Patrick R. Romano

Autophosphorylation in the Activation Loop Is Required for Full Kinase Activity In Vivo of Human and Yeast Eukaryotic Initiation Factor 2α Kinases PKR and GCN2

ABSTRACT The human double-stranded RNA-dependent protein kinase (PKR) is an important component of the interferon response to virus infection. The activation of PKR is accompanied by autophosphorylation at multiple sites, including one in the N-terminal regulatory region (Thr-258) that is required for full kinase activity. Several protein kinases are activated by phosphorylation in the region between kinase subdomains VII and VIII, referred to as the activation loop. We show that Thr-446 and Thr-451 in the PKR activation loop are required in vivo and in vitro for high-level kinase activity. Mutation of either residue to Ala impaired translational control by PKR in yeast cells and COS1 cells and led to tumor formation in mice. These mutations also impaired autophosphorylation and eukaryotic initiation factor 2 subunit α (eIF2α) phosphorylation by PKR in vitro. Whereas the Ala-446 substitution substantially reduced PKR function, the mutant kinase containing Ala-451 was completely inactive. PKR specifically phosphorylated Thr-446 and Thr-451 in synthetic peptides in vitro, and mass spectrometry analysis of PKR phosphopeptides confirmed that Thr-446 is an autophosphorylation site in vivo. Substitution of Glu-490 in subdomain X of PKR partially restored kinase activity when combined with the Ala-451 mutation. This finding suggests that the interaction between subdomain X and the activation loop, described previously for MAP kinase, is a regulatory feature conserved in PKR. We found that the yeast eIF2α kinase GCN2 autophosphorylates at Thr-882 and Thr-887, located in the activation loop at exactly the same positions as Thr-446 and Thr-451 in PKR. Thr-887 was more critically required than was Thr-882 for GCN2 kinase activity, paralleling the relative importance of Thr-446 and Thr-451 in PKR. These results indicate striking similarities between GCN2 and PKR in the importance of autophosphorylation and the conserved Thr residues in the activation loop.

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

ABSTRACT The human double-stranded RNA (dsRNA)-dependent protein kinase PKR inhibits protein synthesis by phosphorylating translation initiation factor 2α (eIF2α). Vaccinia virus E3Lencodes 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.

Replication of a Cytopathic Strain of Bovine Viral Diarrhea Virus Activates PERK and Induces Endoplasmic Reticulum Stress-Mediated Apoptosis of MDBK Cells

ABSTRACT Endoplasmic reticulum (ER) stress signaling is an adaptive cellular response to the loss of ER Ca2+ homeostasis and/or the accumulation of misfolded, unassembled, or aggregated proteins in the ER lumen. ER stress-activated signaling pathways regulate protein synthesis initiation and can also trigger apoptosis through the ER-associated caspase 12. Viruses that utilize the host cell ER as an integral part of their life cycle would be predicted to cause some level of ER stress. Bovine viral diarrhea virus (BVDV) is a positive-stranded RNA virus of the Flaviviridae family. BVDV and related flaviviruses use the host ER as the primary site of envelope glycoprotein biogenesis, genomic replication, and particle assembly. We are using a cytopathic strain of BVDV (cpBVDV) that causes cellular apoptosis as a model system to determine how virus-induced ER stress contributes to pathogenesis. We show that, in a natural infection of MDBK cells, cpBVDV activates the ER transmembrane kinase PERK (PKR-like ER kinase) and causes hyperphosphorylation of the translation initiation factor eIF2α, consistent with the induction of an ER stress response. Additionally, we show that initiation of cellular apoptosis correlates with downregulation of the antiapoptotic Bcl-2 protein, induced expression of caspase 12, and a decrease in intracellular glutathione levels. Defining the molecular stress pathways leading to cpBVDV-induced apoptosis provides the basis to study how other ER-tropic viruses, such as hepatitis C and B viruses, modulate the host cell ER stress response during the course of persistent infection.

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 2α 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 bindingin 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 eIF2α kinase function of PKR.

