HIV-1 can escape from RNA interference by evolving an alternative structure in its RNA genome

HIV-1 replication can be efficiently inhibited by intracellular expression of an siRNA targeting the viral RNA. However, HIV-1 escape variants emerged after prolonged culturing. These RNAi-resistant viruses contain nucleotide substitutions or deletions in or near the targeted sequence. We observed an inverse correlation between the level of resistance and the stability of the siRNA/target-RNA duplex. However, two escape variants showed a higher level of resistance than expected based on the duplex stability. We demonstrate that these mutations induce alternative folding of the RNA such that the target sequence is occluded from binding to the siRNA, resulting in reduced RNAi efficiency. HIV-1 can thus escape from RNAi-mediated inhibition not only through nucleotide substitutions or deletions in the siRNA target sequence, but also through mutations that alter the local RNA secondary structure. The results highlight the enormous genetic flexibility of HIV-1 and provide detailed molecular insight into the sequence specificity of RNAi and the impact of target RNA secondary structure.     

Structure-function analysis of the 3' stem-loop of hepatitis C virus genomic RNA and its role in viral RNA replication

Previous studies indicate that the 3' terminal 46 nt of the RNA genome of hepatitis C virus (HCV) are highly conserved among different viral strains and essential for RNA replication. Here, we describe a mutational analysis of the 3' terminal hairpin (stem-loop I) that is putatively formed by this sequence and demonstrate its role in replication of the viral RNA. We show that single base substitutions within the 6-nt loop at positions adjacent to the stem abrogate replication of a subgenomic RNA, whereas substitutions in the three apical nucleotides were well tolerated without loss of replication competence. Single point mutations were also well tolerated within the middle section of the duplex, but not at the penultimate nucleotide positions near either end of the stem. However, complementary substitutions at the -19 and -28 positions (from the 3' end) restored replication competence, providing strong evidence for the existence of the structure and its involvement in RNA replication. This was confirmed by rescue of replicating RNAs from mutants containing complementary 10-nt block substitutions at the base of the stem. Each of these RNAs contained an additional U at the 3' terminus. Further experiments indicated a strong preference for U at the 3' terminal position (followed in order by C, A, and G), and a G at the -2 position. These features of stem-loop I are likely to facilitate recognition of the 3' end of the viral RNA by the viral RNA replicase.     

Fitness costs limit viral escape from cytotoxic T lymphocytes at a structurally constrained epitope

The intense selection pressure exerted by virus-specific cytotoxic T lymphocytes (CTL) on replicating human immunodeficiency virus and simian immunodeficiency virus results in the accumulation of CTL epitope mutations. It has been assumed that fitness costs can limit the evolution of CTL epitope mutations. However, only a limited number of studies have carefully examined this possibility. To explore the fitness costs associated with viral escape from p11C, C-M-specific CTL, we constructed a panel of viruses encoding point mutations at each position of the entire p11C, C-M epitope. Amino acid substitutions at positions 3, 4, 5, 6, 7, and 9 of the epitope significantly impaired virus replication by altering virus production and Gag protein expression as well as by destabilizing mature cores. Amino acid substitutions at position 2 of the epitope were tolerated but required reversion or additional compensatory mutations to generate replication-competent viruses. Finally, while amino acid substitutions at positions 1 and 8 of the p11C, C-M epitope were functionally tolerated, these substitutions were recognized by p11C, C-M-specific CTL and therefore provided no selection advantage for the virus. Together, these data suggest that limited sequence variation is tolerated by the region of the capsid encoding the p11C, C-M epitope and therefore that only a very limited number of mutations can allow successful viral escape from the p11C, C-M-specific CTL response.     

