Author Correction: RNA synthesis is modulated by G-quadruplex formation in Hepatitis C virus negative RNA strand.

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RNA synthesis is modulated by G-quadruplex formation in Hepatitis C virus negative RNA strand.

DNA and RNA guanine-rich oligonucleotides can form non-canonical structures called G-quadruplexes or "G4" that are based on the stacking of G-quartets. The role of DNA and RNA G4 is documented in eukaryotic cells and in pathogens such as viruses. Yet, G4 have been identified only in a few RNA viruses, including the Flaviviridae family. In this study, we analysed the last 157 nucleotides at the 3'end of the HCV (-) strand. This sequence is known to be the minimal sequence required for an efficient RNA replication. Using bioinformatics and biophysics, we identified a highly conserved G4-prone sequence located in the stem-loop IIy' of the negative strand. We also showed that the formation of this G-quadruplex inhibits the in vitro RNA synthesis by the RdRp. Furthermore, Phen-DC3, a specific G-quadruplex binder, is able to inhibit HCV viral replication in cells in conditions where no cytotoxicity was measured. Considering that this domain of the negative RNA strand is well conserved among HCV genotypes, G4 ligands could be of interest for new antiviral therapies.

De novo RNA synthesis catalyzed by the Zika Virus RNA polymerase domain.

Mosquito- and tick-borne pathogens including Chikungunya, Dengue, Japanese encephalitis, West Nile, Yellow fever and Zika virus, represent a new economic and public health challenge. In the absence of effective vaccines and specific therapies, only supportive regimens are administrated for most of these infections. Thus, the development of a targeted therapy is mandatory to stop the rapid progression of these pathogens and preoccupant associated burdens such as Guillain-Barre syndrome, microcephaly. For this, it is essential to develop biochemical tools to help study and target key viral enzymes involved in replication such as helicase complexes, methyl-transferases and RNA-dependent RNA polymerases. Here, we show that a highly purified ZIKV polymerase domain is active in vitro. Importantly, we show that this isolated domain is capable of de novo synthesis of the viral genome and efficient elongation without terminal nucleotide transferase activity. Altogether, this isolated polymerase domain will be a precious tool to screen and optimize specific nucleoside and non-nucleoside inhibitors to fight against Zika infections.

Hepatitis C virus intragenomic interactions are modulated by the SLVI RNA structure of the core coding sequence.

Several RNA interactions are thought to play a role in the regulation of the hepatitis C virus (HCV) life cycle. Most of these interactions involve the 5BSL3.2 domain and therefore occur at the 3' end of the viral genomic RNA. A long-range interaction has also been described between 5BSL3.2 and the 5' untranslated region (UTR). Another interaction involves the SLVI stem loop of the core coding region and the 5'UTR. We aimed to analyse the role of this SLVI domain, which likely interferes with others interactions. By evaluating RNA stability, translation and RNA synthesis, we showed that the SLVI stem loop extensively modulates the effect of the interactions mediated by the 5BSL3.2 domain and strongly affects the IIId/5BSL3.2 interaction. Numerous interactions in HCV genomic RNA have been described in the UTRs and the coding sequence but their roles are poorly understood. We showed that the SLVI domain located in the core coding sequence plays an important role in the translation of the polyprotein, but also in the modulation of long-range RNA interactions centred on the 5BSL3.2 domain. The SLVI domain has been absent from most studies, especially from the extensively used subgenomic replicon; our data highlight the importance of this domain in the studies of these long-range interactions in the HCV life cycle.

Mutations of the SL2 dimerization sequence of the hepatitis C genome abrogate viral replication.