Protein Synthesis and Endoplasmic Reticulum Stress Can Be Modulated by the Hepatitis C Virus Envelope Protein E2 through the Eukaryotic Initiation Factor 2α Kinase PERK

ABSTRACT The hepatitis C virus envelope protein, E2, is an endoplasmic reticulum (ER)-bound protein that contains a region of sequence homology with the double-stranded RNA-activated protein kinase PKR and its substrate, the eukaryotic translation initiation factor 2 (eIF2). We previously reported that E2 modulates global translation through inhibition of the interferon-induced antiviral protein PKR through its PKR-eIF2α phosphorylation site homology domain (PePHD). Here we show that the PKR-like ER-resident kinase (PERK) binds to and is also inhibited by E2. At low expression levels, E2 induced ER stress, but at high expression levels, and in vitro, E2 inhibited PERK kinase activity. Mammalian cells that stably express E2 were refractory to the translation-inhibitory effects of ER stress inducers, and E2 relieved general translation inhibition induced by PERK. The PePHD of E2 was required for the rescue of translation that was inhibited by activated PERK, similar to our previous findings with PKR. Here we report the inhibition of a second eIF2α kinase by E2, and these results are consistent with a pseudosubstrate mechanism of inhibition of eIF2α kinases. These findings may also explain how the virus promotes persistent infection by overcoming the cellular ER stress response.

Structural requirements for double-stranded RNA binding, dimerization, and activation of the human eIF-2 alpha kinase DAI in Saccharomyces cerevisiae.

The protein kinase DAI is activated upon viral infection of mammalian cells and inhibits protein synthesis by phosphorylation of the alpha subunit of translation initiation factor 2 (eIF-2 alpha). DAI is activated in vitro by double-stranded RNAs (dsRNAs), and binding of dsRNA is dependent on two copies of a conserved sequence motif located N terminal to the kinase domain in DAI. High-level expression of DAI in Saccharomyces cerevisiae cells is lethal because of hyperphosphorylation of eIF-2 alpha; at lower levels, DAI can functionally replace the protein kinase GCN2 and stimulate translation of GCN4 mRNA. These two phenotypes were used to characterize structural requirements for DAI function in vivo, by examining the effects of amino acid substitutions at matching positions in the two dsRNA-binding motifs and of replacing one copy of the motif with the other. We found that both copies of the dsRNA-binding motif are required for high-level kinase function and that the N-terminal copy is more important than the C-terminal copy for activation of DAI in S. cerevisiae. On the basis of these findings, we conclude that the requirements for dsRNA binding in vitro and for activation of DAI kinase function in vivo closely coincide. Two mutant alleles containing deletions of the first or second binding motif functionally complemented when coexpressed in yeast cells, strongly suggesting that the active form of DAI is a dimer. In accord with this conclusion, overexpression of four catalytically inactive alleles containing different deletions in the protein kinase domain interfered with wild-type DAI produced in the same cells. Interestingly, three inactivating point mutations in the kinase domain were all recessive, suggesting that dominant interference involves the formation of defective heterodimers rather than sequestration of dsRNA activators by mutant enzymes. We suggest that large structural alterations in the kinase domain impair an interaction between the two protomers in a DAI dimer that is necessary for activation by dsRNA or for catalysis of eIF-2 alpha phosphorylation.

Hepatitis C Virus Envelope Protein E2 Does Not Inhibit PKR by Simple Competition with Autophosphorylation Sites in the RNA-Binding Domain

ABSTRACT Double-stranded-RNA (dsRNA)-dependent protein kinase PKR is induced by interferon and activated upon autophosphorylation. We previously identified four autophosphorylated amino acids and elucidated their participation in PKR activation. Three of these sites are in the central region of the protein, and one is in the kinase domain. Here we describe the identification of four additional autophosphorylated amino acids in the spacer region that separates the two dsRNA-binding motifs in the RNA-binding domain. Eight amino acids, including these autophosphorylation sites, are duplicated in hepatitis C virus (HCV) envelope protein E2. This region of E2 is required for its inhibition of PKR although the mechanism of inhibition is not known. Replacement of all four of these residues in PKR with alanines did not dramatically affect kinase activity in vitro or in yeast Saccharomyces cerevisiae. However, when coupled with mutations of serine 242 and threonines 255 and 258 in the central region, these mutations increased PKR protein expression in mammalian cells, consistent with diminished kinase activity. A synthetic peptide corresponding to this region of PKR was phosphorylated in vitro by PKR, but phosphorylation was strongly inhibited after PKR was preincubated with HCV E2. Another synthetic peptide, corresponding to the central region of PKR and containing serine 242, was also phosphorylated by active PKR, but E2 did not inhibit this peptide as efficiently. Neither of the PKR peptides was able to disrupt the HCV E2-PKR interaction. Taken together, these results show that PKR is autophosphorylated on serine 83 and threonines 88, 89, and 90, that this autophosphorylation may enhance kinase activation, and that the inhibition of PKR by HCV E2 is not solely due to duplication of and competition with these autophosphorylation sites.