d8 in CEM (12D-7) (A), H9 (B), and PHA-stimulated human
PBMC (C). CEM (12D-7) cells were transfected with the indicated
molecular clones; H9 and PBMC were infected with HeLa-derived virus
stocks.
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We next examined whether the 34VI change improved
d8
infectivity in a single-cycle assay. CEM (12D-7) cells were infected
with VSV-G-pseudotyped wt,
d8, 34VI/
d8, and KFS
(
env minus [
12])
virions; virus stocks were
harvested, and their infectivities
were measured by MAGI assay
(Materials and Methods) (Fig.
6).
d8 showed an infectivity approximately 25% of that of wt,
whereas
34VI/
d8 showed near-wt infectivity. These results
demonstrate
that, using virus stocks obtained from CEM (12D-7) cells,
the
d8 infectivity defect is repaired by the MA 34VI
substitution.
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FIG. 6.
MAGI infectivities of virus stocks produced from CEM
(12D-7) cells infected with VSV-G pseudotypes. HeLa cells were
cotransfected with wt, KFS (env-minus), d8, 34VI,
or 34VI/d8 molecular clones and a VSV-G expression vector.
The VSV-G-pseudotyped virus stocks were normalized for RT activity and
used to infect CEM (12D-7) cells. Two days postinfection,
virus-containing supernatants were harvested, normalized for RT
activity, and used to infect the MAGI cell line (19).
Infected MAGI cells were fixed, stained, and scored 2 days
postinfection. The infectivity of wt virus stocks was approximately
3 × 104 infectious units/ml. Data presented are
averages of at least two assays, ± standard deviations.
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As indicated in Fig.
3, the
d8 mutation caused a significant
defect in Env incorporation in the CEM (12D-7) T-cell line. To
determine whether the improved replication kinetics and single-cycle
infectivity observed with the 34VI/
d8 revertant were due to
an
increase in Env incorporation relative to the original
d8
mutant,
we performed radioimmunoprecipitation analysis of cell- and
virion-associated
material derived from CEM (12D-7) cells (Fig.
7A). 34VI/
d8 virions
contained
approximately 70% of wt levels of gp120 relative to
p24, a substantial
improvement over the fivefold-reduced gp120
levels observed in
d8 virions. The 34VI single mutant displayed
wt levels of
Env incorporation. To determine whether the reduced
levels of gp120
present on
d8 virions are the result of increased
gp120
shedding from virions following Env incorporation, we measured
the
levels of gp41 on wt,
d8, 34VI, and 34VI/
d8
virions. Consistent
with the gp120 data (Fig.
7A),
d8 showed
a significant reduction
in virion gp41 which was restored to near-wt
levels in 34VI/
d8
double mutant virions (Fig.
7B). These
results support the conclusion
drawn from the gp120 data that
d8 reduces Env incorporation and
that this defect is
reversed by the 34VI change in MA.
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FIG. 7.
Analysis of wt and mutant Env incorporation into
virions. (A) Radioimmunoprecipitation analysis of wt, d8,
34VI, and 34VI/d8. CEM (12D-7) cells were infected with wt
or mutant virions pseudotyped with VSV-G. Labeling and
immunoprecipitation were performed as indicated in the Fig. 3 legend.
(B) Analysis of gp41 by Western blotting. Cell and virion lysates were
prepared from CEM (12D-7) cells infected with VSV-G-pseudotyped KFS
(Env-minus), NL4-3, d8, 34VI, or 34VI/d8. Samples
were transferred to polyvinylidene difluoride membranes, blotted with
an anti-gp41 monoclonal antibody (T32), and reprobed with AIDS patient
sera to detect p24 (CA) (Materials and Methods). These results are
representative of duplicate experiments.
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The fluorescence-activated cell sorting (FACS) data presented in Fig.
4
strongly suggest that levels of
d5 to
d8 Env
expression
at the cell surface are similar to those of wt. However,
since
the
d8 mutant showed a small reduction in surface
expression (Fig.
4), we wished to measure the amount of
d8
Env at the cell surface
using a different technique. To this end, we
performed cell surface
biotinylation of CEM (12D-7) cells infected with
VSV-G-pseudotyped
NL4-3 (wt) and the
d8 derivative. As a
negative control for Env
expression, we again used the
env-minus KFS mutant. The left panel
of Fig.
8 shows total Env expression; the right
side shows cell
surface protein (Materials and Methods)
(
31). To confirm that
only cell surface Env was
biotinylated, we treated cells expressing
wt Env with brefeldin A,
which traps glycoproteins in the endoplasmic
reticulum (
24).
The data indicate that the
d8 deletion mutant
expresses
gp160 and gp120 at the cell surface at levels comparable
to wt. As
expected, gp160 was expressed abundantly in brefeldin
A-treated cells
but was not efficiently expressed at the cell
surface. These results
confirm those presented in Fig.
4 and indicate
that the reduction in
d8 Env incorporation into T-cell-line-derived
virus is not
the result of impaired cell surface Env expression.
View larger version (39K):
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|
FIG. 8.
Analysis of cell surface d8 Env expression by
biotinylation. CEM (12D-7) cells were infected with VSV-G-pseudotyped
NL4-3 KFS (env minus), wt NL4-3, or NL4-3/d8.
