Antiviral RNAi therapy: emerging approaches for hitting a moving target.

The field of directed RNA interference (RNAi) has rapidly developed into a highly promising approach for specifically down regulating genes to alleviate disease pathology. This technology is especially well-suited to treating viral infections, and numerous examples now illustrate that a wide range of viruses can be inhibited with RNAi, both in vitro and in vivo. One principle that has arisen from this work is that antiviral RNAi therapies must be tailored to the unique life cycle of each pathogen, including the choice of delivery vehicle, route of administration, gene(s) targeted and regulation and duration of RNAi induction. Although effective strategies will be customized to each virus, all such therapies must overcome similar challenges. Importantly, treatment strategies must compensate for the inevitable fact that viral genome sequences evolve extremely rapidly, and computational and bioinformatics approaches may aid in the development of therapies that resist viral escape. Furthermore, all RNAi strategies involve the delivery of nucleic acids to target cells, and all will therefore benefit from the development of enhanced gene design and delivery technologies. Here, we review the substantial progress that has been made towards identifying effective antiviral RNAi targets and discuss strategies for translating these findings into effective clinical therapies. Gene Therapy (2006) 13, 532-540. doi:10.1038/sj.gt.3302645; published online 22 September 2005.

Introduction

RNA interference (RNAi) is a mechanism for silencing gene expression that has been conserved through evolution in eukaryotes ranging from plants to humans.[1] In this process, the cellular complex Dicer cleaves a double-stranded RNA (dsRNA) molecule to yield double-stranded duplexes 21–25 nucleotides in length. These short interfering RNAs (siRNA) then guide the RNAi-induced silencing complex (RISC) to cleave target mRNAs that share sequence identity with the siRNA.[1, 2, 3, 4] Since it was first demonstrated that adding exogenous, synthetic siRNA molecules to mammalian cells can induce RNAi,[5] there have been rapidly expanding efforts to develop RNAi therapies that induce the degradation of target messenger RNA (mRNA) involved in genetically inherited (i.e. dominant) or acquired disorders. This review will focus on the features and challenges unique to applying RNAi towards one important class of acquired diseases: viral infections.

RNAi is well suited as an antiviral therapy for numerous reasons. Antiviral therapeutics hinge upon the ability to discriminate virus from host; however, viruses rely extensively upon the host cells for many functions and activities involved in viral replication and therefore typically offer a very limited number of therapeutic targets. For example, the majority of anti-HIV small molecule drugs used in highly active antiretroviral therapies (HAART), focus on one of two viral enzymes, reverse transcriptase and protease.[6] By contrast, because RNAi targets a short stretch of viral nucleic acids rather than a functional domain of a viral protein, even a small viral genome offers a large number of potential targets. Furthermore, in principle the development of RNAi therapeutics can begin once a viral genome sequence is known, whereas the development of small molecule therapies that inhibit complex protein activities requires the prior elucidation of much more biological and functional detail. Finally, although there is limited evidence that RNAi can play a natural antiviral role in mammalian cells,[7, 8, 9, 10] it is clear that it serves as an important defense against viruses in plants and transposable elements in Caenorhabditis elegans.[1, 11] Therefore, human viruses may prove a particularly fruitful therapeutic target for this evolutionarily conserved mechanism.

