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Journal of Virology, August 1999, p. 7014-7020, Vol. 73, No. 8
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Mutations within Four Distinct Gag Proteins Are
Required To Restore Replication of Human Immunodeficiency Virus Type 1 after Deletion Mutagenesis within the Dimerization Initiation
Site
Chen
Liang,1
Liwei
Rong,1
Yudong
Quan,1
Michael
Laughrea,1
Lawrence
Kleiman,1,2 and
Mark A.
Wainberg1,2,*
McGill University AIDS Centre, Lady Davis
Institute-Jewish General Hospital, Montréal, Québec, Canada
H3T 1E2,1 and Department of Microbiology and
Immunology, McGill University, Montréal, Québec, Canada H3A
2B42
Received 20 January 1999/Accepted 16 April 1999
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ABSTRACT |
Human immunodeficiency virus type 1 (HIV-1) genomic RNA segments at
nucleotide (nt) positions +240 to +274 are thought to form a stem-loop
secondary structure, termed SL1, that serves as a dimerization
initiation site for viral genomic RNA. We have generated two distinct
deletion mutations within this region, termed BH10-LD3 and BH10-LD4,
involving nt positions +238 to +253 and +261 to +274, respectively, and
have shown that each of these resulted in significant diminutions in
levels of viral infectiousness. However, long-term culture of each of
these viruses in MT-2 cells resulted in a restoration of
infectiousness, due to a series of compensatory point mutations within
four distinct proteins that are normally cleaved from the Gag
precursor. In the case of BH10-LD3, these four mutations were MA1, CA1,
MP2, and MNC, and they involved changes of amino acid Val-35 to Ile
within the matrix protein (MA), Ile-91 to Thr within the capsid (CA),
Thr-12 to Ile within p2, and Thr-24 to Ile within the nucleocapsid
(NC). The order in which these mutations were acquired by the mutated
BH10-LD3 was MNC > CA1 > MP2 > MA1. The results of
site-directed mutagenesis studies confirmed that each of these four
substitutions contributed to the increased viability of the mutated
BH10-LD3 viruses and that the MNC substitution, which was acquired
first, played the most important role in this regard. Three point
mutations, MP2, MNC, and MA2, were also shown to be sequentially
acquired by viruses that had emerged in culture from the BH10-LD4
deletion. The first two of these were identical to those described
above, while the last involved a change of Val-35 to Leu. All three of
these substitutions were necessary to restore the infectiousness of
mutated BH10-LD4 viruses to wild-type levels, although the MP2 mutation
alone, but neither of the other two substitutions, was able to confer some viability on BH10-LD4 viruses. Studies of viral RNA packaging showed that the BH10-LD4 deletion only marginally impaired
encapsidation while the BH10-LD3 deletion caused a severe deficit in
this regard.
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TEXT |
The RNA genome of human
immunodeficiency virus type 1 (HIV-1) contains a 5'-end noncoding
region that includes a long terminal repeat consisting of the R and U5
regions and the primer binding site, as well as exon 1 leader sequences
downstream of U5 (13). Each of these elements plays a
crucial role in viral replication. The R region includes
cis-acting elements, such as TAR sequences that are required
for transcriptional transactivation by Tat and the poly(A) signal
needed for termination of transcription. The U5 region is involved in
both regulation of reverse transcription and integration of viral cDNA
into host cell chromosomal DNA. The primer binding site is an
18-nucleotide (18-nt) segment that binds to tRNA3Lys,
which serves as the cognate primer of reverse transcription. The exon 1 leader sequences downstream of U5 include the splice donor site and are
also involved in HIV-1 gene transcription as well as the dimerization
and selective encapsidation of full-length viral genomic RNA (3,
6, 23, 27-29, 31).
