Mechanism of interferon action: autoregulation of RNA-dependent P1/eIF-2 alpha protein kinase (PKR) expression in transfected mammalian cells

RNA binding and modulation of PKR activity

PKR is an RNA-dependent protein kinase that is induced in mammalian cells by interferon treatment. It is present in a latent or inactive form in mammalian cells and is activated by very low concentrations of double-stranded (ds) RNA. Activated PKR phosphorylates eIF2, an essential initiation factor of protein synthesis, as well as other substrates including histone IIA, a 90-kDa protein from rabbit reticulocytes, the inhibitor, IkappaB, of the transcription factor, NF-kappaB, and the HIV-1 Tat protein. PKR interacts with several cellular and viral products and these interactions modulate its activation by dsRNA. Here we describe methods that are used to study the activation or inhibition of PKR by RNA modulators. Specifically, we detail (1) the purification of PKR from interferon-treated mammalian cells, (2) functional assays for PKR activation and inhibition in vitro, using purified enzyme or crude cell lysates, and (3) assays allowing evaluation of the binding of dsRNA and single-stranded RNA to PKR.

Mutations in the double-stranded RNA-activated protein kinase insert region that uncouple catalysis from eIF2alpha binding

The interferon-induced, double-stranded RNA (dsRNA)-activated protein kinase, PKR, inhibits protein synthesis via phosphorylation of the alpha subunit of the translation initiation factor eIF2. A kinase insert region N-terminal of PKR kinase subdomain V, which is conserved among eIF2alpha kinases, has been proposed to determine substrate specificity of these kinases. To investigate the function of this kinase insert region, selective PKR mutants were generated, and kinase activities and eIF2alpha affinities were analyzed in vitro. The in vivo function was investigated by growth inhibitory assays in yeast and translational assays in COS cells. Among the 13 mutations, 5 lost kinase activity and 3 exhibited less than 30% of wild-type eIF2alpha binding activity. The deletion of the conserved sequence (amino acids 362-370) resulted in a protein that had no kinase activity and only about 25% of wild-type eIF2alpha binding, suggesting that this sequence is not only required for PKR kinase activity but also is important for substrate interaction. It was determined that the hydrophobicity of the conserved sequence of PKR is required for kinase activity but is not crucial for eIF2alpha binding. The amino acid residue Glu-367 in the conserved motif was shown to be directly involved in substrate binding but was not important for kinase activity. These results suggest that the activation of PKR is not a prerequisite for its binding to the substrate and that the conserved motif in subdomain V contributes to the interaction of PKR and eIF2alpha.

Double-stranded RNA-independent dimerization of interferon-induced protein kinase PKR and inhibition of dimerization by the cellular P58IPK inhibitor

The interferon (IFN)-induced, double-stranded RNA-activated protein kinase (PKR) mediates the antiviral and antiproliferative actions of IFN, in part, via its translational inhibitory properties. Previous studies have demonstrated that PKR forms dimers and that dimerization is likely to be required for activation and/or function. In the present study we used multiple approaches to examine the modulation of PKR dimerization. Deletion analysis with the lambda repressor fusion system identified a previously unrecognized site involved in PKR dimerization. This site comprised amino acids (aa) 244 to 296, which span part of the third basic region of PKR and the catalytic subdomains I and II. Using the yeast two-hybrid system and far-Western analysis, we verified the importance of this region for dimerization. Furthermore, coexpression of the 52-aa region alone inhibited the formation of full-length PKR dimers in the lambda repressor fusion and two-hybrid systems. Importantly, coexpression of aa 244 to 296 exerted a dominant-negative effect on wild-type kinase activity in a functional assay. Due to its role as a mediator of IFN-induced antiviral resistance, PKR is a target of viral and cellular inhibitors. Curiously, PKR aa 244 to 296 contain the binding site for a select group of specific inhibitors, including the cellular protein P58IPK. We demonstrated, utilizing both the yeast and lambda systems, that P58IPK, a member of the tetratricopeptide repeat protein family, can block kinase activity by preventing PKR dimerization. In contrast, a nonfunctional form of P58IPK lacking a TPR motif did not inhibit kinase activity or perturb PKR dimers. These results highlight a potential mechanism of PKR inhibition and define a novel class of PKR inhibitors. Finally, the data document the first known example of inhibition of protein kinase dimerization by a cellular protein inhibitor. On the basis of these results we propose a model for the regulation of PKR dimerization.