Stem-loop SL2 is a self-interacting palindromic sequence that has been identified within the hepatitis C virus genome (HCV). While, RNA dimerization of the HCV genome has been observed in vitro with short RNA sequences, the role of a putative RNA dimerization during viral replication has not been elucidated. To determine the effect of genomic dimerization on viral replication, we introduced mutations into SL2 predicted to disrupt genomic dimerization. Using surface plasmon resonance, we show that mutations within the SL2 bulge impact dimerization in vitro. Transfection of Huh7 cells with luciferase-encoding full-length genomes containing SL2 mutations abolishes viral replication. Luciferase expression indicates that viral translation is not or slightly affected and that the viral RNA is properly encapsidated. However, RT-qPCR analysis demonstrates that viral RNA synthesis is drastically decreased. In vitro synthesis experiments using the viral recombinant polymerase show that modifications of intra-molecular interactions have no effect on RNA synthesis, while impairing inter-molecular interactions decreases polymerase activity. This confirms that dimeric templates are preferentially replicated by the viral polymerase. Altogether, these results indicate that the dimerization of the HCV genomic RNA is a crucial step for the viral life cycle especially for RNA replication. RNA dimerization could explain the existence of HCV recombinants in cell culture and patients reported recently in other studies.

Direct evidence for RNA-RNA interactions at the 3' end of the Hepatitis C virus genome using surface plasmon resonance.

Surface plasmon resonance was used to investigate two previously described interactions analyzed by reverse genetics and complementation mutation experiments, involving 5BSL3.2, a stem-loop located in the NS5B coding region of HCV. 5BSL3.2 was immobilized on a sensor chip by streptavidin-biotin coupling, and its interaction either with the SL2 stem-loop of the 3' end or with an upstream sequence centered on nucleotide 9110 (referred to as Seq9110) was monitored in real-time. In contrast with previous results obtained by NMR assays with the same short RNA sequences that we used or SHAPE analysis with longer RNAs, we demonstrate that recognition between 5BSL3.2 and SL2 can occur in solution through a kissing-loop interaction. We show that recognition between Seq9110 and the internal loop of 5BSL3.2 does not prevent binding of SL2 on the apical loop of 5BSL3.2 and does not influence the rate constants of the SL2-5BSL3.2 complex. Therefore, the two binding sites of 5BSL3.2, the apical and internal loops, are structurally independent and both interactions can coexist. We finally show that the stem-loop SL2 is a highly dynamic RNA motif that fluctuates between at least two conformations: One is able to hybridize with 5BSL3.2 through loop-loop interaction, and the other one is capable of self-associating in the absence of protein, reinforcing the hypothesis of SL2 being a dimerization sequence. This result suggests also that the conformational dynamics of SL2 could play a crucial role for controlling the destiny of the genomic RNA.

Activation of GCN2 upon HIV-1 infection and inhibition of translation.

Higher eukaryotic organisms have a variety of specific and nonspecific defense mechanisms against viral invaders. In animal cells, viral replication may be limited through the decrease in translation. Some viruses, however, have evolved mechanisms that counteract the response of the host. We report that infection by HIV-1 triggers acute decrease in translation. The human protein kinase GCN2 (eIF2AK4) is activated by phosphorylation upon HIV-1 infection in the hours following infection. Thus, infection by HIV-1 constitutes a stress that leads to the activation of GCN2 with a resulting decrease in protein synthesis. We have shown that GCN2 interacts with HIV-1 integrase (IN). Transfection of IN in amino acid-starved cells, where GCN2 is activated, increases the protein synthesis level. These results point to an as yet unknown role of GCN2 as an early mediator in the cellular response to HIV-1 infection, and suggest that the virus is able to overcome the involvement of GCN2 in the cellular response by eliciting methods to maintain protein synthesis.

Effect of cytomegalovirus-induced immune response, self antigen-induced immune response, and microbial translocation on chronic immune activation in successfully treated HIV type 1-infected patients: the ANRS CO3 Aquitaine Cohort.