The secondary structure of the exon 1 leader sequence downstream of U5
includes four distinct stem-loop RNA motifs, termed SL1, SL2, SL3, and
SL4, that were initially predicted on the basis of computer modelling
and biochemical analysis (4, 10, 20). Mutagenesis studies
showed that the SL1, SL3, and SL4 elements were involved in the
selective packaging of viral genomic RNA (33, 34). This is
supported as well by cell-free studies that documented that the viral
nucleocapsid (NC) protein, which acts in trans to promote
viral RNA encapsidation, can also bind to the SL1, SL3, and SL4
structures with high affinity (7, 8, 10, 19, 39). SL1
contains a palindromic loop sequence (GCGCGC) that is
thought to represent the dimerization initiation site for viral genomic
RNA on the basis of cell-free experiments (3, 12, 25, 32, 36,
41). The importance of this region is also highlighted by the
fact that mutations within SL1 severely decreased viral infectiousness
(30, 35). However, the mechanisms involved are still poorly
understood; for example, viruses containing a mutated SL1 element were
only moderately affected in regard to incorporation of viral genomic
RNA. Furthermore, since SL1 is located upstream of the splice donor
site, it is still unclear how the former might exclude spliced viral
RNAs from being incorporated into virions. Contradictory results have
also been reported in regard to the role of SL1 in viral RNA
dimerization in viral replication studies (5, 11, 26, 40).
To shed further light on the role of SL1 in viral replication, we
selectively deleted a number of sequences in the SL1 region and
cultured the recombinant viruses thus generated in MT-2 cells over long
periods to determine whether and how compensation for viral replication
and viral RNA encapsidation might occur. Two deletion mutations,
BH10-LD3 and BH10-LD4, involving deletions of sequences at nt positions
+238 to +253 and +261 to +274, respectively, within the SL1 region,
were extensively analyzed (Fig.
1A).
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FIG. 1.
Schematic illustrations of the BH10-LD3 and BH10-LD4
deletions and their effects on the formation of RNA secondary
structure. Only structures with the lowest levels of free energy are
shown. (A) Secondary structures of wild-type HIV-1 RNA fragment (nt
+179 to +353). Nucleotides removed in the BH10-LD3 and BH10-LD4
deletions are shown by bold and underlined letters, respectively.
Secondary structures were predicted by the MFold program, using a
calculated stability of  43.5 kcal/mol. The SL1, SL2, SL3, and SL4 RNA
structures are consistent with previous reports (10). (B)
Effects of the BH10-LD3 deletion on the formation of RNA secondary
structures. The calculated stability of the secondary structures shown
is 37.1 kcal/mol, and maintenance of SL2 and SL4 is indicated. (C) Effects of the BH10-LD4 deletion
on the formation of RNA secondary structures at a stability of 38.0
kcal/mol. Formation of an SL1-like structure (SL1*) is indicated.
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Mutations termed MA1 (V35I), CA1 (I91T), MP2 (T12I), and MNC (T24I)
are involved in compensation for the BH10-LD3 deletion.
Previous
work by members of our group has shown that mutated BH10-LD3 viruses,
containing a deletion of the genomic segment from nt positions +238 to
+253, were able to revert to near wild-type replication kinetics after
18 passages in MT-2 cells, due to two point mutations, MP2 (T12I) and
MNC (T24I), located within the p2 peptide and NC protein, respectively
(30). However, the reverted viruses, termed BH10-LD3-18,
still showed a 2- to 3-day lag in growth. Therefore, we maintained the
BH10-LD3-18 viruses in MT-2 cells for an additional 11 passages and
showed that the virus thus generated, BH10-LD3-29, had reacquired full
replication capacity (data not shown). To identify additional mutations
responsible for this increased infectiousness, we amplified a 2-kb
HIV-1 DNA fragment (nt positions 454 to +1548) that contained the
BH10-LD3 deletion, using the primer pair Hpa-S-Apa-A and viral DNA
extracted from MT-2 cells. The results of cloning and sequencing
experiments showed that (i) the BH10-LD3 deletion and the previously
described MP2 and MNC point mutations still existed within the genome
of BH10-LD3-29 virus and that (ii) new point mutations MA1 [G(+430)A, i.e., V35I] and CA1 [T(+1000)C, i.e., I91T] were also present within
the matrix protein (MA) and the capsid (CA), respectively (Fig.
2).
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FIG. 2.