Autophosphorylation in the activation loop is required for full kinase activity in vivo of human and yeast eukaryotic initiation factor 2alpha kinases PKR and GCN2

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 alpha (eIF2alpha) 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 eIF2alpha 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.

Interaction of the human protein kinase PKR with the mouse PKR homolog occurs via the N-terminal region of PKR and does not inactivate autophosphorylation activity of mouse PKR

The RNA-dependent protein kinase (PKR) is implicated in the antiviral and antiproliferative actions of interferon. Mutant forms of human PKR display a transdominant behavior when expressed in transfected cells. The potential for the human PKR protein to physically interact with the mouse PKR homolog has therefore been examined. The yeast two-hybrid system was used to probe the association between mouse and human PKR proteins as measured by activation of two Gal4-responsive reporter genes, HIS3 and IacZ. Expression of full-length wild-type mouse PKR(1-515)WT as a Gal4 fusion protein did not exhibit the growth suppression phenotype in yeast characteristic of wild-type human PKR(1-551)WT. Coexpression of mouse PKR(1-515)WT as a Gal4 DNA-binding domain fusion with either the catalytic-deficient human PKR(1-551) K296R mutant, the RNA-binding-deficient human PKR(1-551)K64E/K296R double mutant, or wild-type mouse PKR(1-515)WT as full-length PKR-Gal4 activation domain fusions resulted in activation of the HIS3 and lacZ reporters. The N-terminal RNA-binding region of human PKR, both WT and the K64E RNA-binding-deficient mutant, also interacted with mouse PKR(1-515)WT sufficiently to activate the reporters but the human catalytic region did not. Mouse and human full-length PKR proteins expressed as glutathione S-transferase (GST) fusions in Escherichia coli were purified on Sepharose beads. Using GST-PKR fusion chromatography, direct physical interaction between the mouse and human PKR homologs was established. Intraspecies PKR interactions were more efficient than interspecies PKR interactions, and interactions between RNA-binding-sufficient PKR proteins were more efficient than those involving an RNA-binding mutant as measured by binding to GST-PKR protein Sepharose beads. The N-terminal region of human PKR within amino acids 1-184 was sufficient for binding mouse PKR. Purified mouse full-length PKR(1-515)WT GST fusion protein retained kinase activity on Sepharose beads, but the activity was not impaired by association with either the full-length or the N-terminal region of human PKR.

Regulation of translational initiation during cellular responses to stress

Chemicals and conditions that damage proteins, promote protein misfolding, or inhibit protein processing trigger the onset of protective homeostatic mechanisms resulting in "stress responses" in mammalian cells. Included in these responses are an acute inhibition of mRNA translation at the initiation step, a subsequent induction of various protein chaperones, and the recovery of mRNA translation. Separate, but closely related, stress response systems exist for the endoplasmic reticulum (ER), relating to the induction of specific "glucose-regulated proteins" (GRPs), and for the cytoplasm, pertaining to the induction of the "heat shock proteins" (HSPs). Activators of the ER stress response system, including Ca(2+)-mobilizing and thiol-reducing agents, are discussed and compared to activators of the cytoplasmic stress system, such as arsenite, heavy metal cations, and oxidants. An emerging integrative literature is reviewed that relates protein chaperones associated with cellular stress response systems to the coordinate regulation of translational initiation and protein processing. Background information is presented describing the roles of protein chaperones in the ER and cytoplasmic stress response systems and the relationships of chaperones and protein processing to the regulation of mRNA translation. The role of chaperones in regulating eIF-2 alpha kinase activities, eIF-2 cycling, and ribosomal loading on mRNA is emphasized. The putative role of GRP78 in coupling rates of translation to processing is modeled, and functional relationships between the HSP and GRP chaperone systems are discussed.

