Packageable antiviral therapeutics against human immunodeficiency virus type 1: virion-targeted virus inactivation by incorporation of a single-chain antibody against viral integrase into progeny virions

Targeting the Virus Capsid as a Tool to Fight RNA Viruses

Several strategies have been developed to fight viral infections, not only in humans but also in animals and plants. Some of them are based on the development of efficient vaccines, to target the virus by developed antibodies, others focus on finding antiviral compounds with activities that inhibit selected virus replication steps. Currently, there is an increasing number of antiviral drugs on the market; however, some have unpleasant side effects, are toxic to cells, or the viruses quickly develop resistance to them. As the current situation shows, the combination of multiple antiviral strategies or the combination of the use of various compounds within one strategy is very important. The most desirable are combinations of drugs that inhibit different steps in the virus life cycle. This is an important issue especially for RNA viruses, which replicate their genomes using error-prone RNA polymerases and rapidly develop mutants resistant to applied antiviral compounds. Here, we focus on compounds targeting viral structural capsid proteins, thereby inhibiting virus assembly or disassembly, virus binding to cellular receptors, or acting by inhibiting other virus replication mechanisms. This review is an update of existing papers on a similar topic, by focusing on the most recent advances in the rapidly evolving research of compounds targeting capsid proteins of RNA viruses.

Capsid-Targeted Viral Inactivation: A Novel Tactic for Inhibiting Replication in Viral Infections

Capsid-targeted viral inactivation (CTVI), a conceptually powerful new antiviral strategy, is attracting increasing attention from researchers. Specifically, this strategy is based on fusion between the capsid protein of a virus and a crucial effector molecule, such as a nuclease (e.g., staphylococcal nuclease, Barrase, RNase HI), lipase, protease, or single-chain antibody (scAb). In general, capsid proteins have a major role in viral integration and assembly, and the effector molecule used in CTVI functions to degrade viral DNA/RNA or interfere with proper folding of viral key proteins, thereby affecting the infectivity of progeny viruses. Interestingly, such a capsid-enzyme fusion protein is incorporated into virions during packaging. CTVI is more efficient compared to other antiviral methods, and this approach is promising for antiviral prophylaxis and therapy. This review summarizes the mechanism and utility of CTVI and provides some successful applications of this strategy, with the ultimate goal of widely implementing CTVI in antiviral research.

Driving DNA transposition by lentiviral protein transduction

Gene vectors derived from DNA transposable elements have become powerful molecular tools in biomedical research and are slowly moving into the clinic as carriers of therapeutic genes. Conventional uses of DNA transposon-based gene vehicles rely on the intracellular production of the transposase protein from transfected nucleic acids. The transposase mediates mobilization of the DNA transposon, which is typically provided in the context of plasmid DNA. In recent work, we established lentiviral protein transduction from Gag precursors as a new strategy for direct delivery of the transposase protein. Inspired by the natural properties of infecting viruses to carry their own enzymes, we loaded lentivirus-derived particles not only with vector genomes carrying the DNA transposon vector but also with hundreds of transposase subunits. Such particles were found to drive efficient transposition of the piggyBac transposable element in a range of different cell types, including primary cells, and offer a new transposase delivery approach that guarantees short-term activity and limits potential cytotoxicity. DNA transposon vectors, originally developed and launched as a non-viral alternative to viral integrating vectors, have truly become viral. Here, we briefly review our findings and speculate on the perspectives and potential advantages of transposase delivery by lentiviral protein transduction.

Targeted genome editing by lentiviral protein transduction of zinc-finger and TAL-effector nucleases

Future therapeutic use of engineered site-directed nucleases, like zinc-finger nucleases (ZFNs) and transcription activator-like effector nucleases (TALENs), relies on safe and effective means of delivering nucleases to cells. In this study, we adapt lentiviral vectors as carriers of designer nuclease proteins, providing efficient targeted gene disruption in vector-treated cell lines and primary cells. By co-packaging pairs of ZFN proteins with donor RNA in ‘all-in-one’ lentiviral particles, we co-deliver ZFN proteins and the donor template for homology-directed repair leading to targeted DNA insertion and gene correction. Comparative studies of ZFN activity in a predetermined target locus and a known nearby off-target locus demonstrate reduced off-target activity after ZFN protein transduction relative to conventional delivery approaches. Additionally, TALEN proteins are added to the repertoire of custom-designed nucleases that can be delivered by protein transduction. Altogether, our findings generate a new platform for genome engineering based on efficient and potentially safer delivery of programmable nucleases.