Compensatory point mutations MA1, MA2, CA1, MP2, and MNC
within the HIV-1 genome. Locations are illustrated by asterisks. The
mutations are as follows: MA1, Val-35 to Ile within MA; MA2, Val-35 to
Leu within MA; CA1, Ile-91 to Thr within CA; MP2, Thr-12 to Ile within
p2; and MNC, Thr-24 to Ile within NC. Letters in bold indicate original
nucleotides and amino acids and their replacements. HpaI,
BssHII, PstI, SphI, and
ApaI are unique restriction sites within the HIV-1 genome
that were employed in cloning experiments. The CA1, MA1, and MA2
substitutions were generated by means of PCR with primer pairs
CA1-Apa-A (5'-CCAGTGCATGCAGGGCCTACTGCACCAGGCCAGATC-3'
[+981 to +1016] and 5'-CCTAGGGGCCCTGCAATTTCTG-3'
[+1559 to +1538]), MA1-S-MA1-A
(5'-AATTAAAACATATAATATGGGCAAGC-3' [+421 to
+446] and 5'-GCTTGCCCATATTATATGTTTTAATT-3'
[+446 to +421]), and MA2-S-MA2-A
(5'-AATTAAAACATATATTATGGGCAAGC-3' [+421 to
+446] and 5'-GCTTGCCCATAATATATGTTTTAATT-3'
[+446 to +421]), respectively (mutated nucleotides are
underlined). PBS, primer binding site; DIS, dimerization initiation
site.
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To evaluate the roles of the newly identified MA1 and CA1 point
mutations in rescuing viruses containing the BH10-LD3 deletion,
the
above-mentioned substitutions were inserted into the BH10-LD3
construct
individually or in the context of viruses also containing
the MP2 and
MNC substitutions. The results of infection assays
(Fig.
3) showed that (i) MA1 and CA1 did not
alone or together
confer infectiousness on mutated BH10-LD3 virus
(i.e., BH10-LD3-MA1,
BH10-LD3-CA1, and BH10-LD3-MA1-CA1), (ii) MP2 did
not help MA1
and CA1 to rescue viruses containing the BH10-LD3 deletion
(i.e.,
BH10-LD3-MA1-MP2 and BH10-LD3-CA1-MP2), and (iii) association
of
MNC with either MA1 or CA1 gave rise to viruses able to generate
high
levels of reverse transcriptase (RT) activity in MT-2 cells
(i.e.,
BH10-LD3-MA1-MNC and BH10-LD3-CA1-MNC). Since MNC could
not by itself
rescue BH10-LD3 virus in regard to replication competence
(
30), these data suggest that the ability of both the
BH10-LD3-MA1-MNC
and BH10-LD3-CA1-MNC viruses to infect and replicate
in MT-2 cells
was attributable to the presence of MA1 and CA1
mutations. These
abilities are further demonstrated by the increase in
infectiousness
of the recombinant BH10-LD3 viruses containing various
combinations
of the MP2, MNC, MA1, and CA1 substitutions (Table
1).
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FIG. 3.
Roles of the MA1 and CA1 point mutations in compensation
for the BH10-LD3 deletion mutation. (A) Growth curves of viruses formed
from recombination of the BH10-LD3 deletion either with MA1, with both
MA1 and MP2, or with both MA1 and MNC to yield BH10-LD3-MA1 ( ),
BH10-LD3-MA1-MP2 ( ), and BH10-LD3-MA1-MNC ( ), respectively. The
clones thus generated were transfected into COS-7 cells, and the
progeny viruses were used to infect MT-2 cells. Levels of RT activity
were then monitored in culture fluids. MT-2 cells were exposed to
heat-inactivated wild-type virus as a negative control ( ).  ,
BH10. (B) Growth curves of the recombinant viruses BH10-LD3-CA1 (),
BH10-LD3-CA1-MP2 (), BH10-LD3-CA1-MNC (), BH10-LD3-MA1-CA1 (),
BH10-LD3-MA1-CA1-MP2 (), and BH10-LD3-MA1-CA1-MNC
(+) in MT-2 cells.  , control;
 , BH10.
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The MNC mutation appeared to be unique in that its presence in
concert with MA1, CA1, or MP2 was able to compensate for the
LD3
deletion in regard to restoration of infectiousness. In addition,
the recombinant virus BH10-LD3-MA1-CA1-MP2 replicated much less
efficiently than did BH10-LD3-MA1-CA1-MNC (Fig.
3B), further
highlighting
the importance of
MNC.
We also sought to determine the order in which the four point mutations
were acquired by BH10-LD3 viruses with deletions during
long-term
culture in MT-2 cells. Analysis of nine passages revealed
that the MNC
substitution was generated first (i.e., in one of
six clones after
passage 6 and six of six clones after passage
10) (Table
2). This finding is consistent with the
result described
above showing that the MNC substitution is essential
to compensation
for the BH10-LD3 deletion. The next mutation to be
detected was
CA1 in two of six clones after 10 passages under
conditions of
high levels of RT activity and virus-induced
cytopathology. The
MP2 substitution was observed only after 15 passages
in three
of six clones, and MA1 appeared last (in five of six clones
after
23 passages).
