Previous Article | Next Article 
Journal of Virology, September 2000, p. 8524-8531, Vol. 74, No. 18
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Retracing the Evolutionary Pathways of Human Immunodeficiency
Virus Type 1 Resistance to Protease Inhibitors: Virus Fitness in
the Absence and in the Presence of Drug
Fabrizio
Mammano,1,*
Virginie
Trouplin,1
Veronique
Zennou,2 and
Francois
Clavel1
Laboratoire de Recherche Antivirale, INSERM
U82,1 and Unité d'Oncologie
Virale, Institut Pasteur,2 Paris, France
Received 6 March 2000/Accepted 15 June 2000
 |
ABSTRACT |
Human immunodeficiency virus type 1 (HIV-1) resistance to protease
inhibitors (PI) is a major obstacle to the full success of combined
antiretroviral therapy. High-level resistance to these compounds is the
consequence of stepwise accumulation of amino acid substitutions in the
HIV-1 protease (PR), following pathways that usually differ from one
inhibitor to another. The selective advantage conferred by resistance
mutations may depend upon several parameters: the impact of the
mutation on virus infectivity in the presence or absence of drug, the
nature of the drug, and its local concentration. Because drug
concentrations in vivo are subject to extensive variation over time and
display a markedly uneven tissue distribution, the parameters of
selection for HIV-1 resistance to PI in treated patients are complex
and poorly understood. In this study, we have reconstructed a large
series of HIV-1 mutants that carry single or combined mutations in the
PR, retracing the accumulation pathways observed in ritonavir-,
indinavir-, and saquinavir-treated patients. We have then measured the
phenotypic resistance and the drug-free infectivity of these mutant
viruses. A deeper insight into the evolutionary value of HIV-1 PR
mutants came from a novel assay system designed to measure the
replicative advantage of mutant viruses as a function of drug
concentration. By tracing the resultant fitness profiles, we determined
the range of drug concentrations for which mutant viruses displayed a
replicative advantage over the wild type and the extent of this
advantage. Fitness profiles were fully consistent with the order of
accumulation of resistance mutations observed in treated patients and
further emphasise the key importance of local drug concentration in the patterns of selection of drug-resistant HIV-1 mutants.
| |
INTRODUCTION |
Protease inhibitors (PIs) are widely
used in the highly active antiretroviral therapy regimens currently
prescribed for the treatment of human immunodeficiency virus type 1 (HIV-1) infection. These compounds block the activity of the HIV
protease (PR) (1, 12, 17-19) and exert a profound
inhibitory effect on HIV infectivity in vitro and in vivo, yielding
long-term suppression of detectable HIV replication in treated patients
and spectacular stabilization of the evolution of HIV disease (22,
24). However, when antiretroviral therapy fails to be fully
suppressive of HIV replication, viral variants with decreased
susceptibility to PIs can emerge (10, 20, 29, 31, 33, 37, 42,
45). HIV-1 resistance to PIs is the result of the accumulation of
amino acid substitutions in HIV-1 PR, following a stepwise process that
leads to increasing levels of resistance (4, 9, 20, 33).
Most of the residues involved in PI resistance are highly conserved
within the different clades of HIV-1 (3, 49). It is
therefore assumed that these residues are essential for optimal PR
function, ensuring optimal infectivity of HIV particles.
Correspondingly, it has been shown by several laboratories that a
number of HIV-1 mutants carrying PI resistance mutations, whether
selected in vitro or in treated patients failing PI therapy, display
significantly reduced infectivity, related to incomplete processing of
the structural and enzymatically active proteins of HIV by PR (5,
7, 11, 29, 32, 43, 51). Particular substitutions or combinations
of substitutions appear to exert more profound enzymatic and virus
replicative defects: this is often the case for substitutions that are
located within the active site of the enzyme and are directly involved in inhibitor and substrate binding (20, 23, 30, 41, 43). Interestingly, the enzymatic and replicative defects induced by such
mutations can be partially, or even in some instances completely, compensated for by the emergence of secondary mutations located outside
of the substrate-binding region of the enzyme (5, 20, 27, 29,
35).
Virus resistance is usually calculated by measuring the concentration
of drug that is required to inhibit 50% (IC50) or 90% (IC90) of virus infectivity. For each virus variant, the
level of resistance is therefore calculated relative to its own
infectivity in drug-free conditions, regardless of whether this
infectivity is affected by the presence of resistance mutations. The
selection of any resistance mutation, however, is a function of both
its impact in terms of resistance, as expressed by the IC50
and IC90 values for the virus, and its effect on virus
infectivity both in the presence and in the absence of inhibitors. In
fact, the probability of selection of any resistance mutation is a
function of the concentration of drug at the site of virus replication: at a low drug concentration, the selective pressure will be
insufficient to ensure the emergence of mutations that induce high
levels of resistance but may significantly reduce drug-free virus
infectivity, while at high drug concentrations, the pressure will be to
high for selection of mutations that confer only low-level resistance. Therefore, each HIV variant carrying one or several PI resistance mutations should be best characterized by describing the range of drug
concentrations for which it is advantaged relative to its parent strain
and the extent of this selective advantage as a function of drug concentration.
In this study, we have examined the effect of single and combined amino
acid substitutions in HIV-1 PR both in terms of resistance to PIs and
in terms of drug-free infectivity of the virus. These mutants are
representative of the described pathways of in vivo selection for HIV
resistance to indinavir (IDV), ritonavir (RTV), and saquinavir (SQV)
(9, 31, 33, 42, 47), three PIs often used in current
antiretroviral regimens. Additionally, for each mutant we have
determined the level of its selective advantage relative to wild-type
virus over a range of drug concentrations, thus defining a unique and
characteristic "fitness profile." The fitness profiles that were
calculated for viruses representing each of the mutational pathways
studied were fully consistent with the observations made in vivo
regarding the order of appearance of the mutations in treated patients.
Therefore, we show that by integrating in vitro the main parameters of
the selection for drug resistance, drug-free infectivity, resistance,
and drug concentration, it is possible to anticipate the pattern of
accumulation of resistance mutations in HIV-1 PR.
| |
MATERIALS AND METHODS |
Plasmid construction.
To construct a convenient vector for
site-directed mutagenesis of HIV-1 PR, we cloned the fragment
encompassing the entire PR sequence of pNL-4.3XCS into
pBlueScript-SKII+ (Stratagene), generating plasmid SK-PR. The HIV-1
proviral clone pNL-4.3XCS is a modification of the molecular clone
pNL-4.3 in which an XbaI site has been inserted immediately
upstream of the PR coding sequence together with a ClaI site
immediately downstream (generating pNL-4.3CX) (38) and which
carries a SnaB1 site inserted by silent mutagenesis at
position 3872. The Quick-change site-directed mutagenesis kit (Stratagene) was used to alter residues in the PR coding region of
SK-PR, using for each mutation a positive- and a negative-strand oligonucleotide, according to the manufacturer's instructions. The
mutated PR sequences were used to replace the corresponding fragment of
pNL-4.3XCS, generating full-length mutant clones carrying typical RTV,
IDV, and SQV resistance mutations. Mutant clones contained single PR
mutations or combinations of two, three, and four mutations, retracing
the accumulation pathways observed in treated patients.
The positive-strand oligonucleotides used in the mutagenesis procedure
were as follows: L10-I+,
5'-CTCTTTGGCAGCGACCCATCGTCACAATAAAGATAG-3'; M36-I+,
5'-CAGTATTAGAAGAAATTAATTTGCCAGGAAGATGG-3'; M46-I+,
5'-GAAGATGGAAACCTAAGATAATAGGGGGAATTG-3'; G48-V+,
5'-CAAAACCAAAAATGATAGTGGGGATCGGAGGTTTTATCAAAC-3'; I54-V+, 5'-GAATTGGAGGTTTTGTCAAAGTGAGACAGTATGATCAG-3'; A71-V+,
5'-GAAATCTGCGGACATAAAGTTATAGGTACAGTATTAG-3'; V82-A+,
5'-GGACCTACACCTGCCAACATAATTGG-3'; and L90-M+,
5'-CAACATAATTGGAAGAAATCTCATGACTCAGATTGGCTGCAC-3'.