The double-stranded RNA-dependent protein kinase PKR: structure and function

This review describes the structure and function of the interferon (IFN)-inducible, double-stranded RNA-activated protein kinase PKR. This protein kinase has been studied extensively in recent years, and a large body of evidence has accumulated concerning its expression, interaction with regulatory RNA and protein molecules, and modes of activation and inhibition. PKR has been shown to play a variety of important roles in the regulation of translation, transcription, and signal transduction pathways through its ability to phosphorylate protein synthesis initiation factor eIF2, I-kappaB (the inhibitor of NF-kappaB), and other substrates. Expression studies involving both the wild-type protein and dominant negative mutants of PKR have established roles for the enzyme in the antiviral effects of IFNs, in the responses of uninfected cells to physiologic stresses, and in cell growth regulation. The possibility that PKR may function as a tumor suppressor and inducer of apoptosis suggests that this IFN-regulated protein kinase may be of central importance to the control of cell proliferation and transformation.

Ribosome targeting of PKR is mediated by two double-stranded RNA-binding domains and facilitates in vivo phosphorylation of eukaryotic initiation factor-2

Protein kinase PKR is activated in mammalian cells during viral infection, leading to phosphorylation of the alpha subunit of eukaryotic initiation factor-2 (eIF-2alpha) and inhibition of protein synthesis. This antiviral response is thought to be mediated by association of double-stranded RNA (ds-RNA), a by-product of viral replication, with two ds-RNA-binding domains (DRBDs) located in the amino terminus of PKR. Recent studies have observed that expression of mammalian PKR in yeast leads to a slow growth phenotype due to hyperphosphorylation of eIF-2alpha. In this report, we observed that while DRBD sequences are required for PKR to function in the yeast model system, these sequences are not required for in vitro phosphorylation of eIF-2alpha. To explain this apparent contradiction, we proposed that these sequences are required to target the kinase to the translation machinery. Using sucrose gradient sedimentation, we found that wild-type PKR was associated with ribosomes, specifically with 40 S particles. Deletions or residue substitutions in the DRBD sequences blocked kinase interaction with ribosomes. These results indicate that in addition to mediating ds-RNA control of PKR, the DRBD sequences facilitate PKR association with ribosomes. Targeting to ribosomes may enhance in vivo phosphorylation of eIF-2alpha, by providing PKR access to its substrate.

Oncogenic potential of TAR RNA binding protein TRBP and its regulatory interaction with RNA-dependent protein kinase PKR

TAR RNA binding protein (TRBP) belongs to an RNA binding protein family that includes the double-stranded RNA-activated protein kinase (PKR), Drosophila Staufen and Xenopus xlrbpa. One member of this family, PKR, is a serine/threonine kinase which has anti-viral and anti-proliferative effects. In this study we show that TRBP is a cellular down-regulator of PKR function. Assaying expression from an infectious HIV-1 molecular clone, we found that PKR inhibited viral protein synthesis and that over-expression of TRBP effectively countered this inhibition. In intracellular and in cell-free assays we show that TRBP directly inhibits PKR autophosphorylation through an RNA binding-independent pathway. Biologically, TRBP serves a growth-promoting role; cells that overexpress TRBP exhibit transformed phenotypes. Our results demonstrate the oncogenic potential of TRBP and are consistent with the notion that intracellular PKR function contributes physiologically towards regulating cellular proliferation.

