Double-stranded DNA-induced localized unfolding of HCV NS3 helicase subdomain 2

Helicase inhibitors as specifically targeted antiviral therapy for hepatitis C

The hepatitis C virus (HCV) leads to chronic liver disease and affects more than 2% of the world's population. Complications of the disease include fibrosis, cirrhosis and hepatocellular carcinoma. Current therapy for chronic HCV infection, a combination of ribavirin and pegylated IFN-alpha, is expensive, causes profound side effects and is only moderately effective against several common HCV strains. Specifically targeted antiviral therapy for hepatitis C (STAT-C) will probably supplement or replace present therapies. Leading compounds for STAT-C target the HCV nonstructural (NS)5B polymerase and NS3 protease, however, owing to the constant threat of viral resistance, other targets must be continually developed. One such underdeveloped target is the helicase domain of the HCV NS3 protein. The HCV helicase uses energy derived from ATP hydrolysis to separate based-paired RNA or DNA. This article discusses unique features of the HCV helicase, recently discovered compounds that inhibit HCV helicase catalyzed reactions and HCV cellular replication, and new methods to monitor helicase action in a high-throughput format.

Viral Helicases

Helicases are motor proteins that use the free energy of NTP hydrolysis to catalyze the unwinding of duplex nucleic acids. Helicases participate in almost all processes involving nucleic acids. Their action is critical for replication, recombination, repair, transcription, translation, splicing, mRNA editing, chromatin remodeling, transport, and degradation (Matson and Kaiser-Rogers 1990; Matson et al. 1994; Mendonca et al. 1995; Luking et al. 1998).

The hepatitis C virus NS3 protein: a model RNA helicase and potential drug target

The C-terminal portion of hepatitis C virus (HCV) nonstructural protein 3 (NS3) forms a three domain polypeptide that possesses the ability to travel along RNA or single-stranded DNA (ssDNA) in a 3' to 5' direction. Fueled byATP hydrolysis, this movement allows the protein to displace complementary strands of DNA or RNA and proteins bound to the nucleic acid. HCV helicase shares two domains common to other motor proteins, one of which appears to rotate upon ATP binding. Several models have been proposed to explain how this conformational change leads to protein movement and RNA unwinding, but no model presently explains all existing experimental data. Compounds recently reported to inhibit HCV helicase, which include numerous small molecules, RNA aptamers and antibodies, will be useful for elucidating the role of a helicase in positive-sense single-stranded RNA virus replication and might serve as templates for the design of novel antiviral drugs.

Disorder-order folding transitions underlie catalysis in the helicase motor of SecA

SecA is a helicase-like motor that couples ATP hydrolysis with the translocation of extracytoplasmic protein substrates. As in most helicases, this process is thought to occur through nucleotide-regulated rigid-body movement of the motor domains. NMR, thermodynamic and biochemical data show that SecA uses a novel mechanism wherein conserved regions lining the nucleotide cleft undergo cycles of disorder-order transitions while switching among functional catalytic states. The transitions are regulated by interdomain interactions mediated by crucial 'arginine finger' residues located on helicase motifs. Furthermore, we show that the nucleotide cleft allosterically communicates with the preprotein substrate-binding domain and the regulatory, membrane-inserting C domain, thereby allowing for the coupling of the ATPase cycle to the translocation activity. The intrinsic plasticity and functional disorder-order folding transitions coupled to ligand binding seem to provide a precise control of the catalytic activation process and simple regulation of allosteric mechanisms.

Viral and cellular RNA helicases as antiviral targets

To date, although many viral infections can be successfully prevented via vaccination, we lack effective knowledge of vaccines for numerous important human pathogens, including hepatitis C virus (HCV) and human immunodeficiency virus (HIV). Accordingly, antiviral drugs will be needed to treat many viral diseases. Virally encoded enzymes and cellular enzymes adapted for use by viruses for replication might represent useful targets for antiviral drugs.

Drugs that target either a viral or cellular polypeptide hold different implications. Inhibitors of unique viral functions have a lower risk of toxicity, whereas inhibitors of cellular enzymes that are used by viruses have a narrower window for efficacy without creating toxicity.

All viruses seem to require a helicase function for replication. HCV encodes a viral RNA helicase, and recent findings have shown that HIV-1 adapts a cellular RNA helicase for its viral lifecycle. These observations raise the possibility of small-molecule helicase inhibitors as a general mode of antiviral therapy.

Helicases fall into three super-families (SF1, SF2 and SF3) with conserved motifs. The conserved motifs are associated with conserved helicase function. However, outside of the conserved motifs the primary sequences and tertiary structures between helicases are differ greatly. In this regard, differences in primary sequence and tertiary structure between the helicase of a viral pathogen and that of cellular helicases can be exploited to confer specificity to an antiviral inhibitor.

The conformation of an active helicase can be broadly divided into an 'open' and a 'closed' complex. Strategies for identifying small-molecule helicase inhibitors include: inhibiting NTPase activity by direct competition with NTP binding; competitively inhibit nucleic-acid binding; inhibiting NTP hydrolysis or NDP release by blocking the movement of domain 2; inhibiting the process that couples NTP hydrolysis to translocation and unwinding of nucleic acid; inhibiting unwinding by sterically blocking helicase translocation; and inhibiting unwinding. Other potential inhibitory mechanisms include those that change the physical conformation of the helicase, or those that disrupt helicase turnover, or those that inhibit helicase interaction with other crucial proteins.

Preclinical proof of concept for helicase inhibitors as antiviral agents has been obtained for HSV. This breakthrough finding provides the best evidence to date that it is possible to develop selective, potent inhibitors of a viral helicase as antiviral agents. Searches are ongoing for antihelicase molecules that have activity against HCV or HIV-1.

Although there has been considerable progress in the development of antiviral agents in recent years, there is still a pressing need for new drugs both to improve on the properties of existing agents and to combat the problem of viral resistance. Helicases, both viral and human, have recently emerged as novel targets for the treatment of viral infections. Here, we discuss the role of these enzymes, factors affecting their potential as drug targets and progress in the development of agents that inhibit their activity using the hepatitis C virus-encoded helicase NS3 and the cellular helicase DDX3 adopted for use by HIV-1 as examples.

Enhanced nucleic acid binding to ATP-bound hepatitis C virus NS3 helicase at low pH activates RNA unwinding

The molecular basis of the low-pH activation of the helicase encoded by the hepatitis C virus (HCV) was examined using either a full-length NS3 protein/NS4A cofactor complex or truncated NS3 proteins lacking the protease domain, which were isolated from three different viral genotypes. All proteins unwound RNA and DNA best at pH 6.5, which demonstrate that conserved NS3 helicase domain amino acids are responsible for low-pH enzyme activation. DNA unwinding was less sensitive to pH changes than RNA unwinding. Both the turnover rate of ATP hydrolysis and the K(m) of ATP were similar between pH 6 and 10, but the concentration of nucleic acid needed to stimulate ATP hydrolysis decreased almost 50-fold when the pH was lowered from 7.5 to 6.5. In direct-binding experiments, HCV helicase bound DNA weakly at high pH only in the presence of the non-hydrolyzable ATP analog, ADP(BeF3). These data suggest that a low-pH environment might be required for efficient HCV RNA translation or replication, and support a model in which an acidic residue rotates toward the RNA backbone upon ATP binding repelling nucleic acid from the binding cleft.