Negative-strand oligonucleotide sequences were antiparallel to those of
the positive-strand
oligonucleotides.
Cell cultures and PI resistance assay.
HeLa cells and P4
cells (HeLa-CD4, LTR-lacZ) (8) were cultivated in
Dulbecco's modified Eagle's medium supplemented with 10% fetal calf
serum and antibiotics. P4 cells were cultured in the presence of
geneticin (500 µg/ml).
Subconfluent HeLa cells in 25-cm
2 flasks were transfected
with 8 µg of HIV proviral plasmid DNA by the calcium phosphate
precipitation
method. After 18 h, the transfected HeLa cells were
trypsinized
and split into 200-µl subcultures in triplicate in
96-well plates
in the presence of increasing concentrations of protease
inhibitor
(0, 1, 5, 25, 125, 625, and 3,125 nM for RTV and IDV and 0, 0.064,
0.32, 1.6, 8, 40, 200, and 1,000 nM for SQV). After 30 h of
treatment,
viral supernatants containing equivalent amounts of p24
antigen
from each subculture were used to infect subconfluent P4 cells
cultures in 96-well plates in the presence of DEAE-dextran (20
µg/ml). The p24 concentration was measured for PI-naive subcultures
and extrapolated for treated subcultures originating from the
same
transfection experiment. Forty hours after infection of P4
cells, the
single-cycle titer of viruses produced in the presence
of the inhibitor
was determined by quantification of the
-galactosidase
activity in
P4 lysates, using a colorimetric assay (termed here
the CPRG assay)
based on the cleavage of
chlorophenolred-
-
D-galactopyranoside
(CPRG) by
-galactosidase (adapted from Eustice et al. [
21]).
Briefly, following elimination of the supernatant, the P4 cells
were
lysed in 100 µl of lysis buffer (MgCl
2, 5 mM; NP-40,
0.1%
in phosphate-buffered saline). After incubation for 5 min at room
temperature, 100 µl of reaction buffer (CPRG [6 mM] in lysis
buffer)
was added to the cell lysates and incubated for between 5 min
and 2 h at 37°C. Optical densities in the reaction wells were
read at 570 nm with a reference filter set at 690 nm. The
susceptibility
of the different viruses to PIs was expressed as the
concentration
of inhibitor that inhibited 50 or 90% of infectious
events (IC
50 and IC
90, respectively). Fold
change in susceptibility to PI was
calculated as the ratio of the
IC
90 values for mutant viruses
to the corresponding value
for wild-type
virus.
The 40-h infection time was adopted after careful assessment that the
CPRG signal corresponded to single-cycle infections.
This was
established by comparison with the signal obtained when
zidovudine was
added 6 h after infection to prevent subsequent
virus replication
cycles. Expression and accumulation of
-galactosidase
in infected P4
cells requires several hours, and at 40 h the signal
increases
linearly with the infectious
titer.
Infectivity assays.
The single-cycle titer of the
recombinant viruses was measured on indicator P4 cells. Briefly,
triplicate subconfluent P4 cells in 96-well plates were infected with
the equivalent of 5 and 10 ng of HIV-1 p24 of the different viruses
obtained by transfection of HeLa cells in the presence of 20 µg of
DEAE-dextran per ml. The infectious titer was measured using the CPRG
assay and expressed as a percentage of wild-type infectivity.
Fitness profile assay.
To determine the replicative
advantage of mutant viruses as a function of PI concentration, we
performed resistance assays as described above, except that instead of
calculating IC90 values, we calculated the ratio of mutant
to wild-type infectivity (in CPRG units) for each drug concentration
and for each mutant. The ratios were then interpolated as a continuous
profile across the range of different drug concentrations tested using
Microsoft Excel. A minimum of three independent experiments were
performed for each of the mutants, and the curves shown in Fig. 3, 4,
and 5 represent the averages of the values obtained for each drug concentration. With the wild-type infectivity set as the reference, the
curve representing a mutant virus will be above the wild-type reference
line for drug concentrations at which the mutant displayed a
replicative advantage. The height of the peak is proportional to the
extent of the replicative advantage.
| |
RESULTS |
Effect of mutations in PR on resistance to PIs.
A large series
of virus mutants were reconstructed in a variant of the pNL4-3 HIV-1
molecular clone according to the combinations of mutations typically
observed in patients treated with RTV, IDV, or SQV (9, 31, 42,
47). We first determined the impact of amino acid substitutions
in the HIV-1 PR domain on resistance to RTV, IDV, and SQV. For each
mutant we calculated the fold change in susceptibility to the
inhibitors as the ratio of their IC50 or IC90
values to those for wild-type virus. Mean fold changes based on
IC90 values for the different mutants are reported in Fig.
1. None of the single mutants displayed a
significant increase in resistance to RTV except V82A, which was
slightly but reproducibly less sensitive than wild-type virus (Fig.
1A). Combinations of two or more mutations were required to attain
significant resistance, the level of which generally increased with the
number of mutations, as expected. However, some combinations of
mutations clearly conferred higher levels of resistance than others.
This trend was conserved when resistance based on IC50
values was compared (not shown).
View larger version (21K):
[in this window]
[in a new window]
|
FIG. 1.
PI resistance conferred by mutations in HIV-1 PR.
Resistance to PIs was calculated for each PR mutant on the basis of
IC90 values as fold increase with respect to wild-type (WT)
NL-4.3 virus. Average values with standard deviation are shown for RTV
(A), IDV (B), and SQV (C). Note that different scales are used for
different inhibitors.
|
|
The same mutations in PR are usually observed in patients treated with
RTV and in those treated with IDV, but while the accumulation
of
resistance mutations to RTV in vivo follows a conserved pathway,
most
often starting with the substitution at position 82 (
33),
evolution of resistance to IDV lacks such a landmark (
9,
10).
Analysis of resistance to IDV for the same series of mutant
viruses
showed that all single mutants were at least as sensitive as
wild-type
virus to IDV (Fig.
1B), as previously reported (
9,
10). Only
one of the three double mutants analyzed (mutant
A71V-V82A) displayed
a small but reproducible increase in resistance.
Significant resistance
could be observed only with the clone carrying
four resistance
mutations. Overall, the fold changes in susceptibility
measured
with IDV were lower than those obtained with RTV, indicating
particular
constraints to the development of resistance to
IDV.
Resistance to SQV is characterized by the appearance of mutations G48V,
L90M, and V82A, with the addition of mutations, like
L10I, proposed to
compensate for the structural modifications
induced by primary changes.
Different combinations of these mutations
were frequently observed in
SQV-treated patients except for mutations
V82A and L90M, which have
been previously reported as often being
mutually exclusive. The reduced
SQV susceptibility measured with
different PR mutants (Fig.
1C)
justifies previous observations
made in treated patients and in in
vitro virus cultures. The mutation
G48V alone is sufficient for
significant SQV resistance and was
found in all combinations of
mutations that conferred high-level
resistance. This mutation is more
frequently observed in patients
in whom virus exposure to SQV is high
due to more bioavailable
formulations of the drug than in patients in
whom SQV pressure
is lower and in whom HIV-1 often displays L90M as a
genetic marker
of SQV resistance (
6,
42,
46,
47,
50). In our
analysis,
L90M conferred a small but reproducible increase in SQV
resistance.
