Controlling activation of the RNA-dependent protein kinase by siRNAs using site-specific chemical modification

The RNA-dependent protein kinase (PKR) is activated by binding to double-stranded RNA (dsRNA). Activation of PKR by short-interfering RNAs (siRNAs) and stimulation of the innate immune response has been suggested to explain certain off-target effects in some RNA interference experiments. Here we show that PKR's kinase activity is stimulated in vitro 3- to 5-fold by siRNA duplexes with 19 bp and 2 nt 3′-overhangs, whereas the maximum activation observed for poly(I)•poly(C) was 17-fold over background under the same conditions. Directed hydroxyl radical cleavage experiments indicated that siRNA duplexes have at least four different binding sites for PKR's dsRNA binding motifs (dsRBMs). The location of these binding sites suggested specific nucleotide positions in the siRNA sense strand that could be modified with a corresponding loss of PKR binding. Modification at these sites with N²-benzyl-2′-deoxyguanosine (BndG) blocked interaction with PKR's dsRBMs and inhibited activation of PKR by the siRNA. Importantly, modification of an siRNA duplex that greatly reduced PKR activation did not prevent the duplex from lowering mRNA levels of a targeted message by RNA interference in HeLa cells. Thus, these studies demonstrate that specific positions in an siRNA can be rationally modified to prevent interaction with components of cellular dsRNA-regulated pathways.     

Double-Stranded RNA-Activated Protein Kinase (PKR) Is Negatively Regulated by 60S Ribosomal Subunit Protein L18

The double-stranded RNA (dsRNA)-activated protein kinase (PKR) provides a fundamental control step in the regulation of protein synthesis initiation through phosphorylation of the alpha subunit of eukaryotic translation initiation factor 2 (eIF-2α), a process that prevents polypeptide chain initiation. In such a manner, activated PKR inhibits cell growth and induces apoptosis, whereas disruption of normal PKR signaling results in unregulated cell growth. Therefore, tight control of PKR activity is essential for regulated cell growth. PKR is activated by dsRNA binding to two conserved dsRNA binding domains within its amino terminus. We isolated a ribosomal protein L18 by interaction with PKR. L18 is a 22-kDa protein that is overexpressed in colorectal cancer tissue. L18 competed with dsRNA for binding to PKR, reversed dsRNA binding to PKR, and did not directly bind dsRNA. Mutation of K64E within the first dsRNA binding domain of PKR destroyed both dsRNA binding and L18 interaction, suggesting that the two interactive sites overlap. L18 inhibited both PKR autophosphorylation and PKR-mediated phosphorylation of eIF-2α in vitro. Overexpression of L18 by transient DNA transfection reduced eIF-2α phosphorylation and stimulated translation of a reporter gene in vivo. These results demonstrate that L18 is a novel regulator of PKR activity, and we propose that L18 prevents PKR activation by dsRNA while PKR is associated with the ribosome. Overexpression of L18 may promote protein synthesis and cell growth in certain cancerous tissue through inhibition of PKR activity.     

Variola virus E3L Zα domain,but not its Z-DNA binding activity,is required for PKR inhibition

Responding to viral infection, the interferon-induced, double-stranded RNA (dsRNA)–activated protein kinase PKR phosphorylates translation initiation factor eIF2α to inhibit cellular and viral protein synthesis. To overcome this host defense mechanism, many poxviruses express the protein E3L, containing an N-terminal Z-DNA binding (Zα) domain and a C-terminal dsRNA-binding domain (dsRBD). While E3L is thought to inhibit PKR activation by sequestering dsRNA activators and by directly binding the kinase, the role of the Zα domain in PKR inhibition remains unclear. Here, we show that the E3L Zα domain is required to suppress the growth-inhibitory properties associated with expression of human PKR in yeast, to inhibit PKR kinase activity in vitro, and to reverse the inhibitory effects of PKR on reporter gene expression in mammalian cells treated with dsRNA. Whereas previous studies revealed that the Z-DNA binding activity of E3L is critical for viral pathogenesis, we identified point mutations in E3L that functionally uncouple Z-DNA binding and PKR inhibition. Thus, our studies reveal a molecular distinction between the nucleic acid binding and PKR inhibitory functions of the E3L Zα domain, and they support the notion that E3L contributes to viral pathogenesis by targeting PKR and other components of the cellular anti-viral defense pathway.     

