Laboratory of Molecular Microbiology,
National Institute of Allergy and Infectious Diseases, National
Institutes of Health, Bethesda, Maryland 20892-0460
The envelope glycoprotein of human immunodeficiency virus type 1 (HIV-1) is extensively glycosylated, containing approximately 23 asparagine (N)-linked glycosylation sites on its gp120 subunit. In this
study, specific glycosylation sites on gp120 of a dualtropic primary
HIV-1 isolate, DH12, were eliminated by site-directed mutagenesis and
the properties of the resulting mutant envelopes were evaluated using a
recombinant vaccinia virus-based cell-to-cell fusion assay alone or in
the context of viral infections. Of the glycosylation sites that were
evaluated, those proximal to the V1/V2 loops (N135, N141, N156, N160)
and the V3 loops (N301) of gp120 were functionally critical. The
glycosylation site mutations near the V1/V2 loop compromised the use of
CCR5 and CXCR4 equally. In contrast, a mutation within the V3 loop
preferentially inhibited the usage of CCR5; although this mutant
protein completely lost its CCR5-dependent fusion activity, it retained
50% of the wild-type fusion activity with CXCR4. The replication of a
virus containing this mutation was severely compromised in peripheral
blood mononuclear cells, MT-4 cells, and primary monocyte-derived
macrophages. A revertant virus, which acquired second site changes in
the V3 loop that resulted in an increase in net positive charge, was isolated. The revertant virus fully recovered the usage of CXCR4 but
not of CCR5, thereby altering the tropism of the parental virus from
dualtropic to T-tropic. These results suggest that carbohydrate
moieties near the V1/V2 and the V3 loops play critical roles in
maintaining proper conformation of the variable loops for optimal
interaction with receptors. Our results, combined with those of
previously reported studies, further demonstrate that the function of
individual glycans may be virus isolate dependent.
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INTRODUCTION |
Human immunodeficiency virus type 1 (HIV-1) primarily infects CD4+ T lymphocytes and cells of
monocyte-macrophage lineage. The cellular tropism of HIV-1 is
determined largely at the level of virus entry, which depends on a
series of interactions between viral envelope glycoprotein and cellular
receptors. The gp120 surface glycoprotein subunit is thought to
interact first with CD4 (the primary receptor) and then with one (or
more) of the recently identified coreceptors, which include chemokine
receptors CXCR4 and CCR5 (for reviews, see references 15, 16, 26,
and 32). These interactions are thought to trigger
conformational changes in the complex multimeric viral envelope
glycoprotein structure, allowing the hydrophobic domain of
transmembrane glycoprotein gp41 subunit to interact with the cellular
membrane and induce virus-cell fusion.
While the exact mechanism of membrane fusion is still unclear, the
interactions between gp120 and cellular receptors are slowly beginning
to be understood. The detailed molecular nature of the interactions
between gp120 and CD4 has been elucidated from analysis of a crystal
structure of gp120 core complexed with CD4 (two N-terminal domains) and
the 17b neutralizing monoclonal antibody (Fab fragment), which
interacts with the putative coreceptor binding domain of gp120
(22). The interactions between gp120 and its coreceptors have been investigated using a multitude of indirect experimental approaches, including site-directed mutational analyses, functional and
infectivity studies with chimeric proteins and viruses, and biochemical
competition experiments with site-specific antibodies and chemokines
(5-7, 10, 11, 14, 21, 23, 35, 40-42, 45-47, 49, 52).
The accumulated data from these studies suggest that the variable loops
V1/V2 and V3, which likely form a pocket surrounding the four-stranded
antiparallel 
-sheet (bridging sheet), play important roles in
coreceptor interactions. Depending on the conformation of these loops,
gp120 binds to CCR5, CXCR4, or both, thus determining the cellular
tropism of the virus isolate (macrophage [M]-tropic, T-cell line
[T]-tropic, or dualtropic, respectively).