Along with these potentially advantageous features, viruses pose a number of unique challenges for RNAi-based therapies. Viruses replicate extremely rapidly and accumulate mutations and short deletions, particularly viruses with life cycles that involve RNA genomes. As discussed in further detail below, since RNAi relies upon nearly perfect sequence identity between an siRNA guide and the mRNA target, the accumulation of mutations can render a virus resistant to RNAi suppression, analogous to the evolution of viral resistance to HAART.[6] Furthermore, during viral replication, dsRNA encoding viral proteins or the full genome is often generated, potentially exposing the virus to host cell RNAi. As a result, it is not surprising that numerous viruses have evolved efficient suppressors of RNAi. Although this phenomenon is better characterized in plant infections than in animal viruses,[1] the apparent presence of RNAi suppressors in human viruses indicates that they could impact antiviral RNAi strategies.[7, 8, 10, 12] For instance, the vaccinia E3L and influenza NS1 proteins suppress RNAi when expressed in heterologous systems,[12] although it is not yet clear whether this activity was ‘intentionally’ evolved by the virus or is a side effect of the ability of these proteins to bind dsRNA. Furthermore, it was recently reported that the human immunodeficiency virus type 1 (HIV-1) transcriptional activator protein (Tat) also suppresses RNAi by directly inhibiting Dicer.[10] Targeting an early stage in the viral life cycle before a suppressor accumulates, or directly targeting the suppressor mRNA, may be necessary to circumvent these mechanisms of viral resistance.

The delivery challenge

In general, the RNAi-inducing cargo and its delivery system should be designed to match the life cycle and pathology of the target virus. The first option is to deliver synthetic siRNA molecules, either naked or complexed with a synthetic vector.[5, 13, 14] Alternatively, one can deliver plasmid or viral vector constructs that induce cells to transcribe two complementary RNA molecules that will hybridize to generate an siRNA, or a short hairpin RNA (shRNA) that folds to yield a Dicer substrate.[13, 15, 16] Synthetic siRNAs can provide rapid but transient suppression, which is appropriate for acute viral infections such as influenza or SARS,[14, 17, 18, 19, 20] whereas delivery of expression constructs can provide more sustained RNAi that is suitable for chronic infectious such as hepatitis or HIV-1.[10, 16, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33] Likewise, delivery should be focused to tissues where the target pathogen resides and replicates, somewhat analogous to targeting vaccine delivery to focus immunity in tissues that lie in the pathogen's infectious route of entry into an organism.[34] For example, influenza and respiratory syncytial virus (RSV)[35] therapies are most appropriately delivered by inhalation,[18] whereas hepatitis therapy can be administered intravenously for liver targeting.[13, 22] Similarly, T cells and macrophages can be protected against HIV by harvesting and transducing hematopoietic stem cells with a virus ex vivo to introduce anti-HIV RNAi constructs.[28]

In addition, the RNAi-inducing nucleic acids must be delivered within a therapeutic window of dosage, as dose-dependence has been observed both in vitro and in vivo. Lentiviral vector delivery of an shRNA-expressing construct progressively knocked down target gene expression in single cells with increasing viral dosage.[36] Likewise, in a study of intranasal delivery of polyplex delivery vehicles composed of synthetic anti-influenza siRNAs and the polycationic polymer polyethylenimine, higher siRNA doses protected mice challenged with influenza more effectively.[14] Efficient nucleic acid delivery has been a major challenge in the parallel field of gene therapy, so all delivery vehicles and routes of administration for RNAi-inducing cargo will benefit from prior and continual progress in synthetic and viral vector development.[37]

In addition to a lower delivery limit for efficacy, several phenomena restrict the maximal dosage of RNAi that a host can tolerate. Long dsRNAs, the natural substrates that Dicer processes to generate siRNAs, are known to activate protein kinase R and thereby induce interferon expression, whereas siRNAs themselves are not typically associated with an innate immune response. However, high dosages of synthetic siRNA delivery can stimulate cytotoxic interferon and inflammatory cytokine secretion in a sequence-dependent fashion.[38] In addition, while siRNAs target degradation of mRNAs with a high degree of sequence specificity, they can in some cases also eliminate mRNA containing similar sequences, leading to broader, unintended modulation of host gene expression.[39, 40] These nonspecific or off-target effects lead to the possibility of clinical side effects. Furthermore, shRNAs interact with another endogenous cellular pathway for suppression of gene expression, the microRNA (miRNA) system. miRNAs are initially transcribed as partially double-stranded precursors and are subsequently processed by the RNase III enzyme Drosha to yield RNA hairpins. These hairpins are then exported from the nucleus by Exportin 5 and subsequently suppress the cytoplasmic translation of target mRNAs. Exogenous shRNAs expressed in the nucleus after therapeutic gene delivery also undergo Exportin 5-dependent nuclear export, which can saturate this transport mechanism.[41] A recent report demonstrated that high-efficiency delivery of certain antihepatitis shRNA expression constructs to the murine liver using vectors based on adeno-associated virus serotype 8 could induce significant liver toxicity, likely through competitive inhibition of endogenous miRNA mechanisms.[42] Finally, the RNAi pathway consumes significant amounts of ATP, so constitutive expression of siRNA or shRNA constructs could metabolically tax host cells.[43]