Mechanism of interaction of the double-stranded RNA (dsRNA) binding domain of protein kinase R with short dsRNA sequences

The dsRNA-activated protein kinase (PKR) plays a major role in the cellular response to viral infection. PKR contains an N-terminal dsRNA binding domain (dsRBD) and a C-terminal kinase domain. The dsRBD consists of two tandem copies of a conserved double-stranded RNA binding motif, dsRBM1 and dsRBM2. dsRNA binding is believed to activate PKR by inducing dimerization and subsequent autophosphorylation reactions. We have characterized the function of the dsRBD by assessing the binding of dsRBM1 and dsRBD to a series of dsRNA sequences ranging from 15 to 45 bp. For dsRBM1, the binding stoichiometries agree with an overlapping ligand binding model where the motif binds to multiple faces of the dsRNA duplex and overlaps along the helical axis. Similar behavior is observed for a dsRBD containing both dsRBM1 and dsRBM2 for sequences up to 30 bp; however, the binding affinity is enhanced 30-fold. Longer dsRNA sequences exhibit lower-than-expected stoichiometries, indicating a change in binding mode. NMR spectroscopy was used to define the regions of the dsRBD that interact with dsRNA. dsRNA binding induces exchange broadening of cross-peaks in 1H-15N HSQC spectra. For a 20 bp dsRNA, the resonances most affected map to the known dsRNA binding regions of dsRBM1 as well as the N-terminus of dsRBM2. For a longer 40 bp sequence, additional regions of dsRBM2 exhibit enhanced broadening. These data support a model in which dsRBM1 plays the dominant role in binding short dsRNA sequences and dsRBM2 makes additional interactions with the longer sequences capable of activating PKR.     

Inhibition of Double-Stranded RNA-Dependent Protein Kinase PKR by Vaccinia Virus E3: Role of Complex Formation and the E3 N-Terminal Domain

The human double-stranded RNA (dsRNA)-dependent protein kinase PKR inhibits protein synthesis by phosphorylating translation initiation factor 2α (eIF2α). Vaccinia virus E3L encodes a dsRNA binding protein that inhibits PKR in virus-infected cells, presumably by sequestering dsRNA activators. Expression of PKR in Saccharomyces cerevisiae inhibits protein synthesis by phosphorylation of eIF2α, dependent on its two dsRNA binding motifs (DRBMs). We found that expression of E3 in yeast overcomes the lethal effect of PKR in a manner requiring key residues (Lys-167 and Arg-168) needed for dsRNA binding by E3 in vitro. Unexpectedly, the N-terminal half of E3, and residue Trp-66 in particular, also is required for anti-PKR function. Because the E3 N-terminal region does not contribute to dsRNA binding in vitro, it appears that sequestering dsRNA is not the sole function of E3 needed for inhibition of PKR. This conclusion was supported by the fact that E3 activity was antagonized, not augmented, by overexpressing the catalytically defective PKR-K296R protein containing functional DRBMs. Coimmunoprecipitation experiments showed that a majority of PKR in yeast extracts was in a complex with E3, whose formation was completely dependent on the dsRNA binding activity of E3 and enhanced by the N-terminal half of E3. In yeast two-hybrid assays and in vitro protein binding experiments, segments of E3 and PKR containing their respective DRBMs interacted in a manner requiring E3 residues Lys-167 and Arg-168. We also detected interactions between PKR and the N-terminal half of E3 in the yeast two-hybrid and λ repressor dimerization assays. In the latter case, the N-terminal half of E3 interacted with the kinase domain of PKR, dependent on E3 residue Trp-66. We propose that effective inhibition of PKR in yeast requires formation of an E3-PKR-dsRNA complex, in which the N-terminal half of E3 physically interacts with the protein kinase domain of PKR.     