We evaluated the impact of cytomegalovirus (CMV)-induced immune responses, autoimmune-induced immune responses, and microbial translocation on immune activation in 191 human immunodeficiency virus type 1-infected patients from the ANRS CO3 Aquitaine Cohort. All enrolled subjects had achieved long-term virological suppression during receipt of combination antiretroviral therapy (cART). HLA-DR(+)/CD38(+) expression was 16.8% among CD8(+) T cells. Independent of age, CD4(+) T-cell count, 16S ribosomal DNA load, and regulatory T-cell count, positive results of Quantiferon CMV analysis (P = .02), positive results of CMV-pp65 enzyme-linked immunosorbent spot analysis (P = .01), positive results of CMV-pp65-specific CD8(+) T-cell analysis (P = .05), and CMV seropositivity (P = .01) were associated with a higher percentage of CD8+ T cells that expressed HLA-DR+/CD38+. Autoimmune response and microbial translocation were not associated with immune activation. Therefore, the CMV-induced immune response seems to be associated with chronic immune activation in cART recipients with sustained virological suppression.

Two crucial early steps in RNA synthesis by the hepatitis C virus polymerase involve a dual role of residue 405.

The hepatitis C virus (HCV) NS5B protein is an RNA-dependent RNA polymerase essential for replication of the viral RNA genome. In vitro and presumably in vivo, NS5B initiates RNA synthesis by a de novo mechanism and then processively copies the whole RNA template. Dissections of de novo RNA synthesis by genotype 1 NS5B proteins previously established that there are two successive crucial steps in de novo initiation. The first is dinucleotide formation, which requires a closed conformation, and the second is the transition to elongation, which requires an opening of NS5B. We also recently published a combined structural and functional analysis of genotype 2 HCV-NS5B proteins (of strains JFH1 and J6) that established residue 405 as a key element in de novo RNA synthesis (P. Simister et al., J. Virol. 83:11926-11939, 2009; M. Schmitt et al., J. Virol 85:2565-2581, 2011). We hypothesized that this residue stabilizes a particularly closed conformation conducive to dinucleotide formation. Here we report similar in vitro dissections of de novo synthesis for J6 and JFH1 NS5B proteins, as well as for mutants at position 405 of several genotype 1 and 2 strains. Our results show that an isoleucine at position 405 can promote both dinucleotide formation and the transition to elongation. New structural results highlight a molecular switch of position 405 with long-range effects, resolving the implied paradox of how the same residue can successively favor both the closed conformation of the dinucleotide formation step and the opening necessary to the transition step.

The guanine-quadruplex aptamer 93del inhibits HIV-1 replication ex vivo by interfering with viral entry, reverse transcription and integration.

BACKGROUND: We have previously identified the guanine-rich oligonucleotide (ODN) 93del as a potent inhibitor in vitro of HIV-1 integrase. Moreover, low nanomolar concentrations of ODN 93del have been shown to inhibit HIV-1 replication in infected cells. METHODS: To investigate the ex vivo mechanism of ODN 93del inhibition, we analysed its antiviral effects on the early steps of HIV-1 replication such as viral entry, reverse transcription and integration using quantitative PCR. RESULTS: In addition to the effect on viral entry previously described for other guanine-quadruplex ODNs, transfection experiments showed that ODN 93del severely affects the proviral integration step independently of the effect on viral entry. Moreover, incubation of viral particles with ODN 93del revealed a potential microbicide activity of the aptamer. CONCLUSIONS: Our data point to an original multimodal inhibition of HIV-1 replication by ODN 93del, strongly suggesting that targets of guanine-quartet-forming ODNs involve entry as well as other intracellular early steps of HIV-1 replication.

Hijacking hepatitis C viral replication with a non-coding replicative RNA.