HIV-1 gp120 is one of the most extensively glycosylated proteins
(33). It contains 23 or 24 N-linked glycosylation sites, and the glycans attached to these sites account for approximately one-half of the protein's total mass (based on polyacrylamide gel
mobility). Numerous studies using glycosylation and glycosidase inhibitors have revealed the importance of the carbohydrate moieties in
determining the conformation of the HIV-1 envelope glycoprotein, a
property that undoubtedly affects its processing, intracellular transport, and ability to interact with CD4 (13, 17, 19, 29, 38,
50). The gross modifications resulting from the use of these
inhibitors, however, are not as informative as site-directed mutagenesis, which permits evaluation of the effects of individual glycans on protein structure and function. For example, site-directed mutagenesis of all 24 individual N-linked glycosylation sites of
HIV-1HXB2 indicated that most of the glycosylation sites
were individually dispensable (25). Of the 24 sites, only
5 (amino acids 88, 141, 197, 262, and 276), all of which are located in the amino-terminal half of gp120, affected virus infectivity.
Most site-directed mutagenesis studies have been conducted with gp120s
of T-tropic laboratory-adapted HIV-1 strains (e.g., HXB2 or NL4-3).
Several studies have demonstrated that these envelope glycoproteins
have biochemical and immunological properties which differ from those
of primary HIV-1 isolates (e.g., greater gp120 shedding and increased
susceptibility to neutralizing antibodies or CD4 [1, 12, 30, 31,
48, 55; for a review, see reference 39]). We have
previously characterized cellular tropism and coreceptor usage of a
primary isolate, HIV-1DH12 (7, 23, 44), a
dualtropic virus that can utilize CXCR4 and CCR5 almost equally and can
infect both T-cell lines and primary monocyte-derived macrophages
(MDM). In the present study, we examined the role of carbohydrate
moieties in cellular tropism and coreceptor usage of
HIV-1DH12 by mutagenizing specific N-linked glycosylation
sites throughout gp120. The mutant envelope proteins were examined for their capacity to induce cell-to-cell fusion. Some of the mutants were
further analyzed in the context of virus infectivity in both T-cell
line and primary cells. Our results indicate that the N-linked glycosylation sites near the V1/V2 and V3 variable loops are critical for the induction of membrane fusion and virus entry.
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MATERIALS AND METHODS |
Envelope glycoprotein mutagenesis.
Mutations affecting the
N-linked glycosylation sites were introduced into plasmid pTM-DHgp120H
(24), which encodes HIV-1DH12 gp120.
Asparagine (N) codons AAT or AAC were changed to glutamine (Q) codon
CAG by using the mutagenic oligonucleotides listed in Table
1. Codon changes were made using the Quik
Change site-directed mutagenesis kit according to the manufacturer's
protocol (Stratagene). N-linked glycosylation site mutations (µ) were
subsequently transferred to pNVV-DHenv (7), which encodes
the entire gp160 of HIV-1DH12. The mutations in
pTM-DHgp120H µ1-µ3 were transferred to pNVV-DHenv by replacing the
488-bp KpnI-StuI fragment (nucleotides [nt] 120 to 608) to generate pNVV-DHenv µ1 to µ3. For pNVV-DHenv µ4 and pNVV-DHenv µ5 to µ10, the 787-bp EcoNI fragments (nt 600 to 1387) and the 559-bp BglII fragments (nt 817 to 1376),
respectively, were transferred from the corresponding pTM-DHgp120H
clones. The plasmids pNVV-DHenv µ2-1, µ2-2, µ3-1, µ3-2, µ8-1,
and µ8-2 were generated directly from pNVV-DHenv with the same
site-directed mutagenesis protocol using the oligonucleotides shown in
Table 1.
The Asn-to-Gln mutations in pNVV-DHenv µ2, µ7, µ8, µ8-1, and
µ8-2 were transferred to an infectious molecular clone of chimeric virus AD8-DHenv (pAD8-DHenv [8]), which encodes the
envelope glycoprotein of HIV-1DH12 in the background of
HIV-1AD8. Mutations in µ2, µ8-1, and µ8-2 were
transferred using the 1,883-bp DraIII-SalI fragment (nt 368 to 2251), while those in µ7 and µ8 were
transferred using the 1,643-bp StuI-SalI fragment
(nt 608 to 2251). The revertant envelope clone pNVV-DHenv µ8-R was
constructed by transferring the 559-bp BglII fragment (nt
817 to 1376) from pCR-µ8-R (see below). All of the mutations were
verified by DNA sequence analysis. The nucleotide numbering was based
on the sequence of HIV-1DH12 gp160.