Paradoxical interactions between human delta hepatitis agent RNA and the cellular protein kinase PKR.

The genome of the human delta hepatitis agent is a circular, highly structured single-stranded RNA lacking regular runs of RNA-RNA duplex longer than 15 bp. We have tested the ability of delta agent RNA to participate in reactions with a protein containing a motif which confers the ability to bind double-stranded RNA (dsRNA). Surprisingly, highly purified delta agent RNA preparations from which all traces of contaminating dsRNA have been removed activate PKR, the dsRNA-dependent protein kinase activity of mammalian cells (also known as DAI, P1-eIF-2, and p68 kinase). This behavior is in marked contrast to the interaction of PKR with a number of other highly structured viral single-stranded RNAs, which inhibit, rather than stimulate, activation of this kinase. PKR activation leads to inhibition of protein synthesis in the rabbit reticulocyte lysate system. Paradoxically, delta RNA failed to elicit the expected PKR-mediated inhibition of cell-free translation. Instead, delta RNA interfered with PKR activation and the translational block induced by dsRNA. We conclude that the interaction of PKR and delta agent RNA may represent a new category of protein-RNA interactions involving the dsRNA binding motif.     

Requirement of PKR Dimerization Mediated by Specific Hydrophobic Residues for Its Activation by Double-Stranded RNA and Its Antigrowth Effects in Yeast

The roles of protein dimerization and double-stranded RNA (dsRNA) binding in the biochemical and cellular activities of PKR, the dsRNA-dependent protein kinase, were investigated. We have previously shown that both properties of the protein are mediated by the same domain. Here we show that dimerization is mediated by hydrophobic residues present on one side of an amphipathic α-helical structure within this domain. Appropriate substitution mutations of residues on that side produced mutants with increased or decreased dimerization activities. Using these mutants, we demonstrated that dimerization is not essential for dsRNA binding. However, enhancing dimerization artificially, by providing an extraneous dimerization domain, increased dsRNA binding of both wild-type and mutant proteins. In vitro, the dimerization-defective mutants could not be activated by dsRNA but were activated normally by heparin. In Saccharomyces cerevisiae, unlike wild-type PKR, these mutants could not inhibit cell growth and the dsRNA-binding domain of the dimerization-defective mutants could not prevent the antigrowth effect of wild-type PKR. These results demonstrate the biological importance of the dimerization properties of PKR.     

Phosphorylation of the RNA-dependent protein kinase regulates its RNA-binding activity

The RNA-dependent protein kinase (PKR) is an interferon-induced, RNA-activated enzyme that phosphorylates the α-subunit of eukaryotic initiation factor 2 (eIF2α), inhibiting the function of the eIF2 complex and continued initiation of translation. When bound to an activating RNA and ATP, PKR undergoes autophosphorylation reactions at multiple serine and threonine residues. This autophosphorylation reaction stimulates the eIF2α kinase activity of PKR. The binding of certain viral RNAs inhibits the activation of PKR. Wild-type PKR is obtained as a highly phosphorylated protein when overexpressed in Escherichia coli. We report here that treatment of the isolated phosphoprotein with the catalytic subunit of protein phosphatase 1 dephosphorylates the enzyme. The in vitro autophosphorylation and eIF2α kinase activities of the dephosphorylated enzyme are stimulated by addition of RNA. Thus, inactivation by phosphatase treatment of autophosphorylated PKR obtained from overexpression in bacteria generates PKR in a form suitable for in vitro analysis of the RNA-induced activation mechanism. Furthermore, we used gel mobility shift assays, methidiumpropyl-EDTA·Fe footprinting and affinity chromatography to demonstrate differences in the RNA-binding properties of phospho- and dephosphoPKR. We found that dephosphorylation of PKR increases binding affinity of the enzyme for both kinase activating and inhibiting RNAs. These results are consistent with an activation mechanism that includes release of the activating RNA upon autophosphorylation of PKR prior to phosphorylation of eIF2α.     