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TABLE 2.
Sequential appearance of various point mutations within
mutated BH10-LD3 virus after long-term culture in
MT-2 cellsa
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Long-term culture of BH10-LD4 viruses in MT-2 cells yielded
compensatory point mutations similar to those observed for BH10-LD3
viruses.
Both the BH10-LD3 and BH10-LD4 deletion mutations involve
disruption of the SL1 RNA structure and diminish HIV replication capacity (30). We were therefore anxious to determine
whether compensatory point mutations similar to those seen with
BH10-LD3 viruses might arise after long-term culture of BH10-LD4
viruses in MT-2 cells. After 13 passages, a virus termed BH10-LD4-13
that possessed wild-type replication properties had emerged (data not shown). In order to detect the presence of any compensatory mutations, a 2-kb DNA fragment (nt 454 to +1548) containing the BH10-LD4 deletion was amplified from the DNA of infected MT-2 cells as described
above. The DNA segment thus generated was used to replace the
equivalent region in BH10 to generate a clone termed BH10-LD4-HA. The
results of infectivity assays showed that BH10-LD4-HA was as
replication competent as wild-type virus (data not shown). Therefore,
we sequenced this 2-kb DNA fragment and observed that the BH10-LD4
deletion was still present alongside three point mutations termed MA2
(V35L), MP2 (T12I), and MNC (T24I) (Fig. 2). Both the MP2 and MNC point
mutations were identical to those previously identified in the reverted
BH10-LD3 virus, while the MA2 substitution involved a change of Val-35
to Leu instead of to Ile as was observed in the case of MA1. Therefore,
near-identical profiles of these point mutations were observed in the
genomes of viruses that had emerged from long-term growth of both the BH10-LD3 and BH10-LD4 viruses.
The ability of each of these three point mutations, MA2, MP2, and MNC,
to compensate for the BH10-LD4 deletion mutation was
next investigated
by introducing them individually or collectively
into the mutated
BH10-LD4 DNA clone to generate the following
constructs: BH10-LD4-MA2,
BH10-LD4-MP2, BH10-LD4-MNC, BH10-LD4-MA2-MP2,
BH10-LD4-MA2-MNC,
BH10-LD4-MP2-MNC, and BH10-LD4-MA2-MP2-MNC.
After transfection into
COS-7 cells, the infectiousness of the
viruses thereby produced was
examined in MT-2 cells. The results
of Fig.
4 show the following. (i) Neither the MA2
nor the MNC
point mutation alone (i.e., neither BH10-LD4-MA2 nor
BH10-LD4-MNC)
was able to restore infectiousness to the BH10-LD4 mutant
virus.
However, the MP2 point mutation (i.e., BH10-LD4-MP2) did
potentiate
viral replication and it yielded high levels of RT activity
in
culture fluids after 13 days. (ii) Recombining the MA2 and MNC
point
mutations into the same construct, i.e., BH10-LD4-MA2-MNC,
led to a
renewal of viral replication, as seen with BH10-LD3 virus;
similar
results were seen with combinations of MP2 and MNC (i.e.,
BH10-LD4-MP2-MNC) or MA2 and MP2 (i.e., BH10-LD4-MA2-MP2) within
the
BH10-LD4 construct). (iii) Recombination of the three point
mutations,
i.e., MA2, MP2, and MNC, within BH10-LD4 (i.e., BH10-LD4-MA2-MP2-MNC)
yielded even higher levels of infectiousness, as shown by both
growth
curves and 50% tissue culture infective doses (TCID
50s)
(Fig.
4; Table
2). Therefore, each of these three point mutations,
MA2,
MP2, and MNC, was able to contribute to the restoration of
viral
replication competence, and the MP2 point mutation played
a key role in
this regard.
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FIG. 4.
Roles of the point mutations MA2, MP2, and MNC combined
either separately or together with the BH10-LD4 deletion mutation to
yield BH10-LD4-MA2 (), BH10-LD4-MP2 (), BH10-LD4-MNC (),
BH10-LD4-MA2-MP2 (), BH10-LD4-MA2-MNC (), BH10-LD4-MP2-MNC
(+), and BH10-LD4-MA2-MP2-MNC
(). These constructs and wild-type BH10 () were transfected into
COS-7 cells, and the viruses thus generated were used to infect MT-2
cells. Viral replication was assessed by monitoring RT levels in
culture fluids.  , control.