One approach to overcome such side effects is to limit RNAi to those cells infected with the viral pathogen. The creation of shRNA expression constructs driven by RNA polymerase II promoters [44] has enabled the development of regulated promoters activated by viral infection. For example, in a recent study an antihepatitis C virus (HCV) siRNA construct was inserted in front of the HIV LTR promoter, which contains two NF-κB response elements and is thereby activated by HCV infection. The delivery of this construct to HepG2 cells transfected with full-length hepatitis C virus cDNA significantly silenced viral gene expression.[24] Similarly, Unwalla et al.[30] described a Tat-inducible vector that conditionally expresses anti-HIV shRNA only when HIV is present, thereby inhibiting HIV via a negative feedback mechanism. Alternatively, synthetic siRNA can be administered only upon viral infection, and the development of targeted delivery systems may enable specific delivery to affected cell types.[45]

Despite the challenges, a large and growing body of work demonstrates the far-reaching promise of antiviral RNAi once these obstacles can be fully overcome.

Viral target choice

RNAi has been used to inhibit the expression and block the replication of a broad range of viral species from many families of human and mammalian pathogens (summarized in Table 1). However, viruses vary widely in their basic biology and reproductive mechanisms, which suggests that unique strategies are needed to inhibit each particular virus (see Figure 1). As RNAi is currently understood, RISC-mediated RNA cleavage is restricted to cytoplasmically located target molecules, and since all viruses hijack cellular translation machinery to express their proteins, the targeting of virally encoded cytoplasmic mRNAs is a common locus at which all viruses should be susceptible to inhibition. In support of this assertion, it has been shown that a broad spectrum of viruses can be inhibited by targeting essential viral mRNAs. To date, the list of viruses successfully inhibited in this manner includes Epstein–Barr virus (EBV),[46] foot-and-mouth disease virus (FMDV),[47, 48] hepatitis B virus (HBV),[21, 22, 23] hepatitis C virus (HCV),[24, 49, 50, 51] human immunodeficiency virus type 1 (HIV-1),[10, 16, 25, 26, 27, 28, 29, 30, 31, 52] human papilloma virus (HPV),[53, 54] influenza virus A (IVA),[14, 17, 18, 55] Marburg virus,[56] human parainfluenza virus (PIV),[35, 57] poliovirus,[58, 59] rotavirus,[60, 61] RSV,[35, 57, 62] severe acute respiratory syndrome – associated coronavirus (SARS-CoV),[19, 20, 63, 64] vesicular stomatitis virus (VSV),[57] and West Nile virus (WNV).[55] In most of these cases, inhibition was achieved by directly reducing the viruses' ability to reproduce. However, Butz et al.[54] demonstrated that HPV pathogenesis could be reduced by targeting the viral inhibitor of apoptosis, E6, to limit viral spread by selectively inducing apoptosis in HPV-infected cells. This example also illustrates that each type of viral infection offers unique treatment options.