Protein expression and Western blotting.
The recombinant
vaccinia viruses vvDHenv µ1 to µ10 were generated from
corresponding pNVV-DHenv µ1 to µ10, following protocols previously
described (9). Confluent monolayers of HeLa cells in
6-well plates were infected with recombinant vaccinia viruses at a
multiplicity of infection of 10. Cell lysates were prepared by adding
lysis buffer (10 mM Tris, pH 7.5, 10 mM NaCl, 1.5 mM MgCl2,
1% NP-40) 48 h postinfection. Culture supernatants and cell
lysates were subjected to sodium dodecyl sulfate-polyacrylamide gel
electrophoresis (SDS-PAGE), followed by electrotransfer to nitrocellulose (Hybond; Amersham Life Science) for a Western immunoblot assay. Envelope glycoproteins were detected by blotting with rabbit anti-gp160 antiserum (53) followed by goat anti-rabbit
immunoglobulin G-peroxidase conjugate and visualizing with an ECL
Western blot detection kit according to the manufacturer's protocol
(Amersham Life Science).
Fusion assay.
A highly sensitive secreted alkaline
phosphatase (SEAP) reporter gene-based assay was used to quantitate
cell-cell fusion events as previously described (23). To
prepare target cells, recombinant vaccinia viruses encoding CCR5
(vvCCR5) or CXCR4 (vBD4 [3]), T7 RNA polymerase (vTF7-3
[18]), and human CD4 (vCB-3 [4]) were
used to coinfect Mus dunni cells. To generate vvCCR5, the
CCR5 gene was PCR amplified from a DNA preparation from human peripheral blood mononuclear cells PBMC using the following primers: (+), 5'-CTGAGGATCCCATATGGATTATCAAGTGTCA-AGT-3', and (
),
5'-GATCTTAAGCTTCTAGATCAGTGATGGTGATGGTGATGCGATCC-TCTCAAGCCCACAGATATTTC-3'. The conditions for PCR were as follows: 94°C for 7 min; 3 cycles of 94°C for 1 min, 40°C for 1 min, and 72°C for 3 min;
then 30 cycles of 94°C for 1 min, 55°C for 1 min, and 72°C for 3 min; and finally 72°C for 7 min. The PCR product was digested with BamHI and HindIII (incorporated in the
primers) and cloned into the same restriction sites in pGEM-3Zf()
(Promega, Madison, Wis.) to generate pGEM-CCR5. Subsequently, the
1,100-bp SmaI-XbaI fragment from pGEM-CCR5, which
contains the CCR5 gene, was cloned into SmaI-AvrII sites of pNVV-3 (provided by M. Oldstone). The resulting plasmid, pNVV-CCR5, was used to generate
recombinant vaccinia virus vvCCR5 following protocols previously
described (9). To prepare the effector cells, M. dunni cells were coinfected with recombinant vaccinia viruses
encoding SEAP under the control of T7 promoter (vTM-SEAP
[23]) and either wild-type (vvDHenv [7])
or mutant (vvDHenv µ1 to µ10) envelope glycoproteins. Although some
envelope mutants exhibited reduced levels of membrane-associated gp120,
we used the same multiplicity of infection of the recombinant vaccinia
viruses to express the same amount of the total envelope glycoprotein.
Infected cells were incubated at 37°C for 5 h and then
trypsinized. After the cells were washed twice with the culture medium
(Dulbecco's minimal essential medium containing 10% fetal bovine
serum), duplicate samples containing 5 × 104 (each)
target and effector cells were mixed in a 96-well plate. Cells were
cultured in the medium containing 80 µg of cytosine arabinoside per
ml for 8 to 10 h at 37°C. SEAP activity in the culture
supernatant was measured as previously described (23).
Virus stocks and infections.
The HIV-1 viruses used in this
study were generated from an infectious molecular clone, pAD8-DHenv
(8), which contains the env gene of
HIV-1DH12 in the background of HIV-1AD8.