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To further evaluate the importance of each of these point mutations in
the rescue of BH10-LD4 virus, we determined the order
in which they
appeared during long-term culture of BH10-LD4 virus
in MT-2 cells by
sequencing cDNA from infected cells at passages
3, 4, 5, 7, 10, and 13. Table
3 shows that the MP2 point mutation
appeared first and was present in two of six clones after three
passages. Next to be detected was MNC in one of six clones at
passage
4, followed by MA2 in one of six clones at passage 8.
All three point
mutations were present in all clones sequenced
after 13 passages. These
findings are consistent with the notion
that MP2 was the most important
mutation involved in the rescue
of mutated BH10-LD4 virus.
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TABLE 3.
Order of accumulation of the point mutations MA2, MP2,
and MNC within mutated BH10-LD4 virus when cultured in
MT-2 cellsa
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Comparison of the MA1 and MA2 point mutations in ability to
compensate for the BH10-LD3 and BH10-LD4 deletions.
The above data
indicate that two different amino acid substitutions were detected at
position 35 in MA after long-term growth of the BH10-LD3 and BH10-LD4
viruses and that the two substitutions involved changes from Val to Ile
and Leu, respectively, i.e., MA1 and MA2. Since Ile and Leu are similar
in structure, it was conceivable that the MA1 and MA2 point mutations
might function interchangeably in compensating for the BH10-LD3 and
BH10-LD4 deletions.
MA2 and MA1 mutations were also introduced into viruses with BH10-LD3
and BH10-LD4 deletions to yield the following constructs,
which also
variably contained the MP2 and MNC point mutations:
BH10-LD3-MA2,
BH10-LD3-MA2-MP2, BH10-LD3-MA2-MNC, BH10-LD3-MA2-MP2-MNC,
BH10-LD4-MA1,
BH10-LD4-MA1-MP2, BH10-LD4-MA1-MNC, and BH10-LD4-MA1-MP2-MNC.
Infectivity assays were performed as described above and showed that
neither the BH10-LD3-MA2 nor the BH10-LD3-MA2-MP2 virus
was able to
generate high levels of RT activity, while, in contrast,
the
BH10-LD3-MA2-MNC virus was able to replicate at a reasonably
high level
(Fig.
5). Introduction of the MA2 point
mutation into
BH10-LD3-MP2-MNC resulted in an increase in
TCID
50 (Table
1).
Therefore, MA2 was able to function in
place of MA1 in regard
to compensating for the BH10-LD3 deletion.
Similar experiments
revealed that BH10-LD4-MA1-MNC generated high
levels of RT activity
after 11 days in culture, as did BH10-LD4-MA1-MP2
(Fig.
5). Finally,
the presence of MA1 increased the TCID
50
of BH10-LD4-MP2-MNC (Table
1). Therefore, the MA1 and MA2 point
mutations play similar roles
in compensating for either the BH10-LD3 or
the BH10-LD4 deletion.
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FIG. 5.
Roles of the MA1 and MA2 point mutations in compensation
for both the BH10-LD3 and BH10-LD4 deletion mutations through
generation of BH10-LD3-MA2 (), BH10-LD3-MA2-MP2 (),
BH10-LD3-MA2-MNC (), BH10-LD4-MA1 (), BH10-LD4-MA1-MP2 (), and
BH10-LD4-MA1-MNC (+). These clones
were transfected into COS-7 cells, and the progeny viruses obtained
were used to infect MT-2 cells. , BH10; , control.
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The BH10-LD4 deletion only slightly affects encapsidation of viral
genomic RNA.
Previous studies showed that the MNC point mutation
was able to correct for the diminished levels of viral genomic RNA
encapsidation that occurred in the case of the BH10-LD3 deletion
(30). Since MA2 and MP2 were together able to restore high
levels of infectiousness to BH10-LD4 mutant virus in the absence of MNC
(see above), it was suggested that BH10-LD4 might not be severely
impaired in regard to packaging of viral RNA. This was assessed by
means of slot blot experiments that showed that both BH10-LD4 and
BH10-LD4-MP2-MNC viruses packaged levels of viral genomic RNA similar
to those packaged by the wild-type BH10 virus (Fig.
6). Therefore, those sequences that were
deleted from BH10-LD3 viruses probably play a key role in packaging of
viral genomic RNA while those that were deleted from BH10-LD4 viruses
do not.
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FIG. 6.