Table 1

Viruses inhibited with RNAi

Virus	Family	Genome	RNAi target	Type a	System (cell line/other)	RNAi inducer b	References
EBV	Herpesviridae	dsDNA	Zta	v	NA, 293	shRNA (p)	[46]
FMDV	Picornoviridae	RNA (+)	VP1	v	bhk-21, suckling mice	shRNA (p)	[47]
FMDV	Picornoviridae	RNA (+)	3P, 3D	v	bhk-21	siRNA	[48]
HBV	Hepadnaviridae	dsDNAc	HBsAg	v	HepG2.2.15, mice	siRNA	[21]
HBV	Hepadnaviridae	dsDNAc	core, Pol, S1, X	v	HuH-7, mice	shRNA (p)	[22]
HBV	Hepadnaviridae	dsDNAc	X, S	v	HuH-7, mice	shRNA (p)	[23]
HCV	Flaviviridae	RNA (+)	NS3, NS5B	v	HuH-7	siRNA	[49]
HCV	Flaviviridae	RNA (+)	5′ NTR, core	v	HuH-7	siRNA	[50]
HCV	Flaviviridae	RNA (+)	C	v	HepG2	shRNA (sv40)	[24]
HCV	Flaviviridae	RNA (+)	NS5B	v	HuH-7	siRNA	[51]
HCV	Flaviviridae	RNA (+)	La, PTB, hVAP-33	c	HuH-7	shRNA (p, ad)	[75]
HIV	Retroviridae	RNA (+)	CXCR4, CCR5 CD4	c	Magi-CXCR4+,-CCR5+, PBMCs	shRNA (p)	[69]
HIV	Retroviridae	RNA (+)	Rev	v	CD34+ HSC, scid mice	shRNA (l)	[16]
HIV	Retroviridae	RNA (+)	Gag	v	Jurkat, CEM-SS, HeLa-CD4+	shRNA (p)	[10]
HIV	Retroviridae	RNA (+)	Tat, Rev	v	H9	shRNA (aav)	[27]
HIV	Retroviridae	RNA (+)	CycT1, CDK9	c	HeLa	siRNA	[72]
HIV	Retroviridae	RNA (+)	Nef	v	SupT1	shRNA (r)	[29]
HIV	Retroviridae	RNA (+)	LTR-TAR, Vir, Nef	v	HeLa-CD4+, PBL	siRNA (p)	[25]
HIV	Retroviridae	RNA (+)	CXCR4	c	HeLa-CD4+/CXCR4+	siRNA	[68]
HIV	Retroviridae	RNA (+)	PARP-1	c	HeLa, J111	siRNA	[71]
HIV	Retroviridae	RNA (+)	Arp2	c	293	shRNA (p)	[32]
HIV	Retroviridae	RNA (+)	Tat,Rev	v	293/EcR	siRNA (p)	[26]
HIV	Retroviridae	RNA (+)	Tat, Rev	v	PBMCs, CD34+ monocytes	shRNA (l)	[28]
HIV	Retroviridae	RNA (+)	CXCR4, CCR5	c	U87-CD4-CXCR4, -CCR5	siRNA	[67]
HIV	Retroviridae	RNA (+)	Sam68	c	293T, HeLa	shRNA (p)	[33]
HIV	Retroviridae	RNA (+)	CD4, Gag	c, v	Magi-CCR5, HeLa-CD4, H9, ACH-2, PBL	siRNA	[52]
HIV	Retroviridae	RNA (+)	Rev	v	293/EcR, CEM, CD34+ HSC	shRNA (p, l)	[30]
HIV	Retroviridae	RNA (+)	Nef	v	SupT1	shRNA (r)	[31]
HIV	Retroviridae	RNA (+)	hRIP	c	HeLa, HL2/3, Jurkat, primary macrophages	siRNA	[73]
HTLV	Retroviridae	RNA (+)	TORC3	c	293T	siRNA	[74]
HPV	Papovaviridae	dsDNA	E6	v	HeLa, SiHa, MCF-7, MeWo, H1299	siRNA, shRNA (p)	[54]
HPV	Papovaviridae	dsDNA	E6, E7	v	HeLa	siRNA	[53]
IVA	Orthomyxoviridae	RNA (−)	NP, PA	v	MDCK, Vero, chicken embryos	siRNA	[17]
IVA	Orthomyxoviridae	RNA (−)	NP, PA, PB1	v	MDCK, Vero, mice	siRNA, shRNA (p, l)	[14]
IVA	Orthomyxoviridae	RNA (−)	M2 splice junction	v	293T, BHK	shRNA (p)	[55]
IVA	Orthomyxoviridae	RNA (−)	NP, PA	v	MDCK, mice	siRNA	[18]
Marburg	Filoviridae	RNA (−)	NP, VP35 and VP30	v	Vero, HeLa-CCL-2	siRNA	[56]
PIV	Paramyxoviridae	RNA (−)	F, HN, RdRP	v	A549	siRNA	[57]
PIV	Paramyxoviridae	RNA (−)	P	v	mice	siRNA	[35]
Poliovirus	Picornoviridae	RNA (+)	capsid, P3	v	HeLa S3, mouse embryonic fibroblasts	siRNA	[58]
Poliovirus	Picornoviridae	RNA (+)	capsid, P3	v	HeLa S3, P19	siRNA, esiRNA	[59]
Rotavirus	Reoviridae	dsRNA	VP4, VP7	v	MA104	siRNA	[61]
Rotavirus	Reoviridae	dsRNA	VP4	v	MA104	siRNA	[60]
RSV	Paramyxoviridae	RNA (−)	P, F, SH	v	A549	siRNA	[57]
RSV	Paramyxoviridae	RNA (−)	P, F	v	A549	siRNA	[62]
RSV	Paramyxoviridae	RNA (−)	P	v	A549, mice	siRNA	[35]
SARS-CoV	Coronaviridae	RNA (+)	Rep 1A	v	FRhk-4	siRNA	[19]
SARS-CoV	Coronaviridae	RNA (+)	Leader	v	293T, Vero E6	siRNA, shRNA (p)	[63]
SARS-CoV	Coronaviridae	RNA (+)	N	v	Vero E6	shRNA (p)	[64]
SARS-CoV	Coronaviridae	RNA (+)	48 genomic & coding	v	FRhk-4	siRNA	[20]
VSV	Rhabdoviridae	RNA (−)	M, RdRP	v	HEp-2	siRNA	[57]
WNV	Flaviviridae	RNA (+)	capsid, NS5	v	293T	shRNA (p)	[55]