Wild-type and mutant viruses were generated by transfecting respective
plasmids into HeLa cells using the calcium phosphate-based Profection
transfection system (Promega). Virus stocks were concentrated by
ultracentrifugation (Beckman SW 55Ti rotor; 35,000 rpm for 30 min). The
relative amounts of viruses were determined by measuring reverse
transcriptase (RT) activity in the stocks as previously described
(54). Viral infections were performed in 96-well plates
using either phytohemagglutinin-blasted human PBMC, MT-4 cells, or MDM
essentially as previously described (7).
Cloning the revertant env gene.
Human PBMC were
infected with AD8-DHenv µ8-R virus, which was initially isolated from
PBMC culture supernatants at peak RT activity (day 22). Infected cells
were harvested and Hirt DNA was prepared as described previously
(20). A 3-kb fragment spanning the env gene of
HIV-1DH12 was amplified by PCR from the Hirt DNA using the
following primers: (+), 5'-CAGTAGATCCTAGACTAGAGCCCTGG-3' (387 nt upstream from the env initiation codon), and
(), 5'-GCTGCTCCCACCCCATCTG-CTGCTG-3' (98 nt downstream
from the env stop codon). The conditions for PCR were as
follows: 94°C for 2 min followed by 10 cycles 94°C for 20 s,
63°C for 30 s, and 68°C for 4 min; 20 cycles of 94°C for
20 s, 63°C for 30 s, and 68°C for 4 min, plus 20 additional s for each incremental cycle; and finally 68°C for 7 min.
PCR was performed using the Expand long template PCR system (Boehringer Mannheim), and the PCR product was cloned using a Topo TA cloning kit
(Invitrogen). The env gene of the resulting plasmid
(pCR-µ8-R) was subsequently sequenced.
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RESULTS |
Mutagenesis and expression of envelope glycoproteins.
To
examine whether carbohydrate moieties of HIV-1 gp120 played any role in
its function or structural integrity, mutations (asparagine to
glutamine) were introduced into the conserved as well as variable
regions of HIV-1DH12 gp120, as depicted in Fig. 1. Either one (µ1, µ4, µ5, and
µ6) or two (µ2, µ3, µ7, µ8, µ9, and µ10) potential
N-linked glycosylation sites were changed throughout gp120. To
determine whether these mutations had any effect on the expression
and/or processing of gp160, recombinant vaccinia viruses encoding
either wild-type or mutant envelope glycoproteins were used to infect
HeLa cells. Cell lysates and culture supernatants were subjected to
SDS-PAGE and Western immunoblotting with rabbit anti-gp160 antiserum as
shown in Fig. 2a and b, respectively. Although the level of gp120 was somewhat lower for a few of the mutants
(e.g., µ3 and µ4) compared to the wild-type protein, all of the
mutant gp160s were expressed and processed to gp120. An increase in
electrophoretic mobility was observed for each of the deglycosylated
mutant glycoproteins compared to the wild type. This was more apparent
for the mutants containing two mutations (µ2, µ3, µ7, µ8, µ9,
and µ10). These results suggest that each of the asparagine residues
we had mutated was indeed being utilized for N-linked glycosylation.
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FIG. 1.
A schematic diagram of N-linked glycosylation site
mutant constructs. The positions of 23 potential N-linked glycosylation
sites and the variable regions of HIV-1DH12 gp120 are
identified at the top. Ten initial mutant constructs (µ1 through
µ10) are shown with the locations of the mutated glycosylation
site(s). Mutants µ1 and µ4 through 6 have only a single site
removed while the others have two sites removed.
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FIG. 2.
Western immunoblot of envelope glycoproteins expressed
by recombinant vaccinia viruses. Cell lysates (a) and culture medium
(b) of HeLa cells infected with either wild-type or mutant
envelope-expressing vaccinia viruses were subjected to SDS-PAGE
followed by Western immunoblotting. The positions of molecular weight
markers, gp160, and gp120 are indicated.
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Coreceptor usage of N-linked glycosylation site mutants.