Poliovirus escape from RNA interference: short interfering RNA-target recognition and implications for therapeutic approaches

Short interfering RNAs (siRNAs) directed against poliovirus and other viruses effectively inhibit viral replication. Although RNA interference (RNAi) may provide the basis for specific antiviral therapies, the limitations of RNAi antiviral strategies are ill defined. Here, we show that poliovirus readily escapes highly effective siRNAs through unique point mutations within the targeted regions. Competitive analysis of the escape mutants provides insights into the basis of siRNA recognition. The RNAi machinery can tolerate mismatches but is exquisitely sensitive to mutations within the central region and the 3' end of the target sequence. Indeed, specific mutations in the target sequence resulting in G:U mismatches are sufficient for the virus to escape siRNA inhibition. However, using a pool of siRNAs to simultaneously target multiple sites in the viral genome prevents the emergence of resistant viruses. Our study uncovers the elegant precision of target recognition by the RNAi machinery and provides the basis for the development of effective RNAi-based therapies that prevent viral escape.     

Role of Naturally Occurring Basic Amino Acid Substitutions in the Human Immunodeficiency Virus Type 1 Subtype E Envelope V3 Loop on Viral Coreceptor Usage and Cell Tropism

To assess the role of naturally occurring basic amino acid substitutions in the V3 loop of human immunodeficiency virus type 1 (HIV-1) subtype E on viral coreceptor usage and cell tropism, we have constructed a panel of chimeric viruses with mutant V3 loops of HIV-1 subtype E in the genetic background of HIV-1LAI. The arginine substitutions naturally occurring at positions 8, 11, and 18 of the V3 loop in an HIV-1 subtype E X4 strain were systematically introduced into that of an R5 strain to generate a series of V3 loop mutant chimera. These chimeric viruses were employed in virus infectivity assays using HOS-CD4 cells expressing either CCR5 or CXCR4, peripheral blood mononuclear cells, T-cell lines, or macrophages. The arginine substitution at position 11 of the V3 loop uniformly caused the loss of infectivity in HOS-CD4-CCR5 cells, indicating that position 11 is critical for utilization of CCR5. CXCR4 usage was conferred by a minimum of two arginine substitutions, regardless of combination, whereas arginine substitutions at position 8 and 11 were required for T-cell line tropism. Nonetheless, macrophage tropism was not conferred by the V3 loop of subtype E R5 strain per se. We found that the specific combinations of amino acid changes in HIV-1 subtype E env V3 loop are critical for determining viral coreceptor usage and cell tropism. However, the ability to infect HOS-CD4 cells through either CXCR4 or CCR5 is not necessarily correlated with T-cell or macrophage tropism, suggesting that cellular tropism is not dictated solely by viral coreceptor utilization.     

RNA interference as a tool for exploring HIV-1 robustness

Short interfering RNAs (siRNAs) that target viral genes can efficiently inhibit human immunodeficiency virus type 1 (HIV-1) replication. Nevertheless, there is the potential for viral escape, particularly with a highly mutable target such as HIV-1. We present a novel strategy for anticipating and preventing viral escape using second-generation siRNAs. The evolutionary capacity of HIV-1 was tested by exerting strong selective pressure on a highly conserved sequence in the HIV-1 genome. We assayed the antiviral efficacy of five overlapping siRNAs directed against an essential region of the HIV-1 protease. Serial viral transfers in U87-CD4-CXCR4 cells were performed using four of the siRNAs. This procedure was repeated until virus breakthrough was detected. After several serial culture passages, resistant virus with a single point mutation in the targeted region was detected in the culture supernatants. The emergence of resistant virus was confirmed by molecular cloning and DNA sequencing of viral RNA. The most common escape route was the D30N mutation. Importantly, the addition of a second-generation siRNA that matched the D30N mutation restored viral inhibition and delayed development of escape variants. Passages performed with both siRNAs prevented the emergence of the D30N escape mutant and forced the virus to develop new escape routes. Thus, second-generation siRNAs can be used to block escape from RNA interference (RNAi) and to search for new RNAi escape routes. The protocol described here may be useful for exploring the sequence space available for HIV-1 evolution and for producing attenuated or deleterious viruses.     

