Naturally occurring amino acid polymorphisms in human immunodeficiency virus type 1 (HIV-1) Gag p7(NC) and the C-cleavage site impact Gag-Pol processing by HIV-1 protease

Human immunodeficiency virus type 1 (HIV-1) protease activity is targeted at nine cleavage sites comprising different amino acid sequences in the viral Gag-Pol polyprotein. Amino acid polymorphisms in protease and in regions of Gag, particularly p7(NC) and the C-cleavage site between p2 and p7(NC), occur in natural variants of HIV-1 within infected patients. Studies were designed to examine the role of natural polymorphisms in protease and to identify determinants in Gag that modulate protease processing activity. Closely related Gag-Pol regions from an HIV-1-infected mother and two children were evaluated for processing in an inducible expression system, for protease activity on cleavage-site analogues, and for impact on replication by recombinant viruses. Gag-Pol regions displayed one of three processing phenotypes based on the appearance of Gag intermediates and accumulation of mature p24(CA). Gag-Pol regions that were processed rapidly to produce p24(CA) resulted in high-level replication by recombinant viruses, while slow-processing Gag-Pol variants resulted in recombinant viruses that replicated with reduced kinetics in both T cell lines and peripheral blood mononuclear cells. Direct impact by Gag sequences on processing by protease was assessed by construction of chimeric Gag-Pol regions and by site-directed mutagenesis. Optimal protease activity occurred when Gag and Pol regions were derived from the same gag-pol allele. Heterologous Gag regions generally diminished rates and extent of protease processing. Natural polymorphisms in novel positions in p7(NC) and the C-cleavage site have a dominant effect on protease processing activity. Accumulation of Gag products after processing at the C site appears to delay subsequent cleavage and production of mature p24(CA).     

Natural polymorphisms in the protease gene modulate the replicative capacity of non-B HIV-1 variants in the absence of drug pressure.

BACKGROUND: Genetic variation in the HIV-1 pol gene, which encodes the main targets for anti-HIV drugs, may favors different susceptibility and resistance pathways to antiretroviral agents. Several amino acid substitutions occur frequently in some non-B viruses at positions associated with drug resistance in clade B viruses. The clinical relevance of those polymorphisms is unclear. OBJECTIVE: To evaluate the effect of two natural protease (PR) polymorphisms, K20I and M36I, which are frequently found in non-B subtypes, on the virus replicative capacity in the presence and absence of protease inhibitors (PI). STUDY DESIGN: Infectious HIV-1 clones carrying K20I, M36I or K20I/M36I were designed. Their replication kinetics were analyzed by viral competition in the absence of PI. Susceptibility to six different PI was phenotypically assessed in clones and in recombinant viruses carrying non-B proteases from 16 drug-naive individuals. RESULTS: In the absence of drug, the M36I clone replicated more rapidly than wt (wild type) or the double mutant K20I/M36I. Natural polymorphisms 20I and/or 36I improved the virus replicative capacity under drug pressure, reducing the susceptibility to saquinavir and indinavir, with IC(50) values 2-3.5-fold higher than wt. All but one drug-naive individual carrying non-B viruses were fully susceptibility to all tested PI, suggesting that additional substitutions within the PR might compensate the reduced PI susceptibility caused by K20I and/or M36I. CONCLUSION: Natural PR polymorphisms in non-B HIV-1 variants can influence in vitro the virus replication capacity in the presence and/or absence or certain PI. Hypothetically, the improved viral replication of mutant 36I might favor a more rapid spreading of non-B subtypes of HIV-1.     

The role of lysine residue at amino acid position 165 of human immunodeficiency virus type 1 CRF01_AE Gag in reducing viral drug susceptibility to protease inhibitors

Recombinant human immunodeficiency virus type 1 (HIV-1) containing a CRF01_AE Gag, AE-Gag62, was significantly less susceptible to protease inhibitors (PIs) than the subtype B reference strain, NL4-3; therefore, the mechanism of how AE-Gag62 reduced viral drug susceptibility to PIs was studied in this report. The results showed that the lysine residue at amino acid position 165 (K165) of AE-Gag62 played a role in reducing the drug susceptibility of the recombinant virus to PIs. In addition, K165 potentially appears more frequently in CRF01_AE viruses than in the viruses of other major HIV-1 subtypes. Although K165 had no effect on the extent of recombinant protease-mediated in vitro Gag cleavage, it enhanced the incorporation of the Gag-Pol precursor protein, p160, into virions. Taken together, these results suggest that K165 of CRF01_AE Gag affects the regulation of virion assembly or maturation, and reduces viral drug susceptibility to PIs.     