HIV-1DH12 is a dualtropic virus, utilizing both CCR5 and
CXCR4 as coreceptors for virus entry. To examine whether
deglycosylation had affected its ability to induce membrane fusion
and/or coreceptor usage, we performed a highly sensitive cell-to-cell
fusion assay using SEAP as an indicator (23). As shown in
Fig. 3, the mutations did not appreciably
disrupt coreceptor usage, except for µ2, µ3, and µ8. The fusion
activity decreased to 30 to 40% of that of the wild-type protein for
µ2, whereas the activity was completely abolished for µ3 with
either CCR5 or CXCR4. This loss of fusion activity by µ3 was not
necessarily due to reduced gp160-processing efficiency of this mutant
since µ4, which exhibited a similar level of processing, induced only
slightly less cell-to-cell fusion activity compared to the wild type. A
different pattern of coreceptor fusion dysfunction was observed for
µ8; while retaining approximately 50% of the fusion activity with
CXCR4 compared to the wild type, it completely lost the activity with
the CCR5 receptor. These results indicate that the carbohydrate
moieties near the V1/V2 (µ2 and µ3) and V3 (µ8) loops of HIV-1
gp120 influence its capacity to induce membrane fusion, possibly by
altering the structure of envelope domain(s) interacting with either
CD4 and/or the coreceptors. A soluble CD4 (sCD4) binding assay
indicated that the interaction of µ3 gp120 with CD4 was reduced
approximately 50% compared to wild-type gp120. In contrast, µ2 and
µ8 gp120s exhibited binding properties to sCD4 similar to those of
the wild-type protein (data not shown).
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FIG. 3.
Cell-to-cell fusion activity. Fusion activity of mutant
envelope proteins with CCR5 or CXCR4 is shown as percentage of relative
light units (RLU) in comparison to the wild-type protein.
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Replication profile of viruses containing µ2 and µ8.
To
characterize the effects of glycosylation site mutations µ2 and µ8
in the context of an infectious virus, the mutations were transferred
to a full-length molecular clone, pAD8-DHenv (8). This
chimeric virus, which contains the HIV-1DH12 env gene in the background of HIV-1AD8, was used because its
capacity to produce progeny virus was superior to that of the parental HIV-1DH12 (8). The replication profiles of
µ2 and µ8 viruses in human PBMC, MT-4 cells, and human primary MDM
were compared to those of the wild-type virus and of another mutant
virus (µ7), which did not exhibit defective cell-to-cell fusion (Fig.
4).
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FIG. 4.
Replication of viruses carrying mutant envelopes. The
replication of three mutant viruses (µ2, µ7, and µ8) was compared
to that of the wild type in PBMC (a), MT-4 T cells (b), and MDM (c).
Virion-associated RT activity in the culture medium of virus-infected
cells was determined as described in Materials and Methods.
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The replication kinetics of mutants µ2 and µ7 in PBMC were slightly
delayed compared to that of wild-type virus (Fig. 4a). Thus, although
µ2 exhibited only 30 and 40% of the fusion activity with CCR5 and
CXCR4, respectively, the mutation had minimal effects on virus
replication in PBMC. In contrast, the replication of µ8, which had
retained 50% of the fusion activity with CXCR4 but completely lost its
ability to utilize CCR5, was significantly delayed in PBMC. In some
experiments, replication of µ8 was not observed (data not shown). In
MT-4 cells, µ7 replicated with only a slight delay compared to the
wild type, similar to what was observed in PBMC (Fig. 4b). In contrast,
the replication of µ2 was markedly delayed (first detected 16 days
postinfection). Surprisingly, no replication of µ8 was ever detected
in MT-4 cells even though µ8 exhibited fusion activity similar to or
greater than that of µ2 with CXCR4. Only wild-type and µ7 viruses
were infectious in MDM, with µ7 lagging slightly behind the wild type
(Fig. 4c). No replication of µ2 virus, which exhibited approximately
30% of the wild-type fusion activity with CCR5, was detected in MDM.
Fine mutagenesis of the V1/V2 and V3 regions of gp120.
Membrane fusion and virus infectivity assays indicated that the sites
mutated in the mutants µ2, µ3, and µ8 very likely play an
important role(s) in envelope glycoprotein function. All three mutants
carry mutations at two adjacent glycosylation sites. To ascertain the
relative importance of each glycosylation site within the pair, six
additional single-site mutants were constructed by individually
mutating N135 (µ2-1), N141 (µ2-2), N156 (µ3-1), N160 (µ3-2),
N295 (µ8-1), and N301 (µ8-2) (Fig.