The kinase insert domain of interferon-induced protein kinase PKR is required for activity but not for interaction with the pseudosubstrate K3L

Interferon-induced protein kinase (PKR) is a member of a family of kinases that regulate translation initiation through phosphorylation of eukaryotic initiation factor 2alpha. In addition to the conserved catalytic subdomains that are present in all serine/threonine kinases, the eukaryotic initiation factor 2alpha kinases possess an insert region between catalytic subdomains IV and V that has been termed the kinase insert domain. To investigate the importance of the kinase insert domain of PKR, several deletions and point mutations were introduced within this domain and analyzed for kinase activity both in vitro and in vivo. Here we show that deletion of the kinase insert sequence or mutation of serine 355, which lies within this region, abrogates kinase activity. In addition, the kinase insert domain of PKR and adjacent amino acids (LFIQME) in catalytic subdomain V are not required for binding of the pseudosubstrate inhibitor K3L from vaccinia virus. A portion of the catalytic domain of PKR between amino acids 366 and 415 confers K3L binding in vivo, suggesting a possible role for this region of PKR in substrate interaction.

The P58 cellular inhibitor complexes with the interferon-induced, double-stranded RNA-dependent protein kinase, PKR, to regulate its autophosphorylation and activity

The 58-kDa protein, referred to as P58, is a cellular inhibitor of the interferon-induced, double-stranded RNA-activated protein kinase, PKR. The P58 protein inhibits both the autophosphorylation of PKR and the phosphorylation of the PKR natural substrate, the alpha subunit of eukaryotic initiation factor eIF-2. Sequence analysis revealed that P58 is a member of the tetratricopeptide family of proteins. Utilizing experimental approaches, which included coprecipitation or coselection of native and recombinant wild-type and mutant proteins, we found that P58 can efficiently complex with the PKR protein kinase. Attempts to map the P58 interactive sites revealed a correlation between the ability of P58 to inhibit PKR in vitro and bind to PKR. The DnaJ sequences, present at the carboxyl terminus of P58, were dispensable for binding in vitro, while sequences containing the eIF-2 alpha similarity region were essential for efficient complex formation. Furthermore, not all tetratricopeptide motifs were necessary for PKR-P58 interactions. Initial experiments to map the binding domains present in PKR showed that P58 complexed with PKR molecules that lacked the first RNA binding domain but did not bind to a PKR mutant containing only the amino terminus. These data, taken together, demonstrate that P58 inhibits PKR through a direct interaction, which is likely independent of the binding of double-stranded RNA to the protein kinase.

Double-stranded (ds) RNA binding and not dimerization correlates with the activation of the dsRNA-dependent protein kinase (PKR)

Upon binding to double-stranded (ds) RNA, the dsRNA-dependent protein kinase (PKR) sequentially undergoes autophosphorylation and activation. Activated PKR may exist as a dimer and phosphorylates the eukaryotic translation initiation factor 2 alpha subunit (cIF-2 alpha) to inhibit polypeptide chain initiation. Transfection of COS-1 cells with a plasmid cDNA expression vector encoding a marker gene, activates endogenous PKR, and selectively inhibits translation of the marker mRNA, dihydrofolate reductase (DHFR). This system was used to study the dsRNA binding and dimerization requirements for over-expressed PKR mutants and subdomains to affect DHFR translation. DHFR translation was rescued by expression of either an ATP hydrolysis defective mutant PKR K296P, the amino-terminal 1-243 fragment containing two dsRNA binding motifs, or the isolated first RNA binding motif (amino acids 1-123). Mutation of K64E within the dsRNA binding motif 1 destroyed dsRNA binding and the ability to rescue DHFR translation. Immunoprecipitation of T7 epitope-tagged PKR derivatives from cell lysates detected interaction between intact PKR and the amino-terminal 1-243 fragment as well as a 1-243 fragment harboring the K64E mutation. Expression of adenovirus VAI RNA, a potent inhibitor of PKR activity, did not disrupt this interaction. In contrast, intact PKR did not interact with fragments containing the first dsRNA binding motif (1-123), the second dsRNA binding motif (98-243), or the isolated PKR kinase catalytic domain (228-551). These results demonstrate that the translational stimulation mediated by the dominant negative PKR mutant does not require dimerization, but requires the ability to bind dsRNA and indicate these mutants act by competition for binding to activators.