Viruses carrying both G48V and L90M mutations were markedly
resistant,
and if the L10I substitution was added, the fold increase in
resistance
was the highest observed in our study. Surprisingly, in the
NL-4.3
background, the V82A substitution did not confer significant
resistance
to SQV, and its addition to different combinations of
mutations
did not augment the resistance level. Finally, in our system,
mutants carrying both V82A and L90M displayed even higher sensitivity
to SQV than wild-type virus. The resistance levels measured with
our
assay are somewhat lower than those obtained in systems based
on
multiple virus replication cycles using primary virus isolates
(
33). Nonetheless, the high reproducibility of our results
allows
accurate detection of small differences between individual
clones.
Both the resistance impact of the individual mutations
described
here and the finding that resistance to PIs increases with
the
number of PR mutations are in agreement with previous reports
in
which different techniques and target cells were used (
4,
9,
10,
26,
33,
36,
39).
Impact of resistance mutations on viral infectivity.
We and
others have previously observed that viral variants carrying PI
resistance mutations display a variable reduction in drug-free virus
infectivity, often termed viral fitness (11, 29, 32, 43,
51). Here we determined the impact of single and combined
mutations in the PR on drug-free virus infectivity, measured in a
highly reproducible single-cycle infectivity assay (7, 8, 30,
51). For each of the mutants described above, we measured the
infectivity of viral particles produced in drug-free cultures as a
percentage of that of wild-type NL-4.3XCS virus. Most viral clones
carrying single RTV or IDV resistance mutations were characterized by
wild-type levels of infectivity (Fig.
2A). Interestingly, mutants with two
mutations could be as infectious as wild-type virus (mutant A71V-V82A)
or markedly impaired (mutant I54V-V82A). The same was true for the
different combinations of three mutations. Wild-type infectivity was
also observed for the clone carrying four mutations. Comparison of the
infectivity of the different clones suggests that mutation I54V, which
had no major impact on drug-free virus fitness when expressed alone, markedly decreased the infectivity of viral clones when other resistance mutations were present. This effect seemed to be neutralized to some extent by the addition of the substitution A71V.
View larger version (41K):
[in this window]
[in a new window]
|
FIG. 2.
Resistance-associated loss of viral infectivity.
Drug-free infectivity of PR mutants of the RTV/IDV series (A) and SQV
series (B) is shown as a percentage of wild-type (WT) NL-4.3 virus.
Average values with standard deviation are illustrated.
|
|
The infectivities of viral clones carrying SQV resistance mutations are
shown in Fig.
2B. The G48V mutation associated with
high-level SQV
resistance markedly affected viral infectivity
whether expressed alone
or in combination with other mutations.
We previously described this
phenomenon working on viral clones
carrying patient-derived viral PR
alleles (
51). In line with
the observations of other
authors, the rare combination of V82A
and L90M determined a marked
reduction in viral infectivity, which
could be only partially rescued
by the compensatory mutation L10I.
Addition of mutation L10I had a
similar effect on the infectivity
of clones G48V-V82A and G48V-L90M.
Selective advantage as a function of drug concentration: the
fitness profiles.
To determine the range of drug concentrations
for which each combination of mutations conferred a replicative
advantage and the extent of this advantage, we traced fitness profiles
for each of the mutants, representing the ratio of infectivity (in CPRG units) with respect to wild-type virus in variable drug concentrations (Fig. 3 and 4). From these comparisons,
we could determine that mutation V82A conferred a small but
reproducible replicative advantage in the presence of RTV
concentrations ranging from 20 to 400 nM (Fig. 3A). For lower drug
concentrations, this mutant displayed wild-type infectivity, while for
higher drug concentrations, both wild-type and V82A mutant viruses were
noninfectious. Again, none of the other single mutants analyzed
displayed a replicative advantage with respect to wild-type virus.
Caution should be used in interpreting minor differences in profiles at
relatively high drug concentrations, at which wild-type virus
infectivity is close to 0 CPRG units. Viruses carrying multiple
mutations in the PR generally showed significant differences from
wild-type virus (Fig. 3B; note the different scale with respect to Fig.
3A). A marked replicative advantage was observed for mutant A71V-V82A
in the presence of drug concentrations of up to 1,000 nM. Mutant
M46I-V82A replicated to a lower extent than V71A-V82A in low drug
concentrations, but it was infectious even when produced in medium
containing high concentration of RTV. The two mutants carrying a
combination of three mutations in the PR gene had remarkably different
phenotypes, showing that A71V was a more advantageous addition to
I54V-V82A than was M46I, in terms of both extent of replication and
range of inhibitor concentrations at which some infectivity was
preserved. The mutant virus carrying four substitutions in the PR was
characterized by a very high infectivity titer over a wide range of RTV
concentrations, confirming that high-level resistance to PIs relies on
the accumulation of several mutations.
View larger version (28K):
[in this window]
[in a new window]
|
FIG. 3.
Fitness profiles: virus infectivity as a function of RTV
and IDV concentration. Infectivity was measured for wild-type and PR
mutant viruses in a range of PI concentrations. The ratio of mutant to
wild-type infectivity (in CPRG units) was determined in the presence of
various RTV (A and B) and IDV (C and D) concentrations. Viruses
carrying single PR mutations are reported in panels A and C, while
mutants carrying multiple resistance mutations are reported in panels B
and D. The profiles shown correspond to the average values of at least
three independent experiments. In panel B we used a different
infectivity scale because of the high-level resistance to RTV reached
by some mutant viruses.
|
|
Two main characteristics distinguished the curves describing resistance
to IDV for the same series of mutant viruses (Fig.
3C and D): lower
peaks, indicating that mutations conferred a
smaller advantage with
respect to RTV, and limitation of mutant
virus infectivity at low IDV
concentrations. Both of these findings
reflect the difficulty that
HIV-1 encounters in developing high-level
resistance to IDV. Among the
single mutants, only A71V surfaced
over the wild-type infectivity
threshold, while A71V-V82A seemed
preferable to M46I-V82A in terms of
both infectivity and range
of IDV resistance, although limited to very
low drug concentrations.
As in the analysis performed with RTV, mutant
I54V-A71V-V82A showed
significant infectivity in the presence of IDV,
and a marked advantage
could be determined for the mutant virus
carrying four mutations
in the PR. The resistance-associated loss of
viral fitness seems
to be a limiting factor and may be responsible for
the replicative
disadvantage of virus M46I-I54V-V82A even in the
presence of
IDV.
Analysis of curves from SQV-resistant viruses (Fig.
4) clearly showed the advantage conferred
by mutation L90M in low drug
concentrations and the requirement for
G48V to resist high concentrations
of SQV. Less-expected features were
the remarkable level of infectivity
of mutant L10I-G48V-L90M in
different SQV concentrations and the
resistance of mutant
L10I-G48V-V82A to a wide range of inhibitor
concentrations, although
for this virus the flat shape of the
fitness profile indicated only a
limited advantage. The phenotype
of mutant L10I-G48V-L90M was even more
impressive when compared
to the profiles of mutants carrying
combinations of two of the
three mutations involved, which at the most
showed a threefold
advantage over wild-type virus. Finally, under no
condition did
mutants carrying both V82A and L90M present an advantage,
reflecting
the rare observation of such a combination in SQV resistance
pathways
both in patients and in virus culture.
View larger version (21K):
[in this window]
[in a new window]
|
FIG. 4.
Fitness profiles: virus infectivity as a function of SQV
concentration. As in Fig. 3, the ratio of mutant to wild-type
infectivity (in CPRG units) was determined in the presence of various
SQV concentrations. Viruses carrying single PR mutations are shown in
panel A, while mutants carrying multiple resistance mutations are shown
in panel B (note different scales). The profiles shown correspond to
the average values of at least three independent experiments.
|
|
Role of compensatory mutations in Gag.