5a). For the first four mutants (µ2-1,
µ2-2, µ3-1, and µ3-2), recombinant vaccinia viruses were
generated and the fusogenic properties of the mutant envelope
glycoproteins were examined. As shown in Fig. 5b, µ2-1 exhibited
fusion activity indistinguishable from that of µ2 with both CCR5 and
CXCR4. In contrast, the defect was more severe for µ2-2, which
retained only 10% of the wild-type fusion activity. Fusion activity
was severely affected for both µ3-1 and µ3-2, suggesting that the
carbohydrate moieties at both glycosylation sites are critical for this
protein function.
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FIG. 5.
Further analyses of mutants µ2, µ3, and µ8. The
two altered glycosylation sites in mutants µ2, µ3, and µ8 were
individually mutagenized to evaluate the relative importance of each
site. (a) Mutant constructs with the corresponding glycosylation site
that was mutated. (b) Cell-to-cell fusion activity levels of mutants
µ2-1, µ2-2, µ3-1, and µ3-2 were compared with those of the wild
type, µ2, and µ3. (c) Replication kinetics of the mutants µ8-1
and µ8-2 in PBMC are shown compared to those of the wild type and
µ8.
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For µ8-1 and µ8-2, the mutations were characterized in the context
of virus replication in human PBMC. As shown previously, the
replication of µ8 virus was markedly delayed by the mutation (Fig.
5c). However, virus bearing the µ8-1 mutation exhibited replication
kinetics similar to that of its wild-type parent, although a somewhat
lower progeny virus yield was observed. This result was somewhat
anticipated since the µ7 virus, which also carries the mutation at
N295, replicated quite efficiently (Fig. 4a) and demonstrated nearly
wild-type coreceptor usage (Fig. 3). In contrast, the virus containing
the µ8-2 mutation failed to replicate. These results strongly
indicate that carbohydrate moiety on N301 is critical for several
envelope glycoprotein functions and is primarily responsible for the
replication defects observed in µ8.
Characterization of the µ8 revertant.
A characteristic
property of HIV-1 mutants undergoing second-site revertant changes is
the delayed appearance of progeny virus, which usually regains partial
or even wild-type infection kinetics. In this study, µ2 virus
harvested at the markedly delayed peak of its infection of MT-4 cells
(day 20) (Fig. 4b) replicated with wild-type kinetics in subsequent
infection of MT-4 cells (data not shown), indicating the very likely
emergence of a µ2 revertant virus. Because of the unusual coreceptor
usage phenotype of µ8 (viz., CCR5/CXCR4+) (Fig. 3), we were
interested in ascertaining whether second-site revertants might have
arisen during the extended µ8 infection of PBMC (Fig. 4a). Progeny
virus present in day 22 culture supernatants from this infection was
used to reinfect fresh PBMC. As shown in Fig.
6a, the progeny virus (designated µ8-R)
replicated almost as efficiently as the wild-type virus, indicating
that a reversion had, in fact, occurred. The revertant virus, µ8-R,
also exhibited infection kinetics similar to that of the wild-type
virus in MT-4 cells (data not shown), suggesting that the reversion
permitted efficient utilization of CXCR4 as a coreceptor. In contrast,
µ8-R failed to replicate in MDM (data not shown).
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FIG. 6.
Characterization of second-site revertant. Replication
kinetics (a) and cell-to-cell fusion activity levels (b) of the
revertant µ8-R and its parental µ8 virus are compared to those of
the wild type. (a) Virus replication in PBMC. CPM, counts per minute;
WT, wild type.
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To elucidate the nature of reversion, the env gene of the
revertant virus was PCR amplified, cloned, and sequenced. As shown in
Table 2, µ8-R had acquired two
mutations within the V3 loop (N300Y and G306R) located near the
original mutations (N295Q and N301Q), which were still present. To
confirm that the two amino acid substitutions observed were indeed
responsible for the phenotypic change, both mutations were transferred
into the pNVV-DHenv plasmid and recombinant vaccinia virus was
generated. As shown in Fig. 6b, the second-site mutations completely
restored CXCR4 coreceptor usage to wild-type levels, as measured in a
fusion assay. However, the revertant envelope glycoprotein still failed
to utilize CCR5, consistent with the inability of the revertant virus
to replicate in MDM.
