Magnesium-Dependent Interaction of PKR with Adenovirus VAI

Protein kinase R (PKR) is an interferon-induced kinase that plays a pivotal role in the innate immunity pathway for defense against viral infection. PKR is activated to undergo autophosphorylation upon binding to RNAs that contain duplex regions. Activated PKR phosphorylates the α-subunit of eukaryotic initiation factor 2, thereby inhibiting protein synthesis in virus-infected cells. Viruses have evolved diverse PKR-inhibitory strategies to evade the antiviral response. Adenovirus encodes virus-associated RNA I (VAI), a highly structured RNA inhibitor that binds PKR but fails to activate. We have characterized the stoichiometry and affinity of PKR binding to define the mechanism of PKR inhibition by VAI. Sedimentation velocity and isothermal titration calorimetry measurements indicate that PKR interactions with VAI are modulated by Mg²⁺. Two PKR monomers bind in the absence of Mg²⁺, but a single monomer binds in the presence of divalent ion. Known RNA activators of PKR are capable of binding multiple PKR monomers to allow the kinase domains to come into close proximity and thus enhance dimerization. We propose that VAI acts as an inhibitor of PKR because it binds and sequesters a single PKR in the presence of divalent cation.     

Higher-order substrate recognition of eIF2alpha by the RNA-dependent protein kinase PKR

In response to binding viral double-stranded RNA byproducts within a cell, the RNA-dependent protein kinase PKR phosphorylates the alpha subunit of the translation initiation factor eIF2 on a regulatory site, Ser51. This triggers the general shutdown of protein synthesis and inhibition of viral propagation. To understand the basis for substrate recognition by and the regulation of PKR, we determined X-ray crystal structures of the catalytic domain of PKR in complex with eIF2alpha. The structures reveal that eIF2alpha binds to the C-terminal catalytic lobe while catalytic-domain dimerization is mediated by the N-terminal lobe. In addition to inducing a local unfolding of the Ser51 acceptor site in eIF2alpha, its mode of binding to PKR affords the Ser51 site full access to the catalytic cleft of PKR. The generality and implications of the structural mechanisms uncovered for PKR to the larger family of four human eIF2alpha protein kinases are discussed.     

The double-strand RNA-dependent protein kinase PKR plays a significant role in a sustained ER stress-induced apoptosis

Sustained ER stress leads to apoptosis. However, the exact mechanism still remains to be elucidated. Here, we demonstrate that the double strand RNA-dependent protein kinase (PKR) is involved in the ER stress-mediated signaling pathway. ER stress rapidly activated PKR, inducing the phosphorylation of eIF2alpha, followed by the activation of the ATF4/CHOP pathway. ER-stress-mediated eIF2alpha/ATF4/CHOP signaling and associated cell death was markedly reduced by PKR knockdown. We also found that PKR activation was mediated by PACT, the expression of which was elevated by ER-stress. These results indicate that the ER-stress-mediated eIF2alpha/ATF4/CHOP/cell death pathway is, to some degree, dependent on PACT-mediated PKR activation apart from the PERK pathway.     

A truncated Danio rerio PKZ isoform functionally interacts with eIF2α and inhibits protein synthesis

A protein kinase containing Z-DNA binding domains (PKZ), which resembles protein kinase R (PKR) in domain organization, was recently discovered to be a member of the eIF2α kinase family in fish. PKR has roles in antiviral immunity through inhibiting protein synthesis and activating NF-κB; therefore, it is thought that PKZ may have a similar role in fish antiviral immunity. In the present study, the roles of two Danio rerio PKZ isoforms (DrPKZ-A and DrPKZ-B) in eIF2α phosphorylation and protein synthesis regulation were explored. DrPKZ-A and DrPKZ-B possess N-terminal Z-DNA binding domains and a conserved eIF2α kinase domain; however, they have domains of differing lengths inserted between kinase subdomains IV and V. DrPKZ-A has an insert domain of 73 amino acids (aa), whereas DrPKZ-B has an insert sequence of only 10 aa, suggesting that DrPKZ-B could be a dysfunctional isoform or could interact with different substrates. Our results show that both DrPKZ-A and DrPKZ-B functionally interact with eIF2α and inhibit protein synthesis, although DrPKZ-B possesses attenuated kinase activity. Our results also show that deletion of the insert in either isoform results in the complete abrogation of kinase activity, suggesting that the insert is critical for PKZ kinase activity. Kinase activity appears to be independent of insert length but may depend on the presence of specific amino acids within the insert domain. Furthermore, the effects of the N-terminal regulatory domain on kinase activity were analyzed. Deletion of the N-terminus results in reduced kinase activity of these isoforms relative to the wild-type forms, indicating that the isolated kinase domain is sufficient for eIF2α phosphorylation and that DrPKZ-A and DrPKZ-B may be regulated in a similar manner. Overall, our results show that DrPKZ-B is a functional kinase in zebrafish and contribute to our understanding of the function of PKZ in fish.     