We and others have
previously reported that mutations in Gag cleavage sites can partially
restore the viral infectivity of an HIV-1 PR mutant (16, 30,
52). In particular, we described an RTV-resistant patient-derived
virus that, besides developing PR mutations I54V and V82A (one of the
combinations of mutations analyzed here), displayed a Gag cleavage site
amino acid change (A431V) associated with a significant rescue of
drug-free infectivity. Here we measured the impact of this Gag cleavage
site mutation on the reconstructed clone carrying the PR mutations I54V
and V82A in different RTV concentrations (Fig.
5). Mutant I54V-V82A failed to display
significant replicative advantage with respect to wild-type virus at
any RTV concentration (Fig. 4B and 5A), despite the relatively frequent
detection of this combination of mutations in treated patients
(47). The addition of the A431V Gag mutation significantly
increased the infectivity of this mutant virus over a wide range of RTV
concentrations (Fig. 5A). Interestingly, in the presence of variable
IDV concentrations (Fig. 5B), the presence of the Gag A431V
substitution largely compensated for the resistance-associated loss of
viral fitness of mutant I54V-V82A, producing a fitness profile similar
to that of the wild type. Although this clone does not display a
replicative advantage over the wild type in the presence of IDV, it may
represent a viable intermediate for the subsequent accumulation of
mutations in PR, in agreement with the reported high frequency of Gag
cleavage site mutations in viruses from IDV-treated patients
(52).
View larger version (17K):
[in this window]
[in a new window]
|
FIG. 5.
Effect of compensatory mutations in Gag cleavage sites.
Comparison of fitness profiles for PR mutant I54V-V82A with and without
compensatory changes in a Gag cleavage site (mutation A431V) in the
presence of various concentrations of RTV (A) and IDV (B).
|
|
From these data, one can speculate that the emergence of combinations
of mutations that markedly decrease PR function and
HIV fitness in
treated patients may depend on the presence of
compensatory mutations
in
Gag.
| |
DISCUSSION |
When HIV-1 escapes PI therapy, viral replication under the
selective pressure of these compounds leads to the emergence of amino
acid substitutions that reduce inhibitor affinity for the mutated PR
and thereby promote resistance. The selection of resistance mutations
is a function of three main parameters: (i) the frequency of their
introduction in the viral genome during replication; (ii) the
concentration of inhibitor at the site of selection; and (iii) the
impact of the mutations on the enzymatic performance of PR and
therefore on the replicative fitness of the virus as a function of drug
concentration. Here, we will only consider the last two of these
parameters and will disregard the frequency of nucleotide
misincorporation events during viral DNA synthesis by reverse
transcriptase (40). Thus, we will assume that before introduction of therapy, the heterogeneous population of HIV-1 quasispecies that is characteristic of RNA viruses in vivo
(15) potentially generates equal proportions of any variant
bearing a single PI resistance mutation. All the amino acid
substitutions analyzed here may be generated by a single nucleotide
change in the corresponding codon.
Early stages of the selection for PI resistance.
During the
process of selection for HIV drug resistance in vivo, each mutant
quasispecies confronts different conditions of competitive growth
relative to its parental wild-type counterpart and relative to other
mutants, in tissue compartments where the concentration of inhibitor
can vary. Resistance per se, as usually expressed by the
IC50 and/or IC90 values for a virus, merely
reflects the fraction of the viral replicative capacity that is reduced by a particular concentration of drug, regardless of the drug-free replicative capacity of the virus. On the other hand, drug-free infectivity, often termed viral fitness, does not take into account the
selective advantage of a mutant in the presence of inhibitor. Here, we
have devised a novel method of evaluation of the selective value of
HIV-1 variants carrying mutations associated with resistance and viral
escape to PIs, which is based on the assessment of the replicative
advantage of the mutant relative to wild-type virus in the presence of
different concentrations of inhibitors. Although fitness was not
assessed using traditional growth competition experiments, the rapid
single-cycle infectivity assay used here was reproducible and sensitive
enough to allow fitness comparisons involving multiple HIV-1 variants
and multiple drug concentrations.
Using the separate methods of assessment of resistance and infectivity,
but more precisely using the novel fitness profiles
method, we found
that when present as single mutations, most of
the amino acid
substitutions that are part of the combinations
known to mediate HIV-1
resistance to PIs do not confer any selective
advantage to the virus,
whatever the concentration of inhibitor.
There are two notable
exceptions: mutation V82A, which appears
to confer a reproducible
selective advantage in the presence of
relatively low concentrations of
RTV, and mutation L90M, which
confers significant selective advantage
in the presence of SQV.
Interestingly, these two mutations are
consistently found to be
the first to emerge during in vivo HIV-1
escape to RTV and SQV
therapy, respectively (
6,
33). As for
mutant G48V, for which
the traditional evaluation of resistance by
IC
90 measurement revealed
a significant level of
resistance, it did not appear to be significantly
advantaged even under
strong SQV pressure in the absence of an
accessory mutation such as
L10I. This finding must relate to the
fact that mutant G48V
consistently displays a marked reduction
in drug-free replicative
capacity, which is likely to prevent
its efficient selection in spite
of significant resistance. Regarding
resistance to IDV, the multiple
genetic pathways leading to resistance
to this drug in treated patients
consistently involve mutations
at position 46 and/or 82, with further
accumulation of substitutions
at position 71 and/or 54, among others
(
9,
52). Such disordered
development of resistance is fully
justified by the lack of selective
advantage for any of the single
mutants analyzed here (Fig.
3C).
Evolution toward higher levels of resistance.
The gradual
accumulation of resistance mutations resulted in a notable increase in
the extent and the range of the selective advantage displayed by the
corresponding viruses. In the presence of RTV, we found that variants
carrying combinations of A71V with V82A among other mutations were
clearly the most efficient viruses, with the maximal advantage obtained
for the mutant carrying all four of the tested substitutions in
combination. This mutant, which appeared as fit as wild-type virus when
tested in drug-free conditions, was considerably more efficient than
wild-type virus and than viruses carrying fewer mutations over a wider
range of both RTV and IDV concentrations. It has to be emphasized that although the same substitutions have been described in viruses escaping
IDV or RTV therapy, resistance to RTV, whether expressed as traditional
IC90 values or by the viral fitness profile, was always
markedly more pronounced than resistance to IDV. In the presence of
SQV, the most favorable combination associated mutations L10I, G48V,
and L90M, a combination that is often observed in viruses escaping SQV
in vivo. Similar to what was seen with RTV, this "optimal"
combination markedly outperformed the other mutants both in the extent
of the replicative performance and in the range of drug concentrations
over which this advantage could be perceived. Overall, our findings
explain why the selection for resistance to PIs is a gradual process,
with only a marginal advantage conferred by the first mutations
selected. Unlike mutations that mediate resistance to other compounds,
such as lamivudine (3TC) and nonnucleosidic reverse transcriptase
inhibitors, single mutations in PR are unable to lead to rapid
outgrowth of resistant virus selected from quasispecies present even
before therapy. Resistance to PIs can only be detected following the
accumulation of two or more mutations, leading to a gradual increase in
the range and extent of the replicative advantage. Because this process
requires that HIV-1 continue to replicate in the presence of
treatment, it is crucial that treatment with PIs achieve nearly
complete suppression of viral replication in order to avoid the
emergence of resistance.
Importance of drug levels for the development of resistance.
In individuals receiving antiretroviral therapy, the concentration of
drug in peripheral blood can vary greatly over time during a single
day, the result of discontinuous oral drug intake by patients and of
more or less rapid drug inactivation by the natural clearance systems
of the body (28, 34, 44). Drug concentrations are also
presumed to vary widely from one anatomical compartment to another,
with some compartments often considered possible sanctuaries for virus
replication in spite of therapy (2, 13, 48). Virus variants
bearing one particular mutation will therefore encounter different
conditions of drug selective pressure within an infected individual.
Upon analysis of the fitness profile of any given mutant, it is easy to
determine which conditions of drug concentration will allow its
emergence in competition with its parental wild-type counterpart.