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DISCUSSION |
Carbohydrate moieties on HIV-1 gp120 are known to play several
important roles in the virus life cycle. Characterization of the
biochemical properties of the envelope glycoproteins synthesized in the
presence of various inhibitors of glycosylation or glycosidases have
shown that proper attachment and trimming of glycans on gp120 are
important for its folding and, therefore, for its biological function
(13, 17, 19, 29, 38, 50). However, our study clearly
demonstrates that gp120-associated N-linked glycosylation sites do not
contribute equally during virus entry, a result consistent with
previously reported site-directed mutagenesis studies for HIV-1
(25) or simian immunodeficiency virus (36).
Among the glycosylation sites we have evaluated, only those that are
near or within the V1/V2 (amino acids N135, N141, N156, N160) and V3 (amino acid N301) loops were critical for membrane fusion. These results are also consistent with numerous reports showing that the
V1/V2 and the V3 loops are critical determinants of coreceptor usage
and cellular tropism.
Although the amounts of total envelope glycoprotein expressed were
quite comparable, the levels of membrane-associated gp120 were lower
for some of the mutant envelopes (i.e., µ2, µ3, µ4, µ6, µ7,
and µ8) compared to the wild-type protein (Fig. 2a). This could be
due to decreased gp160 processing, increased shedding of gp120 from
gp41, or both. Thus, the defect in fusion activity for some of the
mutants could be due to the reduced levels of functional gp120-gp41
complexes on the membrane in addition to (or separate from) the
inherent biochemical properties of the mutant protein. We performed our
fusion assays based on the same amount of total envelope protein
expressed (i.e., by using the same amount of vaccinia virus) rather
than normalizing the level of membrane-associated gp120 for two
reasons. First, because the altered level of membrane-associated gp120
in itself is a phenotype of the mutation, comparing different envelopes
based on the same amount of total protein expressed, rather than the
amount of membrane-associated gp120, would be more appropriate. Second,
it is our observation that cell-to-cell membrane fusion is quite
efficient and that very little envelope protein is required for this
process. So, even the low amount of membrane-associated gp120 observed
for some of the mutant envelopes should be more than sufficient to induce cell-to-cell fusion. For example, µ4, which has the lowest amount of membrane-associated gp120 (Fig. 2a), exhibited quite efficient fusion activity (Fig. 3). Thus, the contribution of the low
level of membrane-associated gp120 on the reduced fusion activity
exhibited by µ2, µ3, and µ8 is not likely to be significant.
We have identified five gp120-associated N-linked glycosylation sites
that play important roles for dualtropic HIV-1DH12. The
corresponding glycosylation sites in other virus isolates may or may
not serve equally important functions. For example, mutation of N301 in
DH12 gp120 (sixth residue of the V3 loop) completely eliminated the
usage of CCR5 and severely impaired (reducing by 50%) CXCR4 usage.
Similarly, mutation of the corresponding residue on NL4-3 (T-tropic)
and SF13 (dualtropic) compromised CXCR4-dependent fusion activity
(34). However, no reduction of CCR5 usage was observed
when the same residue was mutated on SF13 and SF162 (M-tropic)
(34) or ConB (M-tropic) (51). Additionally, the corresponding mutation had no effect on infectivity of other T-tropic stains (LAI, BRU, and HXB2 [2, 27, 43]). These apparent discrepancies are likely due to specific differences in amino
acid sequences in the V3 loop for different isolates, which together
with carbohydrate residues create a V3 loop structure that interacts
with receptors. This notion is supported by the emergence of the
second-site revertant of µ8 virus (µ8-R), which acquired
compensating mutations in the V3 loop without glycosylation site
replacement. This revertant regained full usage of CXCR4 and replicated
efficiently in PBMC and MT-4 cells, although CCR5 usage remained
severely impaired. Of the two amino acid changes observed in µ8-R, a
glycine-to-arginine substitution at the 11th position of the V3 loop
increased the net positive charge of the V3 loop, thought to be
important for CXCR4 usage (37). Coincidentally, a similar
change at the 11th position of the V3 loop has been reported to rescue
the defect in CXCR4 usage by a mutation affecting the glycosylation
site at the 6th position of the HIV-1NL4-3 V3 loop
(34). These results indicate that depending on the amino acid residues of the neighboring region, the carbohydrate moieties may
or may not play critical roles in gp120 function.