Ebp1 is a dsRNA-binding protein associated with ribosomes that modulates eIF2alpha phosphorylation

dsRNA-binding domains (dsRBDs) characterize an expanding family of proteins involved in different cellular processes, ranging from RNA editing and processing to translational control. Here we present evidence that Ebp1, a cell growth regulating protein that is part of ribonucleoprotein (RNP) complexes, contains a dsRBD and that this domain mediates its interaction with dsRNA. Deletion of Ebp1's dsRBD impairs its localization to the nucleolus and its ability to form RNP complexes. We show that in the cytoplasm, Ebp1 is associated with mature ribosomes and that it is able to inhibit the phosphorylation of serine 51 in the eukaryotic initiation factor 2 alpha (eIF2alpha). In response to various cellular stress, eIF2alpha is phosphorylated by distinct protein kinases (PKR, PERK, GCN2, and HRI), and this event results in protein translation shut-down. Ebp1 overexpression in HeLa cells is able to protect eIF2alpha from phosphorylation at steady state and also in response to various treatments. We demonstrate that Ebp1 interacts with and is phosphorylated by the PKR protein kinase. Our results demonstrate that Ebp1 is a new dsRNA-binding protein that acts as a cellular inhibitor of eIF2alpha phosphorylation suggesting that it could be involved in protein translation control.     

Polypyrimidine tract-binding protein stimulates the poliovirus IRES by modulating eIF4G binding

Tethered hydroxyl‐radical probing has been used to determine the orientation of binding of polypyrimidine tract‐binding protein (PTB) to the poliovirus type 1 (Mahoney) (PV‐1(M)) internal ribosome entry site/segment (IRES)—the question of which RNA‐binding domain (RBD) binds to which sites on the IRES. The results show that under conditions in which PTB strongly stimulates IRES activity, a single PTB is binding to the IRES, a finding which was confirmed by mass spectrometry of PTB/IRES complexes. RBDs1 and 2 interact with the basal part of the Domain V irregular stem loop, very close to the binding site of eIF4G, and RBDs3 and 4 interact with the single‐stranded regions flanking Domain V. The binding of PTB is subtly altered in the presence of the central domain (p50) of eIF4G, and p50 binding is likewise modified if PTB is present. This suggests that PTB stimulates PV‐1(M) IRES activity by inducing eIF4G to bind in the optimal position and orientation to promote internal ribosome entry, which, in PV‐1(M), is at an AUG triplet 30 nt downstream of the base of Domain V.     

Mechanism of PKR activation: dimerization and kinase activation in the absence of double-stranded RNA