Therefore, even if these conditions are met only at certain periods or
within particular anatomical compartments, one can envision that
selection will follow successive fitness leaps depending on the virus
phenotype and on its environment. In this respect, it is striking to
observe that in some treated patients escaping a first line of therapy with a PI, resistance mutations do not appear to accumulate in spite of
a high level of virus replication, as reflected by high amounts of
virus in plasma (14, 25). In these patients, we propose that
during peaks of high drug concentration or within compartments where
drug concentration is high, the fitness of single PR mutants is
insufficient to allow their initial selection, accounting for the
subsequent accumulation of mutations. On the other hand, during troughs
of low drug concentration or in compartments poorly permeated by the
drug, the mutants are outgrown by wild-type virus, ensuring high viral
load. It is remarkable that this phenomenon appears to have been
described mostly in patients treated with IDV, a drug for which we
clearly show here the fitness margin for selection of resistant mutants
is strikingly narrower than for RTV and SQV. Overall, we believe that
the examination of virus behavior using the fitness profile method will
allow further understanding of the mechanisms of selection of HIV-1
drug resistance and may prove useful for the management of
antiretroviral therapy in HIV-infected patients.
| |
ACKNOWLEDGMENTS |
This work was supported in part by a grant from the Agence
Nationale de Recherche sur le SIDA (ANRS). F.M. was the recipient of a
SIDACTION fellowship.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Laboratoire de
Recherche Antivirale, IMEA/INSERM Hôpital Bichat-Claude Bernard,
46 rue H. Huchard, 75018 Paris, France. Phone: 33-1-4025 6359. Fax: 33-1-4025 6370. E-mail: mammano{at}bichat.inserm.fr.
| |
REFERENCES |
| 1.
|
Ashorn, P.,
T. J. McQuade,
S. Thaisrivongs,
A. G. Tomasselli,
W. G. Tarpley, and B. Moss.
1990.
An inhibitor of the protease blocks maturation of human and simian immunodeficiency viruses and spread of infection.
Proc. Natl. Acad. Sci. USA
87:7472-7476[Abstract/Free Full Text].
|
| 2.
|
Aweeka, F.,
A. Jayewardene,
S. Staprans,
S. E. Bellibas,
B. Kearney,
P. Lizak,
T. Novakovic-Agopian, and R. W. Price.
1999.
Failure to detect nelfinavir in the cerebrospinal fluid of HIV-1-infected patients with and without AIDS dementia complex.
J. Acquired Immune Defic. Syndr. Hum. Retrovirol.
20:39-43[Medline].
|
| 3.
|
Barrie, K. A.,
E. E. Perez,
S. L. Lamers,
W. G. Farmerie,
B. M. Dunn,
J. W. Sleasman, and M. M. Goodenow.
1996.
Natural variation in HIV-1 protease, Gag p7 and p6, and protease cleavage sites within Gag/Pol polyproteins: amino acid substitutions in the absence of protease inhibitors in mothers and children infected by human immunodeficiency virus type 1.
Virology
219:407-416[CrossRef][Medline].
|
| 4.
|
Boden, D., and M. Markowitz.
1998.
Resistance to human immunodeficiency virus type 1 protease inhibitors.
Antimicrob. Agents Chemother.
42:2775-2783[Free Full Text].
|
| 5.
|
Borman, A. M.,
S. Paulous, and F. Clavel.
1996.
Resistance of human immunodeficiency virus type 1 to protease inhibitors: selection of resistance mutations in the presence and absence of the drug.
J. Gen. Virol.
77:419-426[Abstract/Free Full Text].
|
| 6.
|
Boucher, C.
1996.
Rational approaches to resistance: using saquinavir.
AIDS
10(Suppl. 1):S15-S19.
|
| 7.
|
Carron de la Carriere, L.,
S. Paulous,
F. Clavel, and F. Mammano.
1999.
Effects of human immunodeficiency virus type 1 resistance to protease inhibitors on reverse transcriptase processing, activity, and drug sensitivity.
J. Virol.
73:3455-3459[Abstract/Free Full Text].
|
| 8.
|
Charneau, P.,
G. Mirambeau,
P. Roux,
S. Paulous,
H. Buc, and F. Clavel.
1994.
HIV-1 reverse transcription: a termination step at the center of the genome.
J. Mol. Biol.
241:651-662[CrossRef][Medline].
|
| 9.
|
Condra, J. H.,
D. J. Holder,
W. A. Schleif,
O. M. Blahy,
R. M. Danovich,
L. J. Gabryelski,
D. J. Graham,
D. Laird,
J. C. Quintero,
A. Rhodes,
H. L. Robbins,
E. Roth,
M. Shivaprakash,
T. Yang,
J. A. Chodakewitz,
P. J. Deutsch,
R. Y. Leavitt,
F. E. Massari,
J. W. Mellors,
K. E. Squires,
R. T. Steigbigel,
H. Teppler, and E. A. Emini.
1996.
Genetic correlates of in vivo viral resistance to indinavir, a human immunodeficiency virus type 1 protease inhibitor.
J. Virol.
70:8270-8276[Abstract].
|
| 10.
|
Condra, J. H.,
W. A. Schleif,
O. M. Blahy,
L. J. Gabryelski,
D. J. Graham,
J. C. Quintero,
A. Rhodes,
H. L. Hobbins,
E. Roth,
M. Shivaprakash,
D. L. Titus,
T. Yang,
H. Teppler,
K. E. Squires,
P. J. Deutsch, and E. A. Emini.
1995.
In vivo emergence of HIV-1 variants resistant to multiple protease inhibitors.
Nature
374:569-571[CrossRef][Medline].
|
| 11.
|
Croteau, G.,
L. Doyon,
D. Thibeault,
G. McKercher,
L. Pilote, and D. Lamarre.
1997.
Impaired fitness of human immunodeficiency virus type 1 variants with high-level resistance to protease inhibitors.
J. Virol.
71:1089-1096[Abstract].
|
| 12.
|
Debouck, C., and B. W. Metcalf.
1990.
Human immunodeficiency virus protease a target for AIDS therapy.
Drug Dev. Res.
21:1-17.
|
| 13.
|
Denissen, J. F.,
B. A. Grabowski,
M. K. Johnson,
A. M. Buko,
D. J. Kempf,
S. B. Thomas, and B. W. Surber.
1997.
Metabolism and disposition of the HIV-1 protease inhibitor ritonavir (ABT-538) in rats, dogs, and humans.
Drug Metab. Dispos.
25:489-501[Abstract/Free Full Text].
|
| 14.
|
Descamps, D.,
P. Flandre,
V. Calvez,
G. Peytavin,
V. Meiffredy,
G. Collin,
C. Delaugerre,
S. Robert-Delmas,
B. Bazin,
J. P. Aboulker,
G. Pialoux,
F. Raffi, and F. Brun-Vezinet.
2000.
Mechanisms of virologic failure in previously untreated HIV-infected patients from a trial of induction-maintenance therapy. Trilege (Agence Nationale de Recherches sur le SIDA 072) Study Team.
JAMA
283:205-211[Abstract/Free Full Text].
|
| 15.
|
Domingo, E.,
C. Escarmis,
N. Sevilla, and E. Baranowski.
1998.
Population dynamics in the evolution of RNA viruses.
Adv. Exp. Med. Biol.
440:721-727[Medline].
|
| 16.
|
Doyon, L.,
F. Poulin,
L. Pilote,
C. Clouette,
D. Thibeault,
G. Croteau, and D. Lamarre.
1996.
Second locus involved in human immunodeficiency virus type 1 resistance to protease inhibitors.
J. Virol.
70:3763-3769[Abstract].
|
| 17.
|
Dreyer, G. B.,
B. W. Metcalf,
T. A. Tomaszek, Jr.,
T. J. Carr,
A. C. d. Chandler,
L. Hyland,
S. A. Fakhoury,
V. W. Magaard,
M. L. Moore,
J. E. Strickler, et al.
1989.