av: viral target, c: cellular target.

bEndogenous expression indicated by aav (AAV vector), ad (adenoviral vector), l (lentiviral vector), r (retroviral vector) p (plasmid), sv40 (SV40 vector).

cHBV uses pregenomic RNA to template genomic DNA synthesis.

Figure 1

RNAi target selection must be tailored to the unique life cycle of the virus. HIV (a) and influenza (b) both have single-stranded RNA genomes, but each is susceptible to RNAi-mediated blocks at different points in its life cycle. This figure highlights viral and cellular targets that have been successfully utilized against HIV and influenza and indicates the steps of the viral replication cycles at which such blocks would occur. However, it is not intended to exhaustively depict all potential targets. Cellular targets appear in blue text, and viral targets appear in red.

When tailoring an RNAi-based therapy to a particular virus, the most important consideration is the unique life cycle of that virus. To a first degree of approximation, these life cycles can be grouped by the type of nucleic acids of which the viral genome is composed. For viruses with DNA genomes, the sole option is to target viral mRNA. For example, targeting HPV mRNAs was sufficient to block viral replication and reduce pathogenesis.[53, 54] However, when targeting viruses with positive-strand RNA genomes (where the viral genomes are transcribed in the same orientation as the viral mRNAs), genomic RNA and mRNA might be degraded simultaneously due to the fact that they share sequence identity. Direct cleavage of positive-strand genomic RNA has been demonstrated for HIV,[25] and HBV's pregenomic RNA (which serves as both an mRNA and a template for reverse transcription of genomic DNA) appears to be similarly susceptible,[21, 22, 23] but it is not yet clear whether simultaneous degradation of genomic and mRNA underlies the observed viral inhibition of the positive-strand RNA viruses HCV[24, 49, 50, 51] and SARS-CoV.[19, 20, 63, 64]