The kinase PKR is a central component of the interferon antiviral pathway. PKR is activated upon binding double-stranded (ds) RNA to undergo autophosphorylation. Although PKR is known to dimerize, the relationship between dimerization and activation remains unclear. Here, we directly characterize dimerization of PKR in free solution using analytical ultracentrifugation and correlate self-association with autophosphorylation activity. Latent, unphosphorylated PKR exists predominantly as a monomer at protein concentrations below 2 mg/ml. A monomer sedimentation coefficient of s(20,w)(0)=3.58 S and a frictional ratio of f/f(0)=1.62 indicate an asymmetric shape. Sedimentation equilibrium measurements indicate that PKR undergoes a weak, reversible monomer-dimer equilibrium with K(d)=450 microM. This dimerization reaction serves to initiate a previously unrecognized dsRNA-independent autophosphorylation reaction. The resulting activated enzyme is phosphorylated on the two critical threonine residues present in the activation loop and is competent to phosphorylate the physiological substrate, eIF2alpha. Dimer stability is enhanced by approximately 500-fold upon autophosphorylation. We propose a chain reaction model for PKR dsRNA-independent activation where dimerization of latent enzyme followed by intermolecular phosphorylation serves as the initiation step. Subsequent propagation steps likely involve phosphorylation of latent PKR monomers by activated enzyme within high-affinity heterodimers. Our results support a model whereby dsRNA functions by bringing PKR monomers into close proximity in a manner that is analogous to the dimerization of free PKR.     

Heparin activates PKR by inducing dimerization

Protein kinase R (PKR) is an interferon-induced kinase that plays a pivotal role in the innate immunity pathway. PKR is activated to undergo autophosphorylation upon binding to double-stranded RNAs or RNAs that contain duplex regions. Activated PKR phosphorylates the α subunit of eukaryotic initiation factor 2, thereby inhibiting protein synthesis. PKR is also activated by heparin, a highly sulfated glycosaminoglycan. We have used biophysical methods to define the mechanism of PKR activation by heparin. Heparins as short as hexasaccharide bind strongly to PKR and activate autophosphorylation. In contrast to double-stranded RNA, heparin activates PKR by binding to the kinase domain. Analytical ultracentrifugation measurements support a thermodynamic linkage model where heparin binding allosterically enhances PKR dimerization, thereby activating the kinase. These results indicate that PKR can be activated by small molecules and represents a viable target for the development of novel antiviral agents.     

Involvement of double-stranded RNA-dependent protein kinase and phosphorylation of eukaryotic initiation factor-2alpha in neuronal degeneration

Inhibition of protein translation plays an important role in apoptosis. While double-stranded RNA-dependent protein kinase (PKR) is named as it is activated by double-stranded RNA produced by virus, its activation induces an inhibition of protein translation and apoptosis via the phosphorylation of the eukaryotic initiation factor 2alpha (eIF2alpha). PKR is also a stress kinase and its levels increase during ageing. Here we show that PKR activation and eIF2alpha phosphorylation play a significant role in apoptosis of neuroblastoma cells and primary neuronal cultures induced by the beta-amyloid (Abeta) peptides, the calcium ionophore A23187 and flavonoids. The phosphorylation of eIF2alpha and the number of apoptotic cells were enhanced in over-expressed wild-type PKR neuroblastoma cells exposed to Abeta peptide, while dominant-negative PKR reduced eIF2alpha phosphorylation and apoptosis induced by Abeta peptide. Primary cultured neurons from PKR knockout mice were also less sensitive to Abeta peptide toxicity. Activation of PKR and eIF2alpha pathway by Abeta peptide are triggered by an increase in intracellular calcium because the intracellular calcium chelator BAPTA-AM significantly reduced PKR phosphorylation. Taken together, these results reveal that PKR and eIF2alpha phosphorylation could be involved in the molecular signalling events leading to neuronal apoptosis and death and could be a new target in neuroprotection.     

trans-Autophosphorylation by the isolated kinase domain is not sufficient for dimerization or activation of the dsRNA-activated protein kinase PKR

The double-stranded (ds) RNA-activated protein kinase PKR phosphorylates the alpha-subunit of the eukaryotic initiation factor 2 (eIF2alpha) and inhibits translation initiation. PKR contains two dsRNA binding domains in its amino terminus and a kinase domain in its carboxy terminus. dsRNA binding activates PKR from a latent state by inducing dimerization and trans-autophosphorylation. Recent studies show that PKR is also activated by caspase cleavage to remove the inhibitory dsRNA binding domains. In this report, we show that the isolated kinase domain of PKR is a constitutively active monomeric kinase that has an activity similar to that of wild-type PKR. We used a solid-phase kinase assay system to show that PKR does not transfer its own phosphate to either PKR or eIF2alpha but rather uses the gamma-phosphate from ATP. In addition, the isolated autophosphorylated kinase domain of PKR phosphorylated intact monomeric PKR in trans in a reaction that did not require dsRNA binding. However, this trans-phosphorylation did not occur at the critical Thr446/451 sites and was not sufficient to induce dimerization and/or activation of PKR. The results show that dsRNA binding domains of PKR are not only required for dimerization of PKR but also required for phosphorylation of Thr446/451 sites of PKR. The results imply that even though the isolated kinase domain of PKR phosphorylates intact PKR and eIF2alpha, it is unable to activate PKR.     