Inhibition of human immunodeficiency virus 1 protease in vitro: rational design of substrate analogue inhibitors.
Proc. Natl. Acad. Sci. USA
86:9752-9756[Abstract/Free Full Text].
|
| 18.
|
Erickson, J., and D. Kempf.
1994.
Structure-based design of symmetric inhibitors of HIV-1 protease.
Arch. Virol. Suppl.
9:19-29[Medline].
|
| 19.
|
Erickson, J.,
D. Neidhart,
J. VanDrie,
D. Kempf,
X. Wang,
D. Norbeck,
J. Plattner,
J. Rittenhouse,
M. Turon,
N. Wideburg,
W. Kohlbrenner,
R. Simmer,
R. Helfrick,
D. Paul, and M. Knigge.
1990.
Design, activity, and 2.8 A crystal structure of a C2 symmetric inhibitor complexed to HIV-1 protease.
Science
249:527-533[Abstract/Free Full Text].
|
| 20.
|
Erickson, J. W.
1995.
The not-so-great escape.
Nat. Struct. Biol.
2:523-529[CrossRef][Medline].
|
| 21.
|
Eustice, D.,
P. Feldman,
A. Colberg-Poley,
R. Buckery, and R. Neubauer.
1991.
A sensitive method for the detection of -galactosidase in transfected mammalian cells.
BioTechniques
11:739-743.
|
| 22.
|
Gulick, R. M.,
J. W. Mellors,
D. Havlir,
J. J. Eron,
C. Gonzalez,
D. McMahon,
D. D. Richman,
F. T. Valentine,
L. Jonas,
A. Meibohm,
E. A. Emini, and J. A. Chodakewitz.
1997.
Treatment with indinavir, zidovudine, and lamivudine in adults with human immunodeficiency virus infection and prior antiretroviral therapy.
N. Engl. J. Med.
337:734-739[Abstract/Free Full Text].
|
| 23.
|
Gulnick, S. V.,
L. I. Suvorov,
B. Liu,
B. Yu,
B. Anderson,
H. Mitsuya, and J. W. Erickson.
1995.
Kinetic characterization and cross-resistance patterns of HIV-1 protease mutants selected under drug pressure.
Biochemistry
34:9282-9287[CrossRef][Medline].
|
| 24.
|
Hammer, S. M.,
K. E. Squires,
M. D. Hughes,
J. M. Grimes,
L. M. Demeter,
J. S. Currier,
J. J. Eron, Jr.,
J. E. Feinberg,
H. H. Balfour, Jr.,
L. R. Deyton,
J. A. Chodakewitz, and M. A. Fischl.
1997.
A controlled trial of two nucleoside analogues plus indinavir in persons with human immunodeficiency virus infection and CD4 cell counts of 200 per cubic millimeter or less. AIDS Clinical Trials Group 320 Study Team.
N. Engl. J. Med.
337:725-733[Abstract/Free Full Text].
|
| 25.
|
Havlir, D. V.,
N. S. Hellmann,
C. J. Petropoulos,
J. M. Whitcomb,
A. C. Collier,
M. S. Hirsch,
P. Tebas,
J. P. Sommadossi, and D. D. Richman.
2000.
Drug susceptibility in HIV infection after viral rebound in patients receiving indinavir-containing regimens.
JAMA
283:229-234[Abstract/Free Full Text].
|
| 26.
|
Hertogs, K.,
M. P. de Bethune,
V. Miller,
T. Ivens,
P. Schel,
A. Van Cauwenberge,
C. Van Den Eynde,
V. Van Gerwen,
H. Azijn,
M. Van Houtte,
F. Peeters,
S. Staszewski,
M. Conant,
S. Bloor,
S. Kemp,
B. Larder, and R. Pauwels.
1998.
A rapid method for simultaneous detection of phenotypic resistance to inhibitors of protease and reverse transcriptase in recombinant human immunodeficiency virus type 1 isolates from patients treated with antiretroviral drugs.
Antimicrob. Agents Chemother.
42:269-276[Abstract/Free Full Text].
|
| 27.
|
Ho, D.,
T. Toyoshima,
H. Mo,
D. Kempf,
D. Norbeck,
C. Chen,
N. Wideburg,
S. Burt,
J. Erickson, and M. Singh.
1994.
Characterization of human immunodeficiency virus type 1 variants with increased resistance to a C2-symmetric protease inhibitor.
J. Virol.
68:2016-2020[Abstract/Free Full Text].
|
| 28.
|
Hsu, A.,
G. R. Granneman, and R. J. Bertz.
1998.
Ritonavir: clinical pharmacokinetics and interactions with other anti-HIV agents.
Clin. Pharmacokinet.
35:275-291[CrossRef][Medline].
|
| 29.
|
Kaplan, A.,
S. Michael,
R. Wehbie,
M. Knigge,
D. Paul,
L. Everitt,
D. Kempf,
D. Norbeck,
J. Erickson, and R. Swanstrom.
1994.
Selection of multiple human immunodeficiency virus type 1 variants that encode viral proteases with decreased sensitivity to an inhibitor of the viral protease.
Proc. Natl. Acad. Sci. USA
91:5597-5601[Abstract/Free Full Text].
|
| 30.
|
Mammano, F.,
C. Petit, and F. Clavel.
1998.
Resistance-associated loss of viral fitness in human immunodeficiency virus type 1: phenotypic analysis of protease and gag coevolution in protease inhibitor-treated patients.
J. Virol.
72:7632-7637[Abstract/Free Full Text].
|
| 31.
|
Markowitz, M.,
H. Mo,
D. Kempf,
D. Norbeck,
T. Bhat,
J. Erickson, and D. Ho.
1995.
Selection and analysis of human immunodeficiency virus type 1 variants with increased resistance to ABT-538, a novel protease inhibitor.
J. Virol.
69:701-706[Abstract].
|
| 32.
|
Martinez-Picado, J.,
A. V. Savara,
L. Sutton, and R. T. D'Aquila.
1999.
Replicative fitness of protease inhibitor-resistant mutants of human immunodeficiency virus type 1.
J. Virol.
73:3744-3752[Abstract/Free Full Text].
|
| 33.
|
Molla, A.,
D. Kempf,
M. Korneyeva,
Q. Gao,
P. Shipper,
H. Mo,
M. Markowitz,
S. Vasavanonda,
T. Chernyavskyi,
P. Niu,
N. Lyons,
A. Hsu,
G. Granneman,
D. Ho,
C. Boucher,
J. Leonard, and D. Norbeck.
1996.
Ordered accumulation of mutations in HIV protease confers resistance to ritonavir.
Nat. Med.
2:760-766[CrossRef][Medline].
|
| 34.
|
Moyle, G. J.,
M. Youle,
C. Higgs,
J. Monaghan,
W. Prince,
S. Chapman,
N. Clendeninn, and M. R. Nelson.
1998.
Safety, pharmacokinetics, and antiretroviral activity of the potent, specific human immunodeficiency virus protease inhibitor nelfinavir: results of a phase I/II trial and extended follow-up in patients infected with human immunodeficiency virus.
J. Clin. Pharmacol.
38:736-743[Abstract].
|
| 35.
|
Nijhuis, M.,
R. Schuurman,
D. de Jong,
J. Erickson,
E. Gustchina,
J. Albert,
P. Schipper,
S. Gulnik, and C. A. Boucher.
1999.
Increased fitness of drug resistant HIV-1 protease as a result of acquisition of compensatory mutations during suboptimal therapy.
AIDS
13:2349-2359[CrossRef][Medline].
|
| 36.
|
Parkin, N. T.,
Y. S. Lie,
N. Hellmann,
M. Markowitz,
S. Bonhoeffer,
D. D. Ho, and C. J. Petropoulos.
1999.