The situation appears more complex when targeting viruses with negative-strand RNA genomes. For example, it was shown when applying anti-influenza virus siRNAs that could potentially induce RNAi against either sense RNA (mRNA and genome-complementary RNA made during replication) or antisense RNA (genomic RNA), only mRNA was susceptible to RISC-mediated cleavage.[17] This selectivity was potentially due partially to the fact that influenza viral replication takes place in the nucleus, which isolates and protects viral RNA from RISC. However, a similar differential susceptibility of viral mRNA and genomic RNA was also observed when targeting RSV, which has a negative-strand RNA genome,[62] and rotavirus, which has a dsRNA genome.[61] These latter viruses reproduce in the cytoplasm and should thus be susceptible to RISC; however, again only viral mRNA was degraded. This selective vulnerability can be at least partly explained by the fact that the genomic RNAs of cytoplasmically replicating viruses are tightly bound by viral proteins that may protect the RNA from RISC. Moreover, since effective siRNAs are loaded asymmetrically into RISC, with a preference for one strand over the other, it is unlikely that both negative-strand RNA genomes and viral mRNAs will be targeted simultaneously by a single siRNA.[65] However, synergistic efficacy could be obtained by targeting the RNA-binding proteins expressed by cytoplasmically replicating RNA viruses, since such inhibition could both repress the production of new viruses and render genomic RNA more susceptible to RNAi-mediated cleavage. In any case, it is clear that each unique viral replication mechanism must be taken into consideration to achieve maximal RNAi-mediated inhibition.

Viral evolution

One drawback to targeting viral genes with RNAi is that viral mutation can lead to a loss of sensitivity to RNAi. This is an especially problematic possibility for the cases of RNA viruses, which accumulate point mutations up to 107-fold more rapidly than do their counterparts with DNA genomes.[66] In illustration of this problem, RNAi-resistant mutants arose in cell culture models while targeting HIV,[27, 29, 31] poliovirus,[58, 59] HCV[51] and HBV.[23] Although most of these mutants achieved resistance through point mutation or deletion of the target sequence, one HIV mutant escaped RNAi suppression by accumulating mutations outside of the target sequence, thereby creating a new local RNA secondary structure that presumably excluded RISC.[31] These results demonstrate conclusively that any effective RNAi-based antiviral therapy must compensate for the evolutionary potential of the pathogen.

It is possible that the problem of viral evolution can be circumvented by directing RNAi against essential cellular cofactors. Ideally, the loss of these cellular targets must block viral replication without inducing loss of function pathology in the cells. For example, HIV utilizes the chemokine receptors CCR5 and CXCR4 as co-receptors for cell entry, and downregulation of these genes in immune cells with RNAi blocks HIV infection.[67, 68, 69] Importantly, humans who are homozygous for deletions that abolish CCR5 expression have apparently normal immune function and are naturally more resistant to HIV.[70] In addition, targeting cellular receptors could truly protect cells from initial viral infection rather than only impair postinfection viral reproduction, which is what targeting viral genes achieves. In addition, producing a block at a viral entry step could strand the virus in the extracellular space for greater amounts of time, rendering it more susceptible to immune surveillance and clearance. Finally, for the virus to compensate for the loss of its primary receptor and/or coreceptor, it would need to make a challenging evolutionary leap comparable to acquiring novel tissue tropism or crossing a species barrier.