Interferon modulates the messenger RNA of G1-controlling genes to suppress the G1-to-S transition in Daudi cells

Interferon (IFN) is one of the potent antiproliferative cytokines and is used to treat some selected cancers. IFN arrests the growth of Burkitt Lymphoma derived cell line Daudi cells in the G1 phase. G1-to-S progression is controlled by positive and negative regulatory genes. Therefore, we investigated the effects of IFN on G1-controlling genes. Expression of cyclin-dependent kinases (Cdks 2, 3, 4, 5, 6), MO15/Cdk7, and cyclins E and H was studied to assess positive regulators, while p15Ink4B, p16Ink4, p18, p21Cip1, and p27Kip1 were assessed as negative regulators. Cdks 2, 4, 6 and cyclin E were markedly down-regulated. MO15/Cdk7 expression showed little change, but its regulatory subunit (cyclin H) was down-regulated like cyclin E. Expression of p15Ink4B and p16Ink4 was not observed. p18 was induced until 48 h and its expression returned to the initial level at 72 h. In contrast, p21Cip1 mRNA expression remained at the baseline level throughout IFN treatment, while the expression of p27Kip1 increased at 48 and 72 h. Taken together, these data indicate that IFN changes the messenger RNA of G1-controlling genes towards the suppression of G1-to-S transition.

Mechanism of interferon action: characterization of the intermolecular autophosphorylation of PKR, the interferon-inducible, RNA-dependent protein kinase

The interferon-inducible, RNA-dependent protein kinase (PKR) is activated by autophosphorylation, a process mediated by double-stranded RNA. A catalytically deficient, histidine-tagged mutant PKR protein [His-PKR(K296R)] was used as the substrate for characterization of the intermolecular phosphorylation catalyzed by purified wild-type PKR [PKR(Wt)]. The intermolecular autophosphorylation of His-PKR(K296R) by PKR(Wt) was RNA dependent. Excess His-PKR(K296R) substrate inhibited both the auto- and the trans-phosphorylation activities of PKR(Wt). Inhibition of PKR(Wt) by His-PKR(K296R) was relieved by higher concentrations of activator double-stranded RNA. Phosphopeptide analysis revealed that the sites of intermolecular autophosphorylation in His-PKR(K296R) were very similar, if not identical, to the sites that were autophosphorylated in PKR(Wt) and suggest a multiple of four major phosphorylation sites per PKR molecule.

Mutants of the RNA-dependent protein kinase (PKR) lacking double-stranded RNA binding domain I can act as transdominant inhibitors and induce malignant transformation

Recently we reported that introduction of catalytically inactive PKR molecules into NIH 3T3 cells causes malignant transformation and the development of tumors in nude mice. We have proposed that PKR may be a tumor suppressor gene possibly because of its translational inhibitory properties. We have now designed and characterized a number of PKR mutants encoding proteins that retain their catalytic competence but are mutated in their regulatory double-stranded RNA (dsRNA) binding domains (RBDs). RNA binding analysis revealed that PKR proteins either lacking or with point mutations in the first RBD (RBD-1) bound negligible amounts of dsRNA activator or adenovirus VAI RNA inhibitor. Despite the lack of binding, such variants remained functionally competent but were much less active than wild-type PKR. PKR variants completely lacking RBD-1 were largely unresponsive to dsRNA in activation assays but could be activated by heparin. To complement these studies, we evaluated the effects of point mutations in RBD-1 or the removal of either RBD-1 or RBD-2 on the proliferation rate of mouse 3T3 cells. We were unsuccessful at isolating stably transformed cells expressing RBD-1 point mutants or RBD-2-minus mutants. In contrast, NIH 3T3 cells, which constitutively expressed PKR proteins that lacked RBD-1, were selected. These cells displayed a transformed phenotype and caused tumors after inoculation in nude mice. Further, levels of endogenous eIF-2 alpha phosphorylation in RBD-1-minus cell lines were reduced, suggesting that such mutants act in a dominant negative manner to inhibit the function of endogenous PKR. These results emphasize the importance of RBD-1 in PKR control of cell growth and provide additional evidence for the critical role played by PKR in the regulation of malignant transformation.