Linkage of a triple helix-forming oligonucleotide to amsacrine-4-carboxamide derivatives modulates the sequence-selectivity of topoisomerase II-mediated DNA cleavage

Amsacrine-4-carboxamide-oligonucleotide conjugates were synthesized and studied for their capacity to form DNA triple helices and to alter human topoisomerase II binding and cleavage properties. The intercalating agent was attached to the 3'- or the 5'-end of a 24 nt triple helix-forming oligonucleotide via linkers of different lengths. The stability of these DNA triple helices was investigated by gel retardation and melting temperature studies using a synthetic 70 bp DNA duplex target. The effect of the conjugates on DNA cleavage by topoisomerase II was evaluated using the 70 bp duplex and a 311 bp restriction fragment containing the same triple helix site. The conjugate with the amsacrine derivative linked to the 3' end of the TFO via a hexaethylene glycol linker modulates the extent of DNA cleavage by topoisomerase II at specific sites.     

Linkage of a Triple Helix-Forming Oligonucleotide to Amsacrine-4-carboxamide Derivatives Modulates the Sequence-Selectivity of Topoisomerase II-Mediated DNA Cleavage

Abstract

Amsacrine-4-carboxamide-oligonucleotide conjugates were synthesized and studied for their capacity to form DNA triple helices and to alter human topoisomerase II binding and cleavage properties. The intercalating agent was attached to the 3′- or the 5′-end of a 24 nt triple helix-forming oligonucleotide via linkers of different lengths. The stability of these DNA triple helices was investigated by gel retardation and melting temperature studies using a synthetic 70 bp DNA duplex target. The effect of the conjugates on DNA cleavage by topoisomerase II was evaluated using the 70 bp duplex and a 311 bp restriction fragment containing the same triple helix site. The conjugate with the amsacrine derivative linked to the 3′ end of the TFO via a hexaethylene glycol linker modulates the extent of DNA cleavage by topoisomerase II at specific sites.     

The Structure of the Cyprinid herpesvirus 3 ORF112-Zα·Z-DNA Complex Reveals a Mechanism of Nucleic Acids Recognition Conserved with E3L,a Poxvirus Inhibitor of Interferon Response

In vertebrate species, the innate immune system down-regulates protein translation in response to viral infection through the action of the double-stranded RNA (dsRNA)-activated protein kinase (PKR). In some teleost species another protein kinase, Z-DNA-dependent protein kinase (PKZ), plays a similar role but instead of dsRNA binding domains, PKZ has Zα domains. These domains recognize the left-handed conformer of dsDNA and dsRNA known as Z-DNA/Z-RNA. Cyprinid herpesvirus 3 infects common and koi carp, which have PKZ, and encodes the ORF112 protein that itself bears a Zα domain, a putative competitive inhibitor of PKZ. Here we present the crystal structure of ORF112-Zα in complex with an 18-bp CpG DNA repeat, at 1.5 Å. We demonstrate that the bound DNA is in the left-handed conformation and identify key interactions for the specificity of ORF112. Localization of ORF112 protein in stress granules induced in Cyprinid herpesvirus 3-infected fish cells suggests a functional behavior similar to that of Zα domains of the interferon-regulated, nucleic acid surveillance proteins ADAR1 and DAI.     

Recognition of viral RNA stem–loops by the tandem double-stranded RNA binding domains of PKR