In addition to cell surface receptors, a number of host cellular RNAi targets that provide blocks at intracellular steps have also been identified. For example, the Arp2/3 complex mediates the nucleation step in actin polymerization, and this mechanism is used by some viruses and bacteria for intracellular transport. HIV infection was accordingly halted at the step of intracellular trafficking to the nucleus when cellular Arp2 was inhibited.[32] Downregulation of poly(ADP-ribose) polymerase 1 (PARP-1) abolished HIV integration and interfered with the activation of NF-κB-dependent genes, including the HIV long terminal repeat (LTR) promoter.[71] It is also possible to impede viral regulatory functions by targeting cellular proteins that interact with viral regulatory factors after the initiation of viral transcription. For example, HIV gene expression and replication are critically dependent upon the recruitment of the host transcriptional complex pTEFb, composed of cyclin T1 and CDK9, by the viral protein Tat. RNAi targeting of cyclin T1 and CDK9 was shown to impair HIV replication.[72] In addition, severely attenuated viral replication was observed when RNAi was directed against either Sam68 or human Rev-interacting protein (hRIP), both of which are required for HIV Rev-mediated nuclear export of unspliced viral genomic RNA.[33, 73]

Analogous to work with HIV, HTLV's Tax-mediated transcriptional activation was blocked by targeting TORC3, an essential cellular factor recruited to the viral promoter.[74] Furthermore, HCV replication was reduced by directing RNAi against various cellular factors, including La, polypyrimidine tract-binding protein (PTB), and human VAMP-associated protein of 33 kDa (hVAP-33).[75] Despite these positive results, a potential shortcoming of the cellular target approach is suggested by experiences with HIV-1. In general, viral replication was more severely crippled by targeting viral genes than by downregulating cellular genes alone.[76] Moreover, before any such cellular target-directed inhibition can be applied as a therapy, for patient safety it must be thoroughly demonstrated that even a total loss of target gene expression would not be harmful. Likewise, this approach in particular could benefit from the further development of strategies to spatially (in cells and tissues for which a virus has tropism) and/or temporally (upon viral infection) regulate RNAi induction.

Another strategy by which viral evolution might be thwarted is the simultaneous application of multiple RNAi-inducing species that target several sequences. This combinatorial strategy is the basis for HAART treatment for HIV, which has improved patient response to antiviral drugs by administering a cocktail of several compounds that targets multiple viral enzymes.[77] In fact, combination RNAi might improve efficacy over single-target treatment by several mechanisms. First, it has been shown that a synergistic inhibition of viral replication was achieved by targeting multiple loci of the same gene.[68] Secondly, by simultaneously targeting several viral genes and thus blocking multiple steps in the viral life cycle, enhanced inhibition can also be achieved.[20, 48] Similarly, simultaneous targeting of multiple cellular cofactors, such as the HIV receptor and coreceptors, led to enhanced viral inhibition.[69] Finally, to overcome this more potent inhibition, the virus would have to accumulate multiple mutations, which significantly reduces the possibility that a fully resistant mutant will emerge.[51, 59, 78] An analogous combinatorial approach is to combine RNAi interference with other gene therapy-mediated inhibitors of viral replication. For example, Rossi et al.[28] achieved enhanced HIV inhibition by using a gene therapy vector that simultaneously expressed siRNA directed against the HIV Rev protein, a nucleolar-localizing TAR decoy RNA, and a ribozyme that downregulates expression of the cellular CCR5 co-receptor. In fact, RNAi might be combined effectively with any number of antiviral therapeutics, including dominant-negative antiviral proteins and more traditional chemotherapeutic drugs, such as those currently used in HAART. Future work will need to synthesize these principles to identify antiviral strategies that provide effective and long-term suppression of viral replication and pathogenesis.