Human immunodeficiency virus type 1 escape is restricted when conserved genome sequences are targeted by RNA interference

RNA interference (RNAi) is a cellular mechanism in which small interfering RNAs (siRNAs) mediate sequence-specific gene silencing by cleaving the targeted mRNA. RNAi can be used as an antiviral approach to silence the human immunodeficiency virus type 1 (HIV-1) through stable expression of short-hairpin RNAs (shRNAs). We previously reported efficient HIV-1 inhibition by an shRNA against the nonessential nef gene but also described viral escape by mutation or deletion of the nef target sequence. The objective of this study was to obtain insight in the viral escape routes when essential and highly conserved sequences are targeted in the Gag, protease, integrase, and Tat-Rev regions of HIV-1. Target sequences were analyzed of more than 500 escape viruses that were selected in T cells expressing individual shRNAs. Viruses acquired single point mutations, occasionally secondary mutations, but—in contrast to what is observed with nef—no deletions were detected. Mutations occurred predominantly at target positions 6, 8, 9, 14, and 15, whereas none were selected at positions 1, 2, 5, 18, and 19. We also analyzed the type of mismatch in the siRNA-target RNA duplex, and G-U base pairs were frequently selected. These results provide insight into the sequence requirements for optimal RNAi inhibition. This knowledge on RNAi escape may guide the design and selection of shRNAs for the development of an effective RNAi therapy for HIV-1 infections.     

Processing of deoxyuridine mismatches and abasic sites by human immunodeficiency virus type-1 integrase.

We have examined the activities of HIV-1 integrase on substrates containing mismatches, composed of deoxyuridine at different positions in either the processed or nonprocessed strand of viral DNA, within and near the conserved CA dinucleotide of the U5 end of the HIV-1 LTR. Substitution in the processed strand of either the C or A of the CA dinucleotide or of the G 5' to the CA reduced strand transfer six-, three- and seven-fold respectively. 3'-processing was also reduced by substitution at the GC but not at the A. Substitution in the nonprocessed strand of the G nucleotide at the processing site abolished strand transfer while substitution of the T had no effect. DNA binding of HIV-1 integrase was not affected by deoxyuridine substitutions. Deoxyuridine substitution outside the trinucleotide remained compatible with enzyme activity. Enzymatically generated abasic sites were created at each mismatch to determine the effect of a missing base on integrase activity. Consistent with the deoxyuridine mismatch observations, 3'-processing and strand transfer were abolished when the abasic site was substituted for either of the nucleotides of the GCA trinucleotide. Integrase was, however, able to tolerate mismatches within this trinucleotide during the disintegration reaction. Taken together, these results suggest that base-mismatched or base-deleted substrates, which can be created by the proofreading-deficient HIV-1 RT, can be tolerated by HIV-1 integrase when located outside of the GCA trinucleotide at the U5 end of the LTR.     

Functional constraints of influenza A virus epitopes limit escape from cytotoxic T lymphocytes

Viruses can exploit a variety of strategies to evade immune surveillance by cytotoxic T lymphocytes (CTL), including the acquisition of mutations in CTL epitopes. Also for influenza A viruses a number of amino acid substitutions in the nucleoprotein (NP) have been associated with escape from CTL. However, other previously identified influenza A virus CTL epitopes are highly conserved, including the immunodominant HLA-A*0201-restricted epitope from the matrix protein, M1(58-66). We hypothesized that functional constraints were responsible for the conserved nature of influenza A virus CTL epitopes, limiting escape from CTL. To assess the impact of amino acid substitutions in conserved epitopes on viral fitness and recognition by specific CTL, we performed a mutational analysis of CTL epitopes. Both alanine replacements and more conservative substitutions were introduced at various positions of different influenza A virus CTL epitopes. Alanine replacements for each of the nine amino acids of the M1(58-66) epitope were tolerated to various extents, except for the anchor residue at the second position. Substitution of anchor residues in other influenza A virus CTL epitopes also affected viral fitness. Viable mutant viruses were used in CTL recognition experiments. The results are discussed in the light of the possibility of influenza viruses to escape from specific CTL. It was speculated that functional constraints limit variation in certain epitopes, especially at anchor residues, explaining the conserved nature of these epitopes.     