Mechanistic link between PKR dimerization, autophosphorylation, and eIF2alpha substrate recognition

The antiviral protein kinase PKR inhibits protein synthesis by phosphorylating the translation initiation factor eIF2alpha on Ser51. Binding of double-stranded RNA to the regulatory domains of PKR promotes dimerization, autophosphorylation, and the functional activation of the kinase. Herein, we identify mutations that activate PKR in the absence of its regulatory domains and map the mutations to a recently identified dimerization surface on the kinase catalytic domain. Mutations of other residues on this surface block PKR autophosphorylation and eIF2alpha phosphorylation, while mutating Thr446, an autophosphorylation site within the catalytic-domain activation segment, impairs eIF2alpha phosphorylation and viral pseudosubstrate binding. Mutational analysis of catalytic-domain residues preferentially conserved in the eIF2alpha kinase family identifies helix alphaG as critical for the specific recognition of eIF2alpha. We propose an ordered mechanism of PKR activation in which catalytic-domain dimerization triggers Thr446 autophosphorylation and specific eIF2alpha substrate recognition.     

Myxoma virus immunomodulatory protein M156R is a structural mimic of eukaryotic translation initiation factor eIF2alpha

Phosphorylation of the translation initiation factor eIF2 on Ser51 of its alpha subunit is a key event for regulation of protein synthesis in all eukaryotes. M156R, the product of the myxoma virus M156R open reading frame, has sequence similarity to eIF2alpha as well as to a family of viral proteins that bind to the interferon-induced protein kinase PKR and inhibit phosphorylation of eIF2alpha. In this study, we demonstrate that, like eIF2alpha. M156R is an efficient substrate for phosphorylation by PKR and can compete with eIF2alpha. To gain insights into the substrate specificity of the eIF2alpha kinases, we have determined the nuclear magnetic resonance (NMR) structure of M156R, the first structure of a myxoma virus protein. The fold consists of a five-stranded antiparallel beta-barrel with two of the strands connected by a loop and an alpha-helix. The similarity between M156R and the beta-barrel structure in the N terminus of eIF2alpha suggests that the viral homologs mimic eIF2alpha structure in order to compete for binding to PKR. A homology-modeled structure of the well-studied vaccinia virus K3L was generated on the basis of alignment with M156R. Comparison of the structures of the K3L model, M156R, and human eIF2alpha indicated that residues important for binding to PKR are located at conserved positions on the surface of the beta-barrel and in the mobile loop, identifying the putative PKR recognition motif.     

A Structural Model for the DEAD Box Helicase YxiN in Solution: Localization of the RNA Binding Domain

DEAD box proteins consist of a common helicase core formed by two globular RecA domains that are separated by a cleft. The helicase core acts as a nucleotide-dependent switch that alternates between open and closed conformations during the catalytic cycle of duplex separation, thereby providing basic helicase activity. Flanking domains can direct the helicase core to a specific RNA substrate by mediating high-affinity or high-specificity RNA binding. In addition, they may position RNA for the helicase core or may directly contribute to unwinding. While structures of different helicase cores have been determined previously, little is known about the orientation of flanking domains relative to the helicase core.YxiN is a DEAD box protein that consists of a helicase core and a C-terminal RNA binding domain (RBD) that mediates specific binding to hairpin 92 in 23S rRNA. To provide a framework for understanding the functional cooperation of the YxiN helicase core and the RBD, we mapped the orientation of the RBD in single-molecule fluorescence resonance energy transfer experiments. We present a model for the global conformation of YxiN in which the RBD lies above a slightly concave patch that is formed by flexible loops on the surface of the C-terminal RecA domain. The orientation of the RBD is different from the orientations of flanking domains in the Thermus thermophilus DEAD box protein Hera and in Saccharomyces cerevisiae Mss116p, in line with the different functions of these DEAD box proteins and of their RBDs. Interestingly, the corresponding patch on the C-terminal RecA domain that is covered by the YxiN RBD is also part of the interface between the translation factors eIF4A and eIF4G. Possibly, this region constitutes an adaptable interface that generally allows for the interaction of the helicase core with additional domains or interacting factors.     