Phenotypic changes in drug susceptibility associated with failure of human immunodeficiency virus type 1 (HIV-1) triple combination therapy.
J. Infect. Dis.
180:865-870[CrossRef][Medline].
|
| 37.
|
Patick, A.,
H. Mo,
M. Markowitz,
K. Appelt,
B. Wu,
L. Musick,
V. Kalish,
S. Kaldor,
S. Reich,
D. Ho, and S. Webber.
1996.
Antiviral and resistance studies of AG1343, an orally bioavailable inhibitor of human immunodeficiency virus protease.
Antimicrob. Agents Chemother.
40:292-297[Abstract].
|
| 38.
|
Patick, A.,
R. Rose,
J. Greytock,
C. Bechtold,
M. Hermsmeier,
P. Chen,
J. Barrish,
R. Zahler,
R. Colonno, and P. Lin.
1995.
Characterization of a human immunodeficiency virus type 1 variant with reduced sensitivity to an aminodiol protease inhibitor.
J. Virol.
69:2148-2152[Abstract].
|
| 39.
|
Petropoulos, C. J.,
N. T. Parkin,
K. L. Limoli,
Y. S. Lie,
T. Wrin,
W. Huang,
H. Tian,
D. Smith,
G. A. Winslow,
D. J. Capon, and J. M. Whitcomb.
2000.
A novel phenotypic drug susceptibility assay for human immunodeficiency virus type 1.
Antimicrob. Agents Chemother.
44:920-928[Abstract/Free Full Text].
|
| 40.
|
Preston, B. D.,
B. J. Poiesz, and L. A. Loeb.
1988.
Fidelity of HIV-1 reverse transcriptase.
Science
242:1168-1171[Abstract/Free Full Text].
|
| 41.
|
Ridky, T. W.,
A. Kikonyogo,
J. Leis,
S. Gulnik,
T. Copeland,
J. Erickson,
A. Wlodawer,
I. Kurinov,
R. W. Harrison, and I. T. Weber.
1998.
Drug-resistant HIV-1 proteases identify enzyme residues important for substrate selection and catalytic rate.
Biochemistry
37:13835-13845[CrossRef][Medline].
|
| 42.
|
Roberts, N. A.
1995.
Drug-resistance patterns of saquinavir and other HIV proteinase inhibitors.
AIDS
9:S27-S32.
|
| 43.
|
Rose, R.,
Y. Gong,
J. Greytok,
C. Bechtold,
B. Terry,
B. Robinson,
M. Alam,
R. Colonno, and P. Lin.
1996.
Human immunodeficiency virus type 1 viral background plays a major role in development of resistance to protease inhibitors.
Proc. Natl. Acad. Sci. USA
93:1648-1653[Abstract/Free Full Text].
|
| 44.
|
Sadler, B. M.,
C. D. Hanson,
G. E. Chittick,
W. T. Symonds, and N. S. Roskell.
1999.
Safety and pharmacokinetics of amprenavir (141W94), a human immunodeficiency virus (HIV) type 1 protease inhibitor, following oral administration of single doses to HIV-infected adults.
Antimicrob. Agents Chemother.
43:1686-1692[Abstract/Free Full Text].
|
| 45.
|
Sardana, V. V.,
A. J. Schlabach,
P. Graham,
B. L. Bush,
J. H. Condra,
J. C. Culberson,
L. Gotlib,
D. J. Graham,
N. E. Kohl,
R. L. LaFemina,
C. L. Schneider,
B. S. Wolanski,
J. A. Wolfgang, and E. A. Emini.
1994.
Human immunodeficiency virus type 1 protease inhibitors: evaluation of resistance engendered by amino-acid substitutions in the enzyme substrate binding site.
Biochemistry
33:2004-2010[CrossRef][Medline].
|
| 46.
|
Schapiro, J. M.,
M. A. Winters,
J. Lawrence, and T. C. Merigan.
1999.
Clinical cross-resistance between the HIV-1 protease inhibitors saquinavir and indinavir and correlations with genotypic mutations.
AIDS
13:359-365[CrossRef][Medline].
|
| 47.
|
Schinazi, R. F.,
B. A. Larder, and J. W. Mellors.
1997.
Mutations in retroviral genes associated with drug resistance.
Int. Antiviral News
5:129-137.
|
| 48.
|
Shetty, B. V.,
M. B. Kosa,
D. A. Khalil, and S. Webber.
1996.
Preclinical pharmacokinetics and distribution to tissue of AG1343, an inhibitor of human immunodeficiency virus type 1 protease.
Antimicrob. Agents Chemother.
40:110-114[Abstract].
|
| 49.
|
Winslow, D. L.,
S. Stack,
R. King,
H. Scarnati,
A. Bincsik, and M. J. Otto.
1995.
Limited sequence diversity in the HIV type 1 protease gene from clinical isolates and in vivo susceptibility to HIV protease inhibitors.
AIDS Res. Hum. Retroviruses
11:107-113[Medline].
|
| 50.
|
Winters, M. A.,
J. M. Schapiro,
J. Lawrence, and T. C. Merigan.
1998.
Human immunodeficiency virus type 1 protease genotypes and in vitro protease inhibitor susceptibilities of isolates from individuals who were switched to other protease inhibitors after long-term saquinavir treatment.
J. Virol.
72:5303-5306[Abstract/Free Full Text].
|
| 51.
|
Zennou, V.,
F. Mammano,
S. Paulous,
D. Mathez, and F. Clavel.
1998.
Loss of viral fitness associated with multiple Gag and Gag-Pol processing defects in human immunodeficiency virus type 1 variants selected for resistance to protease inhibitors in vivo.
J. Virol.
72:3300-3306[Abstract/Free Full Text].
|
| 52.
|
Zhang, Y.,
H. Imamichi,
T. Imamichi,
H. Lane,
J. Falloon,
M. Vasudevachari, and N. Salzman.
1997.
Drug resistance during indinavir therapy is caused by mutations in the protease gene and in its Gag substrate cleavage sites.
J. Virol.
71:6662-6670[Abstract].
|
Journal of Virology, September 2000, p. 8524-8531, Vol. 74, No. 18
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Quercia, R., Dam, E., Perez-Bercoff, D., Clavel, F.
(2009). Selective-Advantage Profile of Human Immunodeficiency Virus Type 1 Integrase Mutants Explains In Vivo Evolution of Raltegravir Resistance Genotypes. J. Virol.
83: 10245-10249
[Abstract]
[Full Text]
-
Parry, C. M., Kohli, A., Boinett, C. J., Towers, G. J., McCormick, A. L., Pillay, D.
(2009). Gag Determinants of Fitness and Drug Susceptibility in Protease Inhibitor-Resistant Human Immunodeficiency Virus Type 1. J. Virol.
83: 9094-9101
[Abstract]
[Full Text]
-
Gao, H., Feldman, M. W.
(2009). Complementation and Epistasis in Viral Coinfection Dynamics. Genetics
182: 251-263
[Abstract]
[Full Text]
-
Koh, Y., Das, D., Leschenko, S., Nakata, H., Ogata-Aoki, H., Amano, M., Nakayama, M., Ghosh, A. K., Mitsuya, H.
(2009). GRL-02031, a Novel Nonpeptidic Protease Inhibitor (PI) Containing a Stereochemically Defined Fused Cyclopentanyltetrahydrofuran Potent against Multi-PI-Resistant Human Immunodeficiency Virus Type 1 In Vitro. Antimicrob. Agents Chemother.
53: 997-1006
[Abstract]
[Full Text]
-
Little, S. J., Frost, S. D. W., Wong, J. K., Smith, D. M., Pond, S. L. K., Ignacio, C. C., Parkin, N. T., Petropoulos, C. J., Richman, D. D.
(2008). Persistence of Transmitted Drug Resistance among Subjects with Primary Human Immunodeficiency Virus Infection. J. Virol.