Mutational analysis of the double-stranded RNA (dsRNA) binding domain of the dsRNA-activated protein kinase, PKR

The interferon-induced, double-stranded RNA (dsRNA)-dependent protein kinase, PKR, is an inhibitor of translation and has antiviral, antiproliferative, and antitumor properties. Previously, the dsRNA binding domain had been located within the N-terminal region of PKR and subsequently shown to include two nearly identical domains comprising residues 55-75 and 145-166. We have undertaken both random and site-directed, alanine-scanning mutagenesis in order to investigate the contribution of individual amino acids within these domains to dsRNA binding. Here we identify 2 residues that were absolutely required for dsRNA binding, glycine 57 and lysine 60. Mutation of 2 other residues within the domain (lysine 64 and leucine 75) resulted in less than 10% binding (compared to wild type). We have also identified a number of other residues that influence dsRNA binding to varying degrees. Mutants that were unable to bind dsRNA were not active in vitro and possessed no antiproliferative activity in vivo. However, dsRNA binding mutants were partially transdominant over wild type PKR in mammalian cells, suggesting that binding of dsRNA activator is not the mechanism responsible for the phenotype of PKR mutants.

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.

Activation of the double-stranded RNA (dsRNA)-activated human protein kinase in vivo in the absence of its dsRNA binding domain

The interferon-induced, dsRNA-activated human protein kinase (PKR) exerts antiviral and antiproliferative effects through inhibition of protein synthesis. Studies of structure-function relationships in PKR have shown that two dsRNA binding motifs are important for its autophosphorylation and activation by dsRNA in vitro. To correlate these findings with the activity of PKR in vivo, we examined the function of various PKR deletion mutants in cultured cells by using an inducible expression system. In a reporter gene assay, mutant forms of the kinase lacking amino acids 1-97 (delta 1-97) and 104-157 (delta 104-157), which are required for dsRNA binding in vitro, retained full activity in vivo. Deletion of amino acids 233-271 (delta 233-271), however, abolished the translational inhibitory activity of the kinase and prevented its phosphorylation. Moreover, cells infected with vaccinia virus recombinants expressing wild-type PKR, the mutant delta 104-157, delta 186-222), developed almost complete inhibition of both viral and cellular protein synthesis was upon induction of PKR. This inhibition of viral protein synthesis was not observed in cells infected with a recombinant expressing delta 233-271 mutant PKR. Our findings establish that the region encompassing amino acids 233-271 of PKR is critical for kinase activity in vivo, whereas its dsRNA binding domain is dispensable.

Mechanism of interferon action: structure of the mouse PKR gene encoding the interferon-inducible RNA-dependent protein kinase

The gene for the RNA-dependent eIF-2 alpha protein kinase (PKR) was isolated from mouse genomic DNA and characterized. The mouse PKR gene contains 16 exons and spans about 28 kilobase pairs. Exon 1 is untranslated; the AUG translation initiation site is located early in the second exon. Exon 16 includes the UAG translation termination site. ATTAAA polyadenylylation signal, and a putative TA rather than CA 3' cleavage site. Primer extension analysis determined one major as well as multiple minor transcription initiation sites; the major site was 159 bp upstream of the translation initiation site. The complete cDNA of mouse PKR is, therefore, 2334 bp in length excluding the 3' poly(A)+ tail. The PKR gene 5' flanking region was a functional promoter in interferon-treated, transfected cells as measured with chloramphenicol acetyltransferase as the reporter gene. Sequence analysis of the 5' flanking region disclosed numerous potential binding sites for transcription factors including both an ISRE element and a GAS element involved in interferon inducibility; Ets, Myb, MyoD, and E2F sites commonly associated with growth control regulation and differentiation; and NF-kappa B-like sites as well as sites for two types of interleukin 6-activated factors, NF-IL6 and APRF, often associated with acute-phase, immune, and inflammatory response genes.

Changes of cell cycle-regulating genes in interferon-treated Daudi cells

Interferon (IFN) modulates the expression of several genes and