Development of transgenic mice expressing a conditionally active form of the eIF2α kinase PKR

Phosphorylation of the alpha (α) subunit of the eukaryotic initiation factor 2 (eIF2) at serine 51 is an important mechanism of translational control in response to various forms of environmental stress. In metazoans, eIF2α phosphorylation is mediated by four kinases each of which becomes activated by distinct stimuli. Previous work established that expression of a chimera protein comprising of the bacteria Gyrase B N-terminal (GyrB) domain fused to the kinase domain (KD) of the eIF2α kinase PKR is capable of inducing eIF2α phosphorylation in cultured cells after treatment with the antibiotic coumermycin. Herein, we report the development of transgenic mice expressing the fusion protein GyrB.PKR ubiquitously. Treatment of mice with coumermycin induces eIF2α phosphorylation in vivo as demonstrated by immunoblotting and immunoshistochemistry of mouse tissues. The GyrB.PKR transgene represents a useful model system to investigate the biological effects of the conditional induction of eIF2α phosphorylation in vivo in the absence of parallel signaling pathways that are elicited in response to stress.     

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.     

Heterologous dimerization domains functionally substitute for the double-stranded RNA binding domains of the kinase PKR.

The protein kinase PKR (dsRNA-dependent protein kinase) phosphorylates the eukaryotic translation initiation factor eIF2alpha to downregulate protein synthesis in virus-infected cells. Two double-stranded RNA binding domains (dsRBDs) in the N-terminal half of PKR are thought to bind the activator double-stranded RNA, mediate dimerization of the protein and target PKR to the ribosome. To investigate further the importance of dimerization for PKR activity, fusion proteins were generated linking the PKR kinase domain to heterologous dimerization domains. Whereas the isolated PKR kinase domain (KD) was non-functional in vivo, expression of a glutathione S-transferase-KD fusion, or co-expression of KD fusions containing the heterodimerization domains of the Xlim-1 and Ldb1 proteins, restored PKR activity in yeast cells. Finally, coumermycin-mediated dimerization of a GyrB-KD fusion protein increased eIF2alpha phosphorylation and inhibited reporter gene translation in mammalian cells. These results demonstrate the critical importance of dimerization for PKR activity in vivo, and suggest that a primary function of double-stranded RNA binding to the dsRBDs of native PKR is to promote dimerization and activation of the kinase domain.     

Nck-1 interacts with PKR and modulates its activation by dsRNA

Activation of the double-stranded RNA (dsRNA)-activated protein kinase PKR results in inhibition of general translation through phosphorylation of the eukaryotic initiation factor 2 alpha-subunit on serine 51 (eIF2αSer51). Previously, we have reported that the adaptor protein Nck-1 modulates eIF2αSer51 phosphorylation by a subset of eIF2α kinases, including PKR. Herein, we demonstrate that Nck-1 prevents efficient activation of PKR by dsRNA, revealing that Nck-1 acts at the level of PKR. In agreement, Nck-1 impairs p38MAPK activation and attenuates cell death induced by dsRNA, in addition to diminish eIF2αSer51 phosphorylation. Our data show that the inhibitory effect of Nck-1 on PKR is reversible, as it could be overcome by increasing levels of dsRNA. Interestingly, we found that Nck-1 interacts with the inactive form of PKR, independently of its Src homology domains. Furthermore, we uncovered that Nck-1 is substrate of PKR in vitro. All together, our data provide the first evidence identifying Nck-1 as a novel endogenous regulator of PKR and support the notion that Nck-1-PKR interaction could be a way to limit PKR activation.