SiRNA-Induced Mutation in HIV-1 Polypurine Tract Region and Its Influence on Viral Fitness

Converting single-stranded viral RNA into double stranded DNA for integration is an essential step in HIV-1 replication. Initial polymerization of minus-strand DNA is primed from a host derived tRNA, whereas subsequent plus-strand synthesis requires viral primers derived from the 3′ and central polypurine tracts (3′ and cPPTs). The 5′ and 3′ termini of these conserved RNA sequence elements are precisely cleaved by RT-associated RNase H to generate specific primers that are used to initiate plus-strand DNA synthesis. In this study, siRNA wad used to produce a replicative HIV-1 variant contained G(-1)A and T(-16)A substitutions within/adjacent to the 3′PPT sequence. Introducing either or both mutations into the 3′PPT region or only the G(-1)A substitution in the cPPT region of NL4-3 produced infectious virus with decreased fitness relative to the wild-type virus. In contrast, introducing the T(-16)A or both mutations into the cPPT rendered the virus(es) incapable of replication, most likely due to the F185L integrase mutation produced by this nucleotide substitution. Finally, the effects of G(-1)A and T(-16)A mutations on cleavage of the 3′PPT were examined using an in vitro RNase H cleavage assay. Substrate containing both mutations was mis-cleaved to a greater extent than either wild-type substrate or substrate containing the T(-16)A mutation alone, which is consistent with the observed effects of the equivalent nucleotide substitutions on the replication fitness of NL4-3 virus. In conclusion, siRNA targeting of the HIV-1 3′PPT region can substantially suppress virus replication, and this selective pressure can be used to generate infectious virus containing mutations within or near the HIV-1 PPT. Moreover, in-depth analysis of the resistance mutations demonstrates that although virus containing a G(-1)A mutation within the 3′PPT is capable of replication, this nucleotide substitution shifts the 3′-terminal cleavage site in the 3′PPT by one nucleotide (nt) and significantly reduces viral fitness.     

Functional compensation of a detrimental amino acid substitution in a cytotoxic-T-lymphocyte epitope of influenza a viruses by comutations

Influenza A viruses accumulate amino acid substitutions in cytotoxic-T-lymphocyte (CTL) epitopes, allowing these viruses to escape from CTL immunity. The arginine-to-glycine substitution at position 384 of the viral nucleoprotein is associated with escape from CTLs. Introduction of the R384G substitution in the nucleoprotein gene segment of influenza virus A/Hong Kong/2/68 by site-directed mutagenesis was detrimental to viral fitness. Introduction of one of the comutations associated with R384G, E375G, partially restored viral fitness and nucleoprotein functionality. We hypothesized that influenza A viruses need to overcome functional constraints to accumulate mutations in CTL epitopes and escape from CTLs.     

Human immunodeficiency virus type 1 escapes from RNA interference-mediated inhibition

Short-term assays have suggested that RNA interference (RNAi) may be a powerful new method for intracellular immunization against human immunodeficiency virus type 1 (HIV-1) infection. However, RNAi has not yet been shown to protect cells against HIV-1 in long-term virus replication assays. We stably introduced vectors expressing small interfering RNAs (siRNAs) directed against the HIV-1 genome into human T cells by retroviral transduction. We report here that an siRNA directed against the viral Nef gene (siRNA-Nef) confers resistance to HIV-1 replication. This block in replication is not absolute, and HIV-1 escape variants that were no longer inhibited by siRNA-Nef appeared after several weeks of culture. These RNAi-resistant viruses contained nucleotide substitutions or deletions in the Nef gene that modified or deleted the siRNA-Nef target sequence. These results demonstrate that efficient inhibition of HIV-1 replication through RNAi is possible in stably transduced cells. Therefore, RNAi could become a realistic gene therapy approach with which to overcome the devastating effect of HIV-1 on the immune system. However, as is known for antiviral drug therapy against HIV-1, antiviral approaches involving RNAi should be used in a combined fashion to prevent the emergence of resistant viruses.     