Encapsidation of viral genomic RNA into wild-type (BH10)
and mutated (BH10-LD4 and BH10-LD4-MP2-MNC) viruses. Slot blot
experiments were performed with viral RNA purified from viruses
containing either 100 or 33.3 ng of p24. Viral RNA digested with RNase
served as a negative control. Amounts of viral RNA packaged by either
wild-type or mutated viruses were determined by arbitrarily setting a
value of 1.0 for the former.
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These studies have examined the abilities of two distinctly mutated
viruses, BH10-LD3 and BH10-LD4, both involving deletions
within SL1, to
revert to wild-type replication kinetics after
long-term culture in a
permissive cell system. Surprisingly, all
of the compensatory mutations
were identified in the Gag protein
and not within the 5'-end noncoding
RNA leader region. We have
observed that the revertants possessed
similar mutations in the
gag gene in each case and that the
MP2 and MNC point mutations
appeared first and were able to restore
viral replication ability
to fairly high levels. Although mutations at
position 35 in MA
were observed for both BH10-LD3 and BH10-LD4 at later
stages,
they involved replacements of amino acids by Ile and Leu,
respectively.
It is noteworthy that Ile and Leu are structurally
similar and
were functionally interchangeable in regard to compensation
for
the BH10-LD3 and BH10-LD4 deletions. Thus, deletions of the
sequences
from +238 to +253 and from +261 to +274 within SL1 can be
compensated
for by similar point mutations within
gag, and
therefore, the
two sequences probably possess similar roles in viral
replication.
This work provides important in vivo confirmation for the
existence
of an SL1 functional structure within the HIV-1 RNA sequence
from
+238 to +274. However, our results also indicate that the two
deleted segments are not functionally equivalent. First, an additional
point mutation, CA1, was detected in mutated BH10-LD3 but not
BH10-LD4
viruses during long-term culture. Second, the MNC and
MP2 point
mutations were observed to have different roles in compensation
of the
deletions in BH10-LD3 and BH10-LD4 viruses. For example,
MNC was a
major factor in regard to the replication kinetics of
BH10-LD3 and was
able to confer infectiousness on this construct
when combined with each
of the MA1, CA1, and MP2 point mutations.
Furthermore, MNC was the
first substitution to be acquired by
BH10-LD3 virus during long-term
culture.
In contrast, MP2 played a more important role than MNC in regard to the
BH10-LD4 deletion. For example, MP2 alone was able
to confer
infectiousness on BH10-LD4 and was the first point mutation
to be
identified in BH10-LD4 virus during long-term culture in
MT-2 cells.
Biochemical analysis showed that BH10-LD3 but not
BH10-LD4 virus was
severely compromised in the ability to encapsidate
viral genomic RNA,
helping to explain why the MNC mutation, important
for restoration of
packaging activity, was crucial to compensate
for BH10-LD3 but not for
BH10-LD4 (
30). Hence, the sequences
from +238 to +253 and
from +261 to +274 together constitute a
functional element, yet at the
same time, they play distinct roles
in viral replication. Ongoing
studies are being performed in regard
to the effects of the BH10-LD3
and BH10-LD4 deletions as well
as of the newly identified compensatory
point mutations on viral
RNA
dimerization.
The different effects of the BH10-LD3 and BH10-LD4 deletions on viral
RNA encapsidation might be due to their ability to modulate
stem-loop
secondary structures in different ways. In the case
of wild-type viral
RNA,
cis-acting RNA packaging signals result
in four
distinct stem-loop structures (i.e., SL1 to SL4) (Fig.
1A). Deletion of
the fragment from nt +238 to +253 (i.e., BH10-LD3)
eliminates SL1 and
SL3, both of which can bind to Gag protein
and are involved in RNA
packaging (Fig.
1B) (
10). In contrast,
the BH10-LD4 deletion
(nt +261 to +274) does not disrupt the formation
of SL2, SL3, or SL4
and, moreover, leads to the formation of an
SL1-like RNA structure
(Fig.
1C). This explains how the BH10-LD3
but not the BH10-LD4 deletion
severely compromises viral RNA
packaging.
The mechanisms involved in compensation for the BH10-LD3 and BH10-LD4
deletions can be inferred from the amino acids involved
in the various
point mutations that have been identified. For
example, MNC involves a
change of Thr-24 to Ile within the first
Zn finger motif of NC, i.e.,
CysPheAsnCysGlyLysGluGlyHisThrAlaArgAsnCys
(Fig.