In humans, the double-stranded RNA (dsRNA)-activated protein kinase (PKR) is expressed in late stages of the innate immune response to viral infection by the interferon pathway. PKR consists of tandem dsRNA binding motifs (dsRBMs) connected via a flexible linker to a Ser/Thr kinase domain. Upon interaction with viral dsRNA, PKR is converted into a catalytically active enzyme capable of phosphorylating a number of target proteins that often results in host cell translational repression. A number of high-resolution structural studies involving individual dsRBMs from proteins other than PKR have highlighted the key features required for interaction with perfectly duplexed RNA substrates. However, viral dsRNA molecules are highly structured and often contain deviations from perfect A-form RNA helices. By use of small-angle X-ray scattering (SAXS), we present solution conformations of the tandem dsRBMs of PKR in complex with two imperfectly base-paired viral dsRNA stem–loops; HIV-1 TAR and adenovirus VA_I-AS. Both individual components and complexes were purified by size exclusion chromatography and characterized by dynamic light scattering at multiple concentrations to ensure monodispersity. SAXS ab initio solution conformations of the individual components and RNA–protein complexes were determined and highlight the potential of PKR to interact with both stem and loop regions of the RNA. Excellent agreement between experimental and model-based hydrodynamic parameter determination heightens our confidence in the obtained models. Taken together, these data support and provide a framework for the existing biochemical data regarding the tolerance of imperfectly base-paired viral dsRNA by PKR.     

RNA Dimerization Promotes PKR Dimerization and Activation

The double-stranded RNA (dsRNA)-activated protein kinase [protein kinase R (PKR)] plays a major role in the innate immune response in humans. PKR binds dsRNA non-sequence specifically and requires a minimum of 15-bp dsRNA for one protein to bind and 30-bp dsRNA to induce protein dimerization and activation by autophosphorylation. PKR phosphorylates eukaryotic initiation factor 2α, a translation initiation factor, resulting in the inhibition of protein synthesis. We investigated the mechanism of PKR activation by an RNA hairpin with a number of base pairs intermediate between these 15- to 30-bp limits: human immunodeficiency virus type 1 transactivation-responsive region (TAR) RNA, a 23-bp hairpin with three bulges that is known to dimerize. TAR monomers and dimers were isolated from native gels and assayed for RNA and protein dimerization to test whether RNA dimerization affects PKR dimerization and activation. To modulate the extent of dimerization, we included TAR mutants with different secondary features. Native gel mixing experiments and analytical ultracentrifugation indicate that TAR monomers bind one PKR monomer and that TAR dimers bind two or three PKRs, demonstrating that RNA dimerization drives the binding of multiple PKR molecules. Consistent with functional dimerization of PKR, TAR dimers activated PKR while TAR monomers did not, and RNA dimers with fewer asymmetrical secondary-structure defects, as determined by enzymatic structure mapping, were more potent activators. Thus, the secondary-structure defects in the TAR RNA stem function as antideterminants to PKR binding and activation. Our studies support that dimerization of a 15- to 30-bp hairpin RNA, which effectively doubles its length, is a key step in driving activation of PKR and provide a model for how RNA folding can be related to human disease.     

A dynamically tuned double-stranded RNA binding mechanism for the activation of antiviral kinase PKR

A key step in the activation of interferon-inducible antiviral kinase PKR involves differential binding of viral double-stranded RNA (dsRNA) to its two structurally similar N-terminal dsRNA binding motifs, dsRBM1 and dsRBM2. We show here, using NMR spectroscopy, that dsRBM1 with higher RNA binding activity exhibits significant motional flexibility on a millisecond timescale as compared with dsRBM2 with lower RNA binding activity. We further show that dsRBM2, but not dsRBM1, specifically interacts with the C-terminal kinase domain. These results suggest a dynamically tuned dsRNA binding mechanism for PKR activation, where motionally more flexible dsRBM1 anchors to dsRNA, thereby inducing a cooperative RNA binding for dsRBM2 to expose the kinase domain.     