The current treatments used against RNA viruses have a limited efficacy and are often hampered by the induction of side-effects. The specific delivery of antiviral proteins in infected cells should increase their efficiency and reduce their impact on healthy cells. Here, we describe the development of a new approach which takes advantage of the viral replication machinery to specifically target the antiviral protein expression to the infected cells. The strategy is based on the delivery of a non-coding (-)RNA carrying the structures required for the binding of the viral replication complex and the complementary sequence of an antiviral gene. The viral replication complex replicates the (-)RNA similarly to the viral genome to give a coding (+)RNA from which the antiviral protein will be expressed. As non-infected cells do not express the replication complex, this specific machinery can be used to target virus-infected cells without affecting healthy cells. We show that this approach can be successfully applied to the hepatitis C virus. In both replicon-harboring cells (genotype 1b) and JFH-1 infected cells (genotype 2a), nrRNAs induced a strong decrease in genomic RNA and viral protein NS5A. These effects were correlated with a strong activation of several interferon-stimulating genes.

Identification of a structural element of the hepatitis C virus minus strand RNA involved in the initiation of RNA synthesis.

The replication of the genomic RNA of the hepatitis C virus (HCV) of positive polarity involves the synthesis of a replication intermediate of negative polarity by the viral RNA-dependent RNA polymerase (NS5B). In vitro and likely in vivo, the NS5B initiates RNA synthesis without primers. This de novo mechanism needs specific interactions between the polymerase and viral RNA elements. Cis-acting elements involved in the initiation of (-) RNA synthesis have been identified in the 3' non-coding region and in the NS5B coding region of the HCV RNA. However, the detailed contribution of sequences and/or structures of (-) RNA involved in the initiation of (+) RNA synthesis has been less studied. In this report, we identified an RNA element localized between nucleotides 177 and 222 from the 3'-end of the (-) RNA that is necessary for efficient initiation of RNA synthesis by the recombinant NS5B. By site-directed mutagenesis experiments, we demonstrate that the structure rather than the primary sequence of this domain is important for RNA synthesis. We also demonstrate that the intact structure of this RNA element is also needed for efficient RNA synthesis when the viral NS5B functions in association with other viral and cellular proteins in cultured hepatic cells.

A functional selection of viral genetic elements in cultured cells to identify hepatitis C virus RNA translation inhibitors.

We developed a functional selection system based on randomized genetic elements (GE) to identify potential regulators of hepatitis C virus (HCV) RNA translation, a process initiated by an internal ribosomal entry site (IRES). A retroviral HCV GE library was introduced into HepG2 cells, stably expressing the Herpes simplex virus thymidine kinase (HSV-TK) under the control of the HCV IRES. Cells that expressed transduced GEs inhibiting HSV-TK were selected via their resistance to ganciclovir. Six major GEs were rescued by PCR on the selected cell DNA and identified as HCV elements. We validated our strategy by further studying the activity of one of them, GE4, encoding the 5' end of the viral NS5A gene. GE4 inhibited HCV IRES-, but not cap-dependent, reporter translation in human hepatic cell lines and inhibited HCV infection at a post-entry step, decreasing by 85% the number of viral RNA copies. This method can be applied to the identification of gene expression regulators.

Inhibition of hepatitis C virus (HCV) RNA polymerase by DNA aptamers: mechanism of inhibition of in vitro RNA synthesis and effect on HCV-infected cells.

We describe here the further characterization of two DNA aptamers that specifically bind to hepatitis C virus (HCV) RNA polymerase (NS5B) and inhibit its polymerase activity in vitro. Although they were obtained from the same selection procedure and contain an 11-nucleotide consensus sequence, our results indicate that aptamers 27v and 127v use different mechanisms to inhibit HCV polymerase. While aptamer 27v was able to compete with the RNA template for binding to the enzyme and blocked both the initiation and the elongation of RNA synthesis, aptamer 127v competed poorly and exclusively inhibited initiation and postinitiation events. These results illustrate the power of the selective evolution of ligands by exponential enrichment in vitro selection procedure approach to select specific short DNA aptamers able to inhibit HCV NS5B by different mechanisms. We also determined that, in addition to an in vitro inhibitory effect on RNA synthesis, aptamer 27v was able to interfere with the multiplication of HCV JFH1 in Huh7 cells. The efficient cellular entry of these short DNAs and the inhibitory effect observed on human cells infected with HCV indicate that aptamers are useful tools for the study of HCV RNA synthesis, and their use should become a very attractive and alternative approach to therapy for HCV infection.