2). NC is known to
play a dominant role in regulation of
packaging of viral genomic RNA,
and mutagenesis studies have demonstrated
that both the Zn fingers
themselves as well as the basic amino
acids that flank them are
involved in this process. Furthermore,
the first Zn finger domain is
functionally more important than
the second (
2,
7-9,
14,
15,
18,
38). Therefore, it
is consistent with these observations that the
MNC point mutation
was able to restore levels of packaging of viral RNA
in the case
of the BH10-LD3-MNC recombinant
virus.
The MP2 point mutation involves a substitution of Ile for Thr at
position 12 in p2, a peptide that is only 14 amino acids
long. It
is interesting that Thr-12 is located at the P3 position
at the
initial site that is cleaved by protease (PR), i.e.,
AlaThrIleMet*MetGlnArgGly,
located between the C terminus
of p2 and the N terminus of NC
(Fig.
2). Therefore, replacement of Thr
by Ile may also have changed
the nature of this cleavage site and/or
the ability of Gag and/or
Gag-Pol to serve as the substrate for PR.
Previous results have
shown that p2 plays an important role in the
processing of the
Gag precursor protein and in viral maturation
(
1,
24,
37,
42). Recent work also implicated the p2 domain
in the specific
packaging of HIV-1 genomic RNA (
22). The
fact that the MP2 mutation
can compensate for deletions in SL1 suggests
that the latter RNA
element may also participate in the processing of
Gag
protein.
It is also interesting that mutations within MA (V35I and V35L) were
able to compensate for deletion mutations within the
SL1 structure. The
amino acid stretch within MA from positions
30 to 43, within which lies
Val35, forms an
-helix (i.e.,
-H2)
that constitutes an N-terminal
globular structure (
21). Others
have shown that the SL1 RNA
hairpin region can bind to Gag protein
with high affinity in cell-free
experiments (
10). Thus, such
interactions may conceivably
play important roles in Gag protein
assembly and in the processing of
Gag by PR in vivo. Our deletions
within SL1 probably affected
interactions between Gag protein
and viral genomic RNA and may have
thereby compromised the assembly
of Gag proteins. The MA1 and MA2 point
mutations may help to compensate
for this defect by modulating the
assembly of Gag proteins in
the case of the viral deletion
mutants.
Another point mutation at position 91 (I91T) in CA termed CA1 was also
identified as involved in compensation for the BH10-LD3
deletion.
Interestingly, the Ile at position 91 is one of only
nine amino acids
(i.e., 85-ProValHisAlaGlyProIleAlaPro-93) within
the CA protein that
comprises the binding site for cyclophilin
A (CypA). Crystal
structure analysis of the CA-CypA complex shows
that the side
chain of Ile-91 projects directly out from the CypA
active site and has
no intermolecular contact (
17). Mutagenesis
studies also
showed that replacement of Ile-91 by either Ala or
Val had no
measurable effect on the efficiency of CypA binding
(
43).
Therefore, the CA1 point mutation may not affect the binding
of CypA to
CA but may instead function through some other mechanism
to help rescue
the BH10-LD3 deletion. In addition, site-directed
mutagenesis studies
in our laboratory showed that the CA1 point
mutation does not diminish
the infectiousness of wild-type virus
(data not shown). Studies of the
effects of the MA1 and MA2 point
mutations on viral infectivity are
ongoing.
In summary, two distinct deletions within the noncoding viral RNA
sequence, SL1, can be compensated for by substitutional
mutations
within four different Gag proteins. Analysis of these
mutations
suggests that the SL1 region is involved in Gag protein
assembly and
processing in addition to its well-documented roles
in viral RNA
packaging and
dimerization.
| |
ACKNOWLEDGMENTS |
This work was supported by grant R01 AI43878-01 from the National
Institute of Allergy and Infectious Diseases and by the Medical
Research Council of Canada.
We thank Maureen Oliveira for technical assistance.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: McGill AIDS
Centre, Jewish General Hospital, 3755, chemin Côte-Ste-Catherine,
Montréal, Québec, Canada H3T 1E2. Phone: (514) 340-8307. Fax: (514) 340-7537. E-mail: mdwa{at}musica.mcgill.ca.
| |
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Journal of Virology, August 1999, p. 7014-7020, Vol. 73, No. 8
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Copyright © 1999, American Society for Microbiology. All rights reserved.
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