Site-specific modification and RNA crosslinking of the RNA-binding domain of PKR

RNA-dependent protein kinase (PKR) is an interferon-induced, RNA-activated enzyme that phosphorylates and inhibits the function of the translation initiation factor eIF-2. PKR is activated in vitro by binding RNA molecules with extensive duplex structure. To further define the nature of the RNA regulation of PKR, we have prepared and characterized site-specifically modified proteins consisting of the PKR 20 kDa RNA-binding domain (RBD). Here we show that the two cysteines found naturally in this domain can be altered by site-directed mutagenesis without loss of RNA binding affinity or the RNA-regulated kinase activity. Introduction of cysteine residues at other sites in the PKR RBD allows for site-specific modification with thiol-selective reagents. PKR RBD mutants reacted selectively with a maleimide to introduce a photoactivatable crosslinking aryl azide at three different positions in the protein. RNA crosslinking efficiency was found to be dependent on the amino acid modified, suggesting differences in access to the RNA from these positions in the protein. One of the amino acid modifications that led to crosslinking of the RNA is located at a residue known to be an autophosphorylation site, suggesting that autophosphorylation at this site could influence the RNA binding properties of PKR. The PKR RBD conjugates described here and other similar reagents prepared via these methods are applicable to future studies of PKR–RNA complexes using techniques such as photocrosslinking, fluorescence resonance energy transfer and affinity cleaving.     

Binding of double-stranded RNA to protein kinase PKR is required for dimerization and promotes critical autophosphorylation events in the activation loop

Protein kinase PKR is activated by double-stranded RNA (dsRNA) and phosphorylates translation initiation factor 2alpha to inhibit protein synthesis in virus-infected mammalian cells. PKR contains two dsRNA binding motifs (DRBMs I and II) required for activation by dsRNA. There is strong evidence that PKR activation requires dimerization, but the role of dsRNA in dimer formation is controversial. By making alanine substitutions predicted to remove increasing numbers of side chain contacts between the DRBMs and dsRNA, we found that dimerization of full-length PKR in yeast was impaired by the minimal combinations of mutations required to impair dsRNA binding in vitro. Mutation of Ala-67 to Glu in DRBM-I, reported to abolish dimerization without affecting dsRNA binding, destroyed both activities in our assays. By contrast, deletion of a second dimerization region that overlaps the kinase domain had no effect on PKR dimerization in yeast. Human PKR contains at least 15 autophosphorylation sites, but only Thr-446 and Thr-451 in the activation loop were found here to be critical for kinase activity in yeast. Using an antibody specific for phosphorylated Thr-451, we showed that Thr-451 phosphorylation is stimulated by dsRNA binding. Our results provide strong evidence that dsRNA binding is required for dimerization of full-length PKR molecules in vivo, leading to autophosphorylation in the activation loop and stimulation of the eIF2alpha kinase function of PKR.     

Selective binding by the RNA binding domain of PKR revealed by affinity cleavage

The RNA-dependent protein kinase (PKR) is regulated by the binding of double-stranded RNA (dsRNA) or single-stranded RNAs with extensive duplex secondary structure. PKR has an RNA binding domain (RBD) composed of two copies of the dsRNA binding motif (dsRBM). The dsRBM is an alpha-beta-beta-beta-alpha structure present in a number of proteins that bind RNA, and the selectivity demonstrated by these proteins is currently not well understood. We have used affinity cleavage to study the binding of PKR's RBD to RNA. In this study, we site-specifically modified the first dsRBM of PKR's RBD at two different amino acid positions with the hydroxyl radical generator EDTA.Fe. Cleavage by these proteins of a synthetic stem-loop ligand of PKR indicates that PKR's dsRBMI binds the RNA in a preferred orientation, placing the loop between strands beta1 and beta2 near the single-stranded RNA loop. Additional cleavage experiments demonstrated that defects in the RNA stem, such as an A bulge and two GA mismatches, do not dictate dsRBMI's binding orientation preference. Cleavage of VA(I) RNA, an adenoviral RNA inhibitor of PKR, indicates that dsRBMI is bound near the loop of the apical stem of this RNA in the same orientation as observed with the synthetic stem-loop RNA ligands. This work, along with an NMR study of the binding of a dsRBM derived from the Drosophila protein Staufen, indicates that dsRBMs can bind stem-loop RNAs in distinct ways. In addition, the successful application of the affinity cleavage technique to localizing dsRBMI of PKR on stem-loop RNAs and defining its orientation suggests this approach could be applied to dsRBMs found in other proteins.