Isolation of TAK-779-resistant HIV-1 from an R5 HIV-1 GP120 V3 loop library

The human immunodeficiency virus (HIV-1) envelope glycoprotein (GP) 120 interacts with CD4 and the CCR5 coreceptor for viral entry. The V3 loop in GP120 is a crucial region for determining coreceptor usage during viral entry, and a variety of amino acid substitutions has been observed in clinical isolates. To construct an HIV-1 V3 loop library, we chose 10 amino acid positions in the V3 loop and incorporated random combinations (27,648 possibilities) of the amino acid substitutions derived from 31 R5 viruses into the V3 loop of HIV-1(JR-FL) proviral DNA. The constructed HIV-1 library contained 6.6 x 10(6) independent clones containing a set of 0-10 amino acid substitutions in the V3 loop. To address whether restricted steric alteration in the V3 loop could confer resistance to an entry inhibitor, TAK-779, we selected entry inhibitor-resistant HIV-1 by increasing the concentration of TAK-779 from 0.10 to 0.30 microM in PM1-CCR5 cells with high expression of CCR5. The selected viruses at passage 8 contained five amino acid substitutions in the V3 loop without any other mutations in GP120 and showed 15-fold resistance compared with the parental virus. These results indicated that a certain structure of the V3 loop containing amino acid substitutions derived from 31 R5 viruses can contribute to the acquisition of resistance to entry inhibitors binding to CCR5. Taken together, this type of HIV-1 V3 loop library is useful for isolating and analyzing the specific biological features of HIV-1 with respect to alterations of the V3 loop structure.     

Neutralizing Antibody Escape during HIV-1 Mother-to-Child Transmission Involves Conformational Masking of Distal Epitopes in Envelope

HIV-1 variants transmitted to infants are often resistant to maternal neutralizing antibodies (NAbs), suggesting that they have escaped maternal NAb pressure. To define the molecular basis of NAb escape that contributes to selection of transmitted variants, we analyzed 5 viruses from 2 mother-to-child transmission pairs, in which the infant virus, but not the maternal virus, was resistant to neutralization by maternal plasma near transmission. We generated chimeric viruses between maternal and infant envelope clones obtained near transmission and examined neutralization by maternal plasma. The molecular determinants of NAb escape were distinct, even when comparing two maternal variants to the transmitted infant virus within one pair, in which insertions in V4 of gp120 and substitutions in HR2 of gp41 conferred neutralization resistance. In another pair, deletions and substitutions in V1 to V3 conferred resistance, but neither V1/V2 nor V3 alone was sufficient. Although the sequence determinants of escape were distinct, all of them involved modifications of potential N-linked glycosylation sites. None of the regions that mediated escape were major linear targets of maternal NAbs because corresponding peptides failed to compete for neutralization. Instead, these regions disrupted multiple distal epitopes targeted by HIV-1-specific monoclonal antibodies, suggesting that escape from maternal NAbs occurred through conformational masking of distal epitopes. This strategy likely allows HIV-1 to utilize relatively limited changes in the envelope to preserve the ability to infect a new host while simultaneously evading multiple NAb specificities present in maternal plasma.     

Mutagenesis of the yellow fever virus NS2B/3 cleavage site: determinants of cleavage site specificity and effects on polyprotein processing and viral replication.

The determinants of cleavage site specificity of the yellow fever virus (YF) NS3 proteinase for its 2B/3 cleavage site have been studied by using site-directed mutagenesis. Mutations at residues within the GARR decreases S sequence were tested for effects on cis cleavage of an NS2B-3(181) polyprotein during cell-free translation. At the P1 position, only the conservative substitution R-->K exhibited significant levels of cleavage. Conservative and nonconservative substitutions were tolerated at the P1' and P2 positions, resulting in intermediate levels of cleavage. Substitutions at the P3 and P4 positions had no effects on cleavage efficiency in the cell-free assay. Processing at other dibasic sites was studied by using transient expression of a sig2A-5(356) polyprotein. Cleavage at the 2B/3 site was not required for processing at downstream sites. However, increased accumulation of high-molecular-weight viral polyproteins was generally observed for mutations which reduced cleavage efficiency at the 2B/3 site. Several mutations were also tested for their effects on viral replication. Virus was not recovered from substitutions which blocked or substantially reduced cleavage in the cell-free assay, suggesting that efficient cleavage at the 2B/3 site is required for flavivirus replication.