82: 5510-5518
[Abstract]
[Full Text]
-
He, Y., King, M. S., Kempf, D. J., Lu, L., Lim, H. B., Krishnan, P., Kati, W., Middleton, T., Molla, A.
(2008). Relative Replication Capacity and Selective Advantage Profiles of Protease Inhibitor-Resistant Hepatitis C Virus (HCV) NS3 Protease Mutants in the HCV Genotype 1b Replicon System. Antimicrob. Agents Chemother.
52: 1101-1110
[Abstract]
[Full Text]
-
Dykes, C., Demeter, L. M.
(2007). Clinical Significance of Human Immunodeficiency Virus Type 1 Replication Fitness. Clin. Microbiol. Rev.
20: 550-578
[Abstract]
[Full Text]
-
Perez-Bercoff, D., Wurtzer, S., Compain, S., Benech, H., Clavel, F.
(2007). Human Immunodeficiency Virus Type 1: Resistance to Nucleoside Analogues and Replicative Capacity in Primary Human Macrophages. J. Virol.
81: 4540-4550
[Abstract]
[Full Text]
-
Parera, M., Fernandez, G., Clotet, B., Martinez, M. A.
(2007). HIV-1 Protease Catalytic Efficiency Effects Caused by Random Single Amino Acid Substitutions. Mol Biol Evol
24: 382-387
[Abstract]
[Full Text]
-
Hu, Z., Giguel, F., Hatano, H., Reid, P., Lu, J., Kuritzkes, D. R.
(2006). Fitness Comparison of Thymidine Analog Resistance Pathways in Human Immunodeficiency Virus Type 1. J. Virol.
80: 7020-7027
[Abstract]
[Full Text]
-
Wu, H., Huang, Y., Dykes, C., Liu, D., Ma, J., Perelson, A. S., Demeter, L. M.
(2006). Modeling and Estimation of Replication Fitness of Human Immunodeficiency Virus Type 1 In Vitro Experiments by Using a Growth Competition Assay. J. Virol.
80: 2380-2389
[Abstract]
[Full Text]
-
Charpentier, C., Nora, T., Tenaillon, O., Clavel, F., Hance, A. J.
(2006). Extensive Recombination among Human Immunodeficiency Virus Type 1 Quasispecies Makes an Important Contribution to Viral Diversity in Individual Patients. J. Virol.
80: 2472-2482
[Abstract]
[Full Text]
-
Resch, W., Parkin, N., Watkins, T., Harris, J., Swanstrom, R.
(2005). Evolution of Human Immunodeficiency Virus Type 1 Protease Genotypes and Phenotypes In Vivo under Selective Pressure of the Protease Inhibitor Ritonavir. J. Virol.
79: 10638-10649
[Abstract]
[Full Text]
-
van der Hoek, L., Back, N., Jebbink, M. F., de Ronde, A., Bakker, M., Jurriaans, S., Reiss, P., Parkin, N., Berkhout, B.
(2005). Increased Multinucleoside Drug Resistance and Decreased Replicative Capacity of a Human Immunodeficiency Virus Type 1 Variant with an 8-Amino-Acid Insert in the Reverse Transcriptase. J. Virol.
79: 3536-3543
[Abstract]
[Full Text]
-
Bouchonnet, F., Dam, E., Mammano, F., de Soultrait, V., Hennere, G., Benech, H., Clavel, F., Hance, A. J.
(2005). Quantification of the Effects on Viral DNA Synthesis of Reverse Transcriptase Mutations Conferring Human Immunodeficiency Virus Type 1 Resistance to Nucleoside Analogues. J. Virol.
79: 812-822
[Abstract]
[Full Text]
-
Mo, H., Lu, L., Pithawalla, R., Kempf, D. J., Molla, A.
(2004). Complementation in Cells Cotransfected with a Mixture of Wild-Type and Mutant Human Immunodeficiency Virus (HIV) Influences the Replication Capacities and Phenotypes of Mutant Variants in a Single-Cycle HIV Resistance Assay. J. Clin. Microbiol.
42: 4169-4174
[Abstract]
[Full Text]
-
Charpentier, C., Dwyer, D. E., Mammano, F., Lecossier, D., Clavel, F., Hance, A. J.
(2004). Role of Minority Populations of Human Immunodeficiency Virus Type 1 in the Evolution of Viral Resistance to Protease Inhibitors. J. Virol.
78: 4234-4247
[Abstract]
[Full Text]
-
Clavel, F., Hance, A. J.
(2004). HIV Drug Resistance. NEJM
350: 1023-1035
[Full Text]
-
Goodenow, M. M., Rose, S. L., Tuttle, D. L., Sleasman, J. W.
(2003). HIV-1 fitness and macrophages. J. Leukoc. Biol.
74: 657-666
[Abstract]
[Full Text]
-
Perrin, V., Mammano, F.
(2003). Parameters Driving the Selection of Nelfinavir-Resistant Human Immunodeficiency Virus Type 1 Variants. J. Virol.
77: 10172-10175
[Abstract]
[Full Text]
-
Simon, V., Padte, N., Murray, D., Vanderhoeven, J., Wrin, T., Parkin, N., Di Mascio, M., Markowitz, M.
(2003). Infectivity and Replication Capacity of Drug-Resistant Human Immunodeficiency Virus Type 1 Variants Isolated during Primary Infection. J. Virol.
77: 7736-7745
[Abstract]
[Full Text]
-
Matsuoka-Aizawa, S., Sato, H., Hachiya, A., Tsuchiya, K., Takebe, Y., Gatanaga, H., Kimura, S., Oka, S.
(2002). Isolation and Molecular Characterization of a Nelfinavir (NFV)-Resistant Human Immunodeficiency Virus Type 1 That Exhibits NFV-Dependent Enhancement of Replication. J. Virol.
77: 318-327
[Abstract]
[Full Text]
-
Maguire, M. F., Guinea, R., Griffin, P., Macmanus, S., Elston, R. C., Wolfram, J., Richards, N., Hanlon, M. H., Porter, D. J. T., Wrin, T., Parkin, N., Tisdale, M., Furfine, E., Petropoulos, C., Snowden, B. W., Kleim, J.-P.
(2002). Changes in Human Immunodeficiency Virus Type 1 Gag at Positions L449 and P453 Are Linked to I50V Protease Mutants In Vivo and Cause Reduction of Sensitivity to Amprenavir and Improved Viral Fitness In Vitro. J. Virol.
76: 7398-7406
[Abstract]
[Full Text]
-
Shafer, R. W.
(2002). Genotypic Testing for Human Immunodeficiency Virus Type 1 Drug Resistance. Clin. Microbiol. Rev.
15: 247-277
[Abstract]
[Full Text]
-
Quer, J., Hershey, C. L., Domingo, E., Holland, J. J., Novella, I. S.
(2001). Contingent Neutrality in Competing Viral Populations. J. Virol.
75: 7315-7320
[Abstract]
[Full Text]
-
Hance, A. J., Lemiale, V., Izopet, J., Lecossier, D., Joly, V., Massip, P., Mammano, F., Descamps, D., Brun-Vezinet, F., Clavel, F.
(2001). Changes in Human Immunodeficiency Virus Type 1 Populations after Treatment Interruption in Patients Failing Antiretroviral Therapy. J. Virol.
75: 6410-6417
[Abstract]
[Full Text]
-
Trouplin, V., Salvatori, F., Cappello, F., Obry, V., Brelot, A., Heveker, N., Alizon, M., Scarlatti, G., Clavel, F., Mammano, F.
(2001). Determination of Coreceptor Usage of Human Immunodeficiency Virus Type 1 from Patient Plasma Samples by Using a Recombinant Phenotypic Assay. J. Virol.
75: 251-259
[Abstract]
[Full Text]
Top
Abstract
Introduction