The properties exhibited by different glycosylation site mutants were
not identical with respect to the extent or the type of defect. While
mutating N135 (µ2-1) reduced fusion activity with both CXCR4 and CCR5
to 50% of the wild-type level, mutating N141, N156, or N160 (µ2-2,
µ3-1, and µ3-2, respectively) almost completely disrupted the
fusion activity with both coreceptors. Mutant µ2, which carries
mutations both at N135 and N141, exhibited a phenotype similar to
µ2-1. In contrast, µ8 (N295 and N301), and presumably µ8-2
(N301), exhibited preferential defect in CCR5 usage. Furthermore,
unlike µ3, which exhibited reduced CD4 binding activity, mutants µ2
and µ8 interacted with CD4 as efficiently as the wild-type gp120. At
present, we can only speculate about which step of the envelope
glycoprotein-induced membrane fusion process is impaired. For example,
the primary defect of mutant µ3, and presumably of µ3-1 and µ3-2,
appears to be CD4 binding. On the other hand, µ2 seems to be impaired
at one of the post-CD4 binding steps, since the mutant gp120 bound CD4
as efficiently as the wild-type protein. This defect could include the
inability to undergo conformational change that occurs when gp120 binds CD4 (i.e., from closed to open conformation where the bridging sheet
becomes exposed) or the inability of gp120 to bind the coreceptors. In
the case of µ8, the interaction of gp120 with CCR5 is affected more
than that with CXCR4. Future analyses of direct binding between different mutant gp120s and CCR5 or CXCR4 may provide additional information on the nature of the defects observed in this study.
At first glance, some of the cell-to-cell fusion and virus infectivity
assay results may seem inconsistent. For example, the replication
kinetics of the virus carrying the µ2 mutation was very similar to
that of the wild-type virus in PBMC. In contrast, the replication of
µ2 virus in MT-4 T cells was severely impaired and no evidence of its
replication was detected in MDM. These results could simply reflect
possible differences in the levels of CD4 and/or chemokine receptors
expressed in different cell types as previously demonstrated by Ly and
Stamatatos (28), who reported that mutation of
glycosylation sites at the base of the V2 loop of gp120 affects viral
replication kinetics in a cell-dependent manner; mutants replicated
efficiently in cells expressing high levels of receptors but not in
cells expressing lower levels.
Considering that recombinant vaccinia viruses express high levels of
envelope glycoprotein, CD4, and coreceptors, it was somewhat surprising
to observe a marked reduction in cell-to-cell fusion activity for µ2
despite its efficient replication in PBMC. A possible explanation is
that both CCR5 and CXCR4 are present on primary CD4+ T
cells while only a single coreceptor is expressed on MT-4 cells, MDM,
and the M. dunni cells used for the fusion assay. The
dynamics of the interactions between a dualtropic gp120 with CCR5,
CXCR4, or both on the surface of primary CD4+ T lymphocytes
remain largely unknown. Given the multiple receptor binding sites on
the virion surface, the interactions between virus and cell are likely
to be highly complex.
We thank Bernard Moss, Ed Berger, Bob Doms, and Michael Oldstone
for providing valuable reagents. Recombinant soluble CD4 was obtained
from R. Sweet, SmithKline Beecham Pharmaceuticals, through the AIDS
Research and Reference Reagent Program, NIAID, NIH.
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Abstract
Introduction
Present address: Protein Engineering Laboratory, Korea Research
Institute of Bioscience and Biotechnology, Yusong, Taejon 305-600, Republic of Korea.
Present address: Purdue BioPharma, Biologics Discovery, Princeton,
NJ 08540.