Seven nucleotide changes characteristic of the hepatitis C virus genotype 3 5' untranslated region: correlation with reduced in vitro replication.

Computer analysis of 158 hepatitis C virus (HCV) 5' untranslated region (5' UTR) sequences from the six genotypes showed that the 5' UTR from genotype 3 displays seven specific non-contiguous nucleotide changes, at positions 8, 13, 14, 70, 97, 203 and 224. The purpose of this study was to investigate the impact of these changes on translation and replication activities. Indeed, these modifications could alter both the internal ribosome entry site (IRES) present in the 5' UTR of the plus-strand RNA and the 3' end of the minus strand involved in the initiation of plus-strand RNA synthesis. We found that the genotype 3-specific nucleotide changes do not modify the in vitro or ex vivo translation activity of the corresponding IRES, in comparison with that of genotype 1. In contrast, in vitro replication from the minus-strand RNA is eight times less efficient for genotype 3 than for genotype 1 RNA, suggesting the involvement of some nucleotide changes in the reduction of RNA synthesis. Nucleotides 13, 14 and 224 were found to be responsible for this effect. Moreover, a reduced replicative activity was confirmed ex vivo for genotype 3, but to a lesser extent than that observed in vitro, using an RNA minigenome.

Cellular uptake of ODNs in HIV-1 human-infected cells: a role for viral particles in DNA delivery?

We have previously described how a 16 nucleotides ODN (termed 93del) is capable of inhibiting the activity of recombinant integrase in a cell-free system as well as HIV-1 replication in human-infected cells with IC(50) in the low nanomolar range. Intracellular HIV-1 replication was inhibited when the ODN was added at the onset of infection. These results raise several questions. Is a naked ODN able to enter the cell? Does the virus play a role in ODN entry? The uptake of several ODNs (93del, 60del(sc), TBA, T30923) was evaluated and then tracked by labeling the ODN with a fluorescent dye and assessing its intracellular localization by confocal microscopy. A significant level of cellular uptake of free ODN was observed in several cell lines: HeLa epithelial cells, Huh7 hepatic cells, and H9 lymphocytes, and was detected for all ODNs tested except for TBA. Striking differences were observed when naked ODNs were added to cell in the presence or absence of the virus. When HIV-1 virions were present a sharp increase in cellular fluorescence was observed. These results strongly suggest a role for HIV-1 virions in the uptake of certain ODNs.

Endogenous expression of an anti-TAR aptamer reduces HIV-1 replication.

An anti-TAR RNA aptamer called R06, which binds tightly and specifically to the trans-activation responsive (TAR) element of the human immunodeficiency virus type 1 (HIV-1) through loop-loop interactions has been previously selected.(1) We used HIV-based retroviral vectors to express the R06 aptamer. Its synthesis was driven by the U16 snoRNA. We investigated the ability of this cassette to interfere with TAR-mediated transcription using HeLa P4 cells stably expressing the beta-galactosidase gene under the control of the HIV-1 5'LTR. We demonstrated that, upon HIV-1 infection, the beta-galactosidase activity was reduced in cells expressing the nucleolar U16-R06 transcript. The replication of HIV-1 in these cells was also reduced as shown by quantification of the HIV-1 protease gene 24 h post-infection. This effect was specific and related to the formation of R06 TAR complex as an aptamer with a mutated loop, which was no longer able to bind to TAR, did not show any effect. The nucleolus is likely a compartment of interest for targeting the TAR-protein complex responsible for the trans-activation of transcription of the HIV-1 genome.

Template requirements and binding of hepatitis C virus NS5B polymerase during in vitro RNA synthesis from the 3'-end of virus minus-strand RNA.