A novel real-time PCR assay to determine relative replication capacity for HIV-1 protease variants and/or reverse transcriptase variants

The emergence of drug-resistant viruses is a major issue in the treatment of HIV-1 infections. Quite often these drug-resistant viruses have a reduced replication capacity. A novel assay was developed to study the impact of mutations selected during therapy on viral replication capacity. Two HIV-1 HXB2 reference clones were constructed for this assay based on viral competition experiments, which are identical except for the presence of two silent nucleotide changes in p24 in one of the two clones. Within these two reference clones, three different contiguous deletions were constructed: (I) the C-terminus of Gag and protease, (II) the N-terminus of RT and (III) the C-terminus of Gag and protease together with the N-terminus of RT. Using these reference clones, recombinant viruses were created and viral competition experiments were performed. The proportion of each virus during the competition experiments was determined with a real-time PCR assay based on the two silent nucleotide changes in p24 in one of the two reference clones. With this novel assay it was possible to detect accurately differences in replication capacity due to mutations in the C-terminus of Gag and protease and/or the N-terminus of RT.     

Contribution of the Gag-Pol transframe domain p6* and its coding sequence to morphogenesis and replication of human immunodeficiency virus type 1

The human immunodeficiency virus type-1 (HIV-1) transframe domain p6* is located between the nucleocapsid protein (NC) and the protease (PR) within the Gag-Pol precursor. This flexible, 68-amino-acid HIV-1 p6* domain has been suggested to negatively interfere with HIV PR activity in vitro proposing a contribution of either the C-terminal p6* tetrapeptide, internal cryptic PR cleavage sites, or a zymogen-related mechanism to a regulated PR activation. To assess these hypotheses in the viral context, a series of recombinant HX10-based provirus constructs has been established with clustered amino acid substitutions throughout the entire p6* coding sequence. Comparative analysis of the mutant proviral clones in different cell culture systems revealed that mutations within the well-conserved amino-terminal p6* region modified the Gag/Gag-Pol ratio and thus resulted in the release of viruses with impaired infectivity. Clustered amino acid substitutions destroying (i) the predicted cryptic PR cleavage sites or (ii) homologies to the pepsinogen propeptide did not influence viral replication in cell culture, whereas substitutions of the carboxyl-terminal p6* residues 62 to 68 altering proper release of the mature PR from the Gag-Pol precursor drastically reduced viral infectivity. Thus, the critical contribution of p6* and overlapping cis-acting sequence elements to timely regulated virus maturation and infectivity is closely linked to precise ribosomal frameshifting and proper N-terminal release of the viral PR from the Gag-Pol precursor, clearly disproving the hypothesis that sequence motifs in the central part of p6* modulate PR activation and viral infectivity.     

Ubiquitination of HIV-1 and MuLV Gag

Our previous biochemical studies of HIV-1 and MuLV virions isolated and identified mature Gag products, HIV-1 p6(Gag) and MuLV p12(Gag), that were conjugated to a single ubiquitin. To study the importance of the monoubiquitination of Gag, a series of lysine to arginine mutants were constructed that eliminated ubiquitination at one or both of the lysines in HIV-1(NL4-3) p6(Gag) and both lysines in Moloney MuLV p12(Gag). HPLC and immunoblot analysis of the HIV-1 mutants demonstrated that either of the lysines in p6(Gag), K27 or K33, could be monoubiquitinated. However, infectivity assays showed that monoubiquitination of HIV-1 p6(Gag) or MuLV p12(Gag) is not required for viral replication in vitro. Pulse-chase radiolabeling of HIV-1-producing cells revealed that monoubiquitination of p6(Gag) does not affect the short-term release of virus from the cell, the maturation of Pr55(Gag), or the sensitivity of these processes to proteasome inhibitors. Experiments with protease-deficient HIV-1 showed that Pr55(Gag) can be monoubiquitinated, suggesting that p6(Gag) is first modified as a domain within Gag. Examination of the proteins inside an HIV-1 mutant found that free ubiquitin was incorporated into the virions in the absence of the lysines in p6(Gag), showing that the ubiquitin inside the virus is not initially brought in as a p6(Gag) conjugate. Although our results establish that monoubiquitination of p6(Gag) and p12(Gag) is not required for viral replication in vitro, this modification may be a by-product of interactions between Gag and cellular proteins during assembly and budding.     

Impact on replicative fitness of the G48E substitution in the protease of HIV-1: an in vitro and in silico evaluation

We observed an unusual glycine-to-glutamate substitution at protease (PR) residue position 48 (G48E) in an African patient infected with a subtype A1 HIV-1 strain failing a saquinavir-containing regimen. Phenotypic analysis of protease inhibitor (PI) susceptibility showed that the G48E site-directed mutant, when introduced into an NL4-3 HIV-1 PR backbone, was slightly resistant to SQV (2-fold when compared with the wild-type virus). In addition, the G48E and G48E/V82A site-directed mutants were associated with a decrease in fitness, whereas a reversion to the wild type at position 48 was observed in vitro. Growth competition experiments using a novel growth competition assay based on enhanced green fluorescent protein- or Discosoma spp. red fluorescent protein-expressing viruses showed that the replicative fitness of the G48E virus was reduced to 55% compared with the parental NL4-3 virus. Synthesizing all possible site-directed mutants found in the patient strain is too time-consuming; therefore, a molecular dynamics (MD) simulation approach was used to understand why this mutation survived despite its fitness cost. These simulations documented that the G48E mutant interacted with PI resistance mutations (M46I, I54V, Q58E, and L63P) and with natural polymorphisms specific to subtype A1 (E35D, M36I, and R57K) that were present in the patient's virus. We hypothesize that the polymorphisms contained in the PR flap regions of the patient's virus may compensate for the presence of G48E, possibly by restoring the flexibility of the PR flaps. In summary, our results demonstrate that the G48E substitution, when introduced in the context of an HIV-1 subtype B strain, is highly unstable and gives rise to viruses with a poor replicative fitness in vitro. We also showed that when confronted with too many mutations to evaluate in vitro, MD simulations are helpful to draft hypotheses on how polymorphisms can interact with resistance mutations to stabilize their potential fitness cost.     