DOI:http://dx.doi.org/10.7554/eLife.01911.001

Altering the genetic code of a living organism to produce certain desirable outcomes is the goal of genetic engineering. The field builds on a long history of human attempts to alter genetics, from selective breeding of crops and livestock to genetically modified organisms and gene therapies. Researchers routinely use gene editing to create ‘knock-out’ mice in which a particular gene is turned off: the researchers can learn more about the function of this gene by watching what happens when it is absent.

As gene editing techniques have grown more sophisticated, they have become an increasingly promising tool for treating diseases that are caused by gene mutations. The aim of this work is to replace faulty genes with genes that work properly. However, it has been difficult to adapt genetic engineering techniques so that they can be used safely in humans.

Scientists have created customized enzymes called nucleases that can remove specific genes, but it has been a challenge to get these nucleases into cells in the first place. A virus can be used to deliver the genes that encode these nucleases into the DNA of a cell, but this approach can lead to the production of too many nucleases and to the removal of more genes than intended.

Now Cai et al. have developed a ‘hit-and-run’ method for getting the nucleases into cells and making them active only for a short period of time. This method involves using a virus to deliver two different nucleases to a cell. Once inside the cell, the viruses released the nucleases, which were able to remove up to one-quarter of their gene targets, with relatively few errors, in the time that they were active.

Next, Cai et al. added gene patches—new genes to replace those removed by the nucleases—to the viruses. This ‘cut and patch’ strategy was successful in up to 8% of the treated cells. The results also suggest that this approach is safer than other gene-editing techniques.

DOI:http://dx.doi.org/10.7554/eLife.01911.002

Defining the interactions and role of DCAF1/VPRBP in the DDB1-cullin4A E3 ubiquitin ligase complex engaged by HIV-1 Vpr to induce a G2 cell cycle arrest

HIV viral protein R (Vpr) induces a cell cycle arrest at the G2/M phase by activating the ATR DNA damage/replication stress signalling pathway through engagement of the DDB1-CUL4A-DCAF1 E3 ubiquitin ligase via a direct binding to the substrate specificity receptor DCAF1. Since no high resolution structures of the DDB1-DCAF1-Vpr substrate recognition module currently exist, we used a mutagenesis approach to better define motifs in DCAF1 that are crucial for Vpr and DDB1 binding. Herein, we show that the minimal domain of DCAF1 that retained the ability to bind Vpr and DDB1 was mapped to residues 1041 to 1393 (DCAF1 WD). Mutagenic analyses identified an α-helical H-box motif and F/YxxF/Y motifs located in the N-terminal domain of DCAF1 WD that are involved in exclusive binding to DDB1. While we could not identify elements specifically involved in Vpr binding, overall, the mutagenesis data suggest that the predicted β-propeller conformation of DCAF1 is likely to be critical for Vpr association. Importantly, we provide evidence that binding of Vpr to DCAF1 appears to modulate the formation of a DDB1/DCAF1 complex. Lastly, we show that expression of DCAF1 WD in the absence of endogenous DCAF1 was not sufficient to enable Vpr-mediated G2 arrest activity. Overall, our results reveal that Vpr and DDB1 binding on DCAF1 can be genetically separated and further suggest that DCAF1 contains determinants in addition to the Vpr and DDB1 minimal binding domain, which are required for Vpr to enable the induction of a G2 arrest.