Future directions

It is clear from the abundance of studies in recent years that many possible strategies and options exist for blocking viral replication with RNAi. Therefore, as the field advances towards clinical trials, it is important to pose a key question: how does one design an optimal antiviral RNAi-based therapy? In addition to the extensive empirical data available and the safety, efficacy, and viral escape considerations described above, it would be useful to draw upon the growing wealth of computational and bioinformatics approaches to identify promising starting points for the empirical testing of antiviral strategies. Viruses often contain complex gene regulation circuits that exhibit nonlinear behavior,[79] and targeting specific loci in this circuitry may optimally suppress viral replication. For example, in analysis of a bacteriophage T7 model system, Endy et al.[80] employed a computational model to determine that antisense-mediated therapies should target viral genes involved in negative-feedback regulation in order to maximize resistance to viral escape. We recently reported the use of an agent-based stochastic simulation describing HIV replication and evolution in the presence of RNAi directed against the HIV TAR element. This model was used to identify criteria of siRNA dose, delivery efficiency, and RNAi target sequence choice (within TAR) required to maximize the probability of long-term viral inhibition.[78]

In the preparation of clinical antiviral RNAi therapies, it would also be prudent to draw upon the experiences gained using HAART to manage HIV infections. Clinical success with HAART can be improved by analyzing patients' primary viral isolates to predict viral drug susceptibility and thereby design drug regimens that resist treatment failure.[77] A direct, although costly, approach is to perform batteries of in vitro assays to test viral isolate susceptibility to different therapies. However, a more cost-effective approach employs statistical bioinformatics analysis of the viral genotype, that is, the dominant viral genetic sequences present in a patient's isolate.[81] For the most part, such approaches use large data sets to correlate viral genotypes with past histories of success or failure on specific drug regimens to guide the choice of optimal drugs. Recent developments have enhanced the predictive ability of such bioinformatics methods by explicitly including considerations of viral evolution. For example, Beerenwinkel et al.[82] have developed a strategy that utilizes the predicted phenotypes of both the viral isolate and its closest genetic ‘neighbors’. Although such approaches have proven effective in many cases and at least in the short term, many patients eventually develop drug-resistant infections.[83] In total, these experiences suggest that computational tools, in combination with relevant in vitro experiments and animal models, can improve the chances for clinical success (and avoid potential pitfalls) as antiviral RNAi therapies are prepared for human trials. Importantly, such proactive measures might preclude the need to amass large databases of clinical trials before effective solutions can be identified.

In summary, since the first demonstration of RNAi in a mammalian cell <5 years ago,[5] there has been enormous progress towards applying RNAi to antiviral therapy. Furthermore, clinical applications will benefit from the advantages that RNAi-based antiviral therapies hold over traditional drugs. Since the RNAi mechanism makes use of an innate cellular pathway, requiring the introduction of only a dsRNA trigger, it offers the potential for effective antiviral therapies with minimal side effects. This consideration is especially relevant when compared to current treatments for chronic infections, such as HIV, which consist of chemotherapeutic drugs that require complicated dosing schedules, can induce severe side effects that undermine patient compliance, and can even cause novel medical problems.[84] Moreover, although each antiviral RNAi therapy will need to target sequences tailored to the particular virus, the actual therapeutic delivery methods will be largely similar across many targets. Consequently, it should be possible to develop new RNAi-based therapies more rapidly than can be achieved with small molecule drugs. Such a readily adaptable approach would be useful in targeting viruses whose dominant genotype and phenotype vary seasonally, such as influenza, especially in cases where vaccination is difficult to predict or in years when the vaccine ineffectively targets the dominant strains. Similarly, once an effective antiviral RNAi-based therapy is developed, it might serve as a basis for quickly developing treatments for emerging viral infections, such as Ebola or SARS-CoV. Such treatments could be made available for treating acute infections, even before the full biology of such novel viruses has been elucidated. Finally, RNAi-based therapies might provide a first line of defense against viral strains that acquire, through natural or human means, resistance to drugs and vaccines previously found to be effective. Although much work remains to be carried out before clinical success is realized, RNAi-based therapies have emerged as highly promising, modular and versatile prospects for treating viral infections.