The SIVmac239 Pr55Gag isoform, SIV p43, suppresses proteolytic cleavage of Pr55Gag

In human immunodeficiency virus type 1 (HIV-1) and simian immunodeficiency virus (SIV) the gag gene encodes the precursor polyprotein Pr55Gag, which is cleaved by the viral protease to produce the major structural proteins. Recently, it has been shown that HIV and SIV gag RNAs contain internal ribosome entry sites (IRESs) that mediate translation of Pr55Gag [Pr57Gag in HIV type 2 (HIV-2)] isoforms. Previously, we demonstrated that SIVmac239 p43(-), a mutant that does not express the Pr55Gag isoform, SIV p43, replicates more efficiently than wild-type (WT) SIVmac239 in cell culture. In this study, we characterize SIVmac239 p43(-) virion production and demonstrate that, in the absence of SIV p43, cleavage of Pr55Gag is increased in budded virions, resulting in a higher percentage of mature particles. Additionally, intracellular cleavage of Pr55Gag is increased in SIVmac239 p43(-), suggesting that SIV p43 suppresses premature cleavage of Pr55Gag by the viral protease.     

Fitness of human immunodeficiency virus type 1 protease inhibitor-selected single mutants

Human immunodeficiency virus type 1 (HIV-1) evolution under chemotherapeutic selection pressure in vivo involves a complex interplay between an increasing magnitude of drug resistance and changes in viral replicative capacity. To examine the replicative fitness of HIV-1 mutants with single, drug-selected substitutions in protease (PR), we constructed virus that contained the most common mutations in indinavir-selected clinical isolates, PR M46I and V82T, and the most common polymorphic change in drug-na?ve patients, PR L63P. These mutants were competed in vitro in the absence of drug against the otherwise isogenic WT virus (NL4-3). Phenotypic drug susceptibility was determined with a recombinant virus assay using a single cycle of virus growth. PR M46I and L63P were as fit as WT. However, PR V82T was out-competed by WT. None of these mutants had appreciable phenotypic resistance to any of the protease inhibitors, including indinavir. The PRV82T mutant was hypersusceptible to saquinavir. Thus, the impaired fitness of the V82T single mutant is consistent with its low frequency in protease inhibitor-na?ve patients. The similar fitness of WT (NL4-3), L63P, and M46I is consistent with the common occurrence of L63P in the absence of protease inhibitor-selection pressure, but not with the rare detection of M46I in drug-na?ve patients.     

Detection of Human Immunodeficiency Virus Type 1 Nucleocapsid Protein p7 In Vitro and In Vivo

We developed and evaluated an immunoassay for the detection and quantification of human immunodeficiency virus type 1 (HIV-1) nucleocapsid protein p7 using electrochemiluminescence technology. The assay had a dynamic range of 50 to 20,000 pg/ml and a lower detection limit equivalent to approximately 10^6.5 HIV-1 RNA copies/ml in culture supernatant. In vitro kinetic replication studies showed that the amount of p7 correlated strongly with the amount of p24 (R² = 0.869; P < 0.0001) and viral RNA (R² = 0.858; P = 0.0009). On the basis of the p7 and RNA concentrations, we calculated the median p7:RNA ratio to be approximately 1,400 p7 molecules per RNA molecule. HIV-1 p7 could be detected and quantified in culture supernatants of both group M subtype A to E viruses and group O viruses. The presence of p7 in vivo was evaluated in 81 serum samples collected from 62 HIV-1-infected individuals. Five samples were p7 positive, whereas 45 samples were HIV-1 p24 positive. Four of the five p7-positive samples were p24 positive as well. p7 could be detected only when serum HIV-1 RNA levels were greater than 10⁶ copies/ml. Anti-p7 antibodies were found in six samples, and all six were p7 negative. In contrast to the in vitro results, it appeared that HIV-1 p7 could not be used as a marker for viral quantification in vivo, since more than 90% of the serum samples were p7 negative. In combination with the low prevalence of anti-p7 antibodies, this may, in turn, be advantageous: the p7 assay may be a good alternative to the p24 assay as the readout system for determination of neutralizing activity against HIV-1 in serum or other fluids containing anti-p24 antibodies.