Cells were biotinylated with
sulfo-N-hydroxysuccinimide-biotin; cell lysates were
immunoprecipitated with AIDS patient sera (to detect total Env
expression) or precipitated with neutravidin-agarose beads (to detect
cell surface Env) and were subjected to Western blotting with rabbit
anti-gp120 polyclonal antibody. To confirm that only cell surface Env
was biotinylated, we treated cells infected with VSV-G-pseudotyped
NL4-3 with brefeldin A (BfrA) (Materials and Methods).
|
|
| |
DISCUSSION |
No clear consensus has emerged from previous studies
concerning the role of the gp41 CT in HIV-1 replication. In general, previous biochemical analyses were performed in cell lines that can be
readily transfected (e.g., COS, CV-1, or HeLa), rather than in cells
that are targets for productive HIV-1 infection. In this study, the use
of a high-level, transient HIV-1 expression system based on
pseudotyping with VSV-G allowed us to determine both biological and
biochemical properties of gp41 CT mutants in T-cell-line cultures. We
examined the effects of mutations in -helix 2 of the gp41 CT on
virus infectivity and Env incorporation. Small deletions in -helix 2 markedly impaired virus replication in both T-cell lines (Fig. 2) and
primary PBMC, at least in part as a result of a defect in Env
incorporation into virions (Fig. 3 and 7). Through the isolation and
characterization of viral revertants which appeared spontaneously in
infected T-cell-line cultures, we found that second-site changes at
gp41 amino acids 275 (LP) and 271 (IN) reversed the replication
defects imposed by the d5 and d7 deletions,
respectively. Most interestingly, we demonstrate that a single amino
acid change in MA residue 34 (34VI) reverses the Env incorporation
defect imposed by the d8 mutation (Fig. 7). The Env
incorporation defect imposed by d8 is not caused by reduced
cell surface Env expression, as FACS analysis demonstrated wt levels of
gp160-gp41 (Fig. 4) and biotinylation assays (Fig. 8) showed wt levels
of gp160 and gp120 on the surface of d8-expressing cells.
Data obtained in the course of this study suggest that, in addition to
their effects on Env incorporation, some of the -helix 2 mutations
disrupt virus infectivity even in the absence of an Env incorporation
defect. When virus is produced from HeLa cells, the gp41 -helix 2 deletion mutants show essentially wt Env incorporation, yet
HeLa-derived virions display substantially reduced infectivity in the
MAGI assay. However, since in some contexts truncation of the entire
gp41 CT has little effect on virus infectivity (9, 12, 31,
35), these defects are likely due to conformational changes
induced by the mutations rather than to a direct role of -helix 2 residues in promoting virus infectivity. These small deletions may
therefore be functionally analogous to previously reported gp41 CT
mutations that impair virus infectivity without disrupting Env
incorporation (9, 13, 46). The observation that the
-helix 2 mutations markedly reduce Env incorporation in T-cell lines
but not in HeLa cells is consistent with our recent finding that HeLa
cells, but not most T-cell lines or primary cell types, are permissive
for the incorporation of HIV-1 Env lacking the gp41 CT (31).
The results presented here provide genetic evidence, in the context of
infected T-cell lines and primary PBMC, for an interaction between MA
and the gp41 CT. How might the region of MA encompassing residue 34 interact with the gp41 CT? X-ray crystallography data for both HIV-1
and simian immunodeficiency virus MA suggest that MA has a propensity
to trimerize and in so doing forms a lattice containing an array of
holes large enough to accommodate a gp41 CT trimer (15, 34).
These structural findings raise the possibility that portions of the
long gp41 CT fit into the holes present in the MA lattice and that this
configuration is stabilized by specific MA-Env interactions. Indeed,
the single amino acid MA mutations that we previously observed to
disrupt Env incorporation (9, 12) lie in a rim surrounding
the large lattice hole (34). However, several aspects of
this model remain uncertain. Since Env incorporation precedes and does
not require Gag processing (17), the MA domain of
Pr55Gag, rather than MA itself, drives the recruitment of
Env into virions. While MA has been reported to form trimers in
solution (30), it is not clear whether trimerization driven
by MA is relevant in the context of Pr55Gag or whether it
occurs in virus-expressing cells. Structural data for the intact CT of
gp41 are currently lacking, and a variety of folding models have been
proposed, several of which predict that gp41 CT -helices interact
with the inner face of the lipid bilayer (20, 28, 40, 43).
In any case, particularly considering the very subtle nature of
the 34VI substitution, it is interesting to note that this change
reverses the Env incorporation defect imposed not only by the gp41
d8 deletion (as shown here) but also by the 12LE MA mutation
(9). These results suggest an important role for MA residues
12 and 34, and gp41 CT -helix 2, in promoting Env incorporation.
| |
ACKNOWLEDGMENTS |
We acknowledge A. Ono, D. Demirov, and R. Willey for critical
review of the manuscript and for helpful discussions. We thank P. Earl
for the T32 anti-gp41 antibody and J. Burns for pHCMV-G. The
following reagents were obtained through the NIH AIDS Research and
Reference Reagent Program: HIV-1 neutralizing sera (from L. Vujcic) and
MAGI cells (from M. Emerman).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Bldg. 4, Rm.
307, NIAID, NIH, Bethesda, MD 20892-0640. Phone: (301) 402-3215. Fax: (301) 402-0226. E-mail: EFreed{at}nih.gov.
| |
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Abstract
Introduction