In our attempt to obtain further information on the replication mechanism of the hepatitis C virus (HCV), we have studied the role of sequences at the 3'-end of HCV minus-strand RNA in the initiation of synthesis of the viral genome by viral RNA-dependent RNA polymerase (RdRp). In this report, we investigated the template and binding properties of mutated and deleted RNA fragments of the 3'-end of the minus-strand HCV RNA in the presence of viral polymerase. These mutants were designed following the newly established secondary structure of this viral RNA fragment. We showed that deletion of the 3'-SL-A1 stem loop significantly reduced the level of RNA synthesis whereas modifications performed in the SL-B1 stem loop increased RNA synthesis. Study of the region encompassing the 341 nucleotides of the 3'-end of the minus-strand RNA shows that these two hairpins play a very limited role in binding to the viral polymerase. On the contrary, deletions of sequences in the 5'-end of this fragment greatly impaired both RNA synthesis and RNA binding. Our results strongly suggest that several domains of the 341 nucleotide region of the minus-strand 3'-end interact with HCV RdRp during in vitro RNA synthesis, in particular the region located between nucleotides 219 and 239.

An oligonucleotide complementary to the SL-B1 domain in the 3'-end of the minus-strand RNA of the hepatitis C virus inhibits in vitro initiation of RNA synthesis by the viral polymerase.

We describe oligonucleotides (ODNs) that inhibit hepatitis C virus (HCV) RNA synthesis in vitro. From a series of 13 ODNs complementary to the 3'-end of the minus-strand HCV RNA, only 4 inhibited RNA synthesis with IC(50) values lower than 1 microM. The inhibition was sequence-specific, since no effect was observed when the ODNs were used with a noncomplementary template. The introduction of a 2'-O-methyl modification increased the inhibitor activity 11-fold (IC(50) = 50 nM) in just 1 (ODN7) of the 4 inhibitory ODNs. ODNs did not inhibit RNA synthesis by interfering with the elongation process as no short RNAs products were detected. We also show that ODN7 did not prevent binding of NS5B to the template or cause polymerase trapping by the duplex RNA/ODN. Our data demonstrate that ODN7 inhibits the initiation process, most probably by modifying structural features present at the 3'-end of the minus-strand RNA.

Hepatitis C virus genetic variability in 52 human immunodeficiency virus-coinfected patients.

The aim of this study was to examine whether hepatitis C virus (HCV) pretreatment quasispecies complexity was linked to virological response or other clinical and biological parameters, in human immunodeficiency virus (HIV)-coinfected patients undergoing anti-HCV treatment. In addition, HCV quasispecies composition is described longitudinally in these patients before, during, and after treatment. The 52 HIV-coinfected patients were included in a randomized therapeutic trial. At inclusion, they had CD4(+) counts of >250/micro l, HIV plasma load of <10,000 copies/ml, and chronic HCV infection with genotype 1 (n = 27), 2 (n = 2) or 3 (n = 23). These values were compared at baseline with 32 HCV-only-infected, interferon-naive patients who were infected with genotype 1, 2, or 3 (n = 16, 1, or 15, respectively). HCV complexity was studied by single-strand conformation polymorphism (SSCP) in E2 hypervariable region 1 (HVR1), and diversity was evaluated at inclusion in 20 coinfected patients by sequencing four major SSCP bands. The baseline number of SSCP bands was identical in HIV-infected and control patients. In HIV-infected patients, HCV complexity was not predictive of sustained virological response to anti-HCV treatment and was unrelated to epidemiological factors, immunological parameters linked to HIV infection (CD4(+) counts, T CD4(+) proliferative responses to HIV-1 p24), protease inhibitor treatment, HCV plasma load, or genotype. HCV diversity was lower in genotype 2- and 3-infected patients. Six months after completion of the anti-HCV treatment, in comparison with baseline, SSCP profiles were modified in 13 of the 21 nonresponding coinfected patients with analyzable samples. In conclusion, in HIV-infected patients, HCV variability had no significant influence on virological response to anti-HCV treatment.