Inhibition of replication of classical swine fever virus in a stable cell line by the viral capsid and Staphylococcus aureus nuclease fusion protein

Classical swine fever (CSF) is one of the major diseases causing serious economic losses to the swine industry. To explore the feasibility of using capsid-targeted viral inactivation (CTVI) as an antiviral strategy against CSF infection, a plasmid pcDNA-Cap-SNase was constructed for expressing a fusion protein of CSFV capsid (Cap) and Staphylococcus aureus nuclease (SNase). Under G418 selection, a mammalian cell line PK-15 expressing stably the fusion protein Cap-SNase(PK-15/Cap-SNase) could be detected by rabbit antiserum against CSFV capsid protein and had good nuclease activity in cleaving linearized plasmid DNA. The CSFV titer produced from infection of this PK-15/Cap-SNase stable cell line was reduced by an order of 10(2)-10(3.5) or 70.8% compared to that produced in control PK-15 cells. Detection of the virus by ELISA indicated that CSFV propagation was inhibited in the PK-15/Cap-SNase cell line. It was demonstrated clearly that the fusion protein Cap-SNase could inhibit effectively the production of CSFV, resulting in a reduction in infectious titers. Therefore, CTVI may be valuable therapeutic approach against CSFV.

Gene therapy approaches to HIV infection

The HIV pandemic represents a new challenge to biomedical research. What began as a handful of recognized cases among homosexual men in the US has become a global pandemic of such proportions that it clearly ranks as one of the most destructive viral scourges in history. In the past few years new treatments and drugs have been developed and tested, but the development of a new generation of therapies remains a major priority, because of the lack of chemotherapeutic drugs or vaccines that show long-term efficacy in vivo. Recently, gene therapeutic strategies for the treatment of patients with HIV infection have received increased attention because they are able to offer the possibility of simultaneously targeting multiple sites in the HIV genome, thereby minimizing the production of resistant virus. Recombinant genes for gene therapy can be classified as expressing interfering proteins (intracellular antibodies, dominant negative proteins) or interfering RNAs (antisense RNAs, ribozymes, RNA decoys). The latter group offers the advantage of avoiding the stimulation of host immune response which might progressively decrease the efficacy of proteins. The stumbling block to achieving lasting antiviral effects is still represented by the lack of efficient gene transfer techniques capable of generating persistent transgene expression and a high number of transduced cells relative to untransduced cells. Novel delivery vectors, such as lentiviruses, might overcome some of these shortcomings. The use of recombinant genes to generate immunity is a very promising concept that is rapidly expanding. Since the immune system can significantly amplify the response to tiny amounts of antigen, DNA vaccines can indeed be delivered by exploiting traditional gene therapy approaches without the need of high transduction efficiency.

Genetic selection of peptide inhibitors of human immunodeficiency virus type 1 Vpr

Human immunodeficiency virus 1 (HIV-1) encodes a gene product, Vpr, that facilitates the nuclear uptake of the viral pre-integration complex in non-dividing cells and causes infected cells to arrest in the G(2) phase of the cell cycle. Vpr was also shown to cause mitochondrial dysfunction in human cells and budding yeasts, an effect that was proposed to lead to growth arrest and cell killing in budding yeasts and apoptosis in human cells. In this study, we used a genetic selection in Saccharomyces cerevisiae to identify hexameric peptides that suppress the growth arrest phenotype mediated by Vpr. Fifteen selected glutathione S-transferase (GST)-fused peptides were found to overcome to different extents Vpr-mediated growth arrest. Amino acid analysis of the inhibitory peptide sequences revealed the conservation of a di-tryptophan (diW) motif. DiW-containing GST-peptides interacted with Vpr in GST pull-down assays, and their level of interaction correlated with their ability to overcome Vpr-mediated growth arrest. Importantly, Vpr-binding GST-peptides were also found to alleviate Vpr-mediated apoptosis and G(2) arrest in HIV-1-producing CD4(+) T cell lines. Furthermore, they co-localized with Vpr and interfered with its nuclear translocation. Overall, this study defines a class of diW-containing peptides that inhibit HIV-1 Vpr biological activities most likely by interacting with Vpr and interfering with critical protein interactions.

Virion-targeted viral inactivation: new therapy against viral infection

BACKGROUND

Acquired immune deficiency syndrome (AIDS) is resistant to all current therapy. Gene therapy is an attractive alternative or additive to current, unsatisfactory AIDS therapy.

MATERIALS AND METHODS

To develop an antiviral molecule targeting viral integrase (HIV IN), we generated a single-chain antibody, termed scAb, which interacted with human immunodeficiency virus type 1 (HIV-1) IN and inhibited virus replication at the integration step when expressed intracellularly. To reduce infectivity from within the virus particles, we made expression plasmids (pC-scAbE-Vpr, pC-scAbE-CA, and pC-scAbE-WXXF), which expressed the anti-HIV IN scAb fused to the N-terminus of HIV-1-associated accessory protein R (Vpr), capsid protein (CA), and specific binding motif to Vpr (WXXF), respectively. All fusion proteins were tagged with a nine-amino acid peptide derived from influenza virus hemagglutinin (HA) at the C terminus.

RESULTS

The fusion molecules, termed scAbE-Vpr, scAbE-CA, and scAbE-WXXF, interacted specifically with HIV IN immobilized on a nitrocellulose membrane. Immunoblot analysis showed that scAbE-Vpr, scAbE-CA, and scAbE-WXXF were incorporated into the virions produced by cotransfection of 293T cells with HIV-1 infectious clone DNA (pLAI) and pC-scAbE-Vpr, pC-scAbE-WXXF. A multinuclear activation galactosidase indicator (MAGI) assay revealed that the virions released from 293T cells cotransfected with pLAI and pC-scAbE-Vpr, pC-scAbE-WXXF had as little 1000-fold of the infectivity of the control wild-type virions, which were produced from the 293T cells transfected with pLAI alone. Furthermore, the virions produced from the 293T cells cotransfected with pLAI and an scAb expression vector (pC-scAb) showed only 1% of the infectivity of the control HIV-1 in a MAGI assay, although scAb was not incorporated into the virions. In either instance, the total quantity of the progeny virions released from the transfected 293T cells and the patterns of the virion proteins were hardly affected by the presence of scAb, scAbE-Vpr, or scAbE-WXXF, as determined by virion-associated reverse transcriptase assay and by immunoblot analysis, respectively. Because G418-selected HeLa clones carrying the expression plasmid for scAbE-WXXF were obtained much more frequently than those for scAbE-Vpr, scAbE-WXXF was inferred to be less toxic to cells than scAbE-Vpr. The result that scAbE-WXXF with viral incorporation achieved more than a 10-fold reduction in infectivity of the progeny virions than scAb without incorporation suggests that scAbE-WXXF is a potential antiviral molecule, inhibiting replication by neutralization of HIV IN activity both within cells and within virions. Moreover, it is nontoxic to human cells. We termed this gene therapy "virion-"targeted-viral inactivation" and these molecules "packageable antiviral therapeutics."

CONCLUSION

This new gene therapy has the potential for wide application in many viral infectious diseases.

Significant interference with hepatitis B virus replication by a core-nuclease fusion protein

Hepatitis B virus (HBV), a small DNA containing virus that replicates via reverse transcription, causes acute and chronic B-type hepatitis in humans. The limited success of current therapies for chronic infection has prompted exploration of alternative strategies. Capsid-targeted viral inactivation is a conceptually powerful approach that exploits virion structural proteins to target a degradative enzyme specifically into viral particles. Its principal feasibility has been demonstrated in retroviral model systems but not yet for a medically relevant virus outside the retrovirus family. Recently, we found that C proximal fusion to the HBV capsid protein of the Ca(2+)-dependent nuclease (SN) from Staphylococcus aureus yields a chimeric protein, coreSN, that in Escherichia coli coassembles with the wild-type capsid protein into particles with internal SN domains. Here we show that, in HBV co-transfected human hepatoma cells, less than 1 coreSN protein per 10 wild-type core protein subunits reduced titers of enveloped DNA containing virions by more than 95%. The antiviral effect depends on both an enzymatically active SN and on the core domain. CoreSN does not block assembly of RNA containing nucleocapsids but interferes with proper synthesis of viral DNA inside the capsid, or leads to rapid DNA degradation. Our data suggest an intracellular nuclease activation that, owing to the characteristics of HBV morphogenesis, is nonetheless highly virus specific. HBV may therefore be particularly vulnerable to the capsid-targeted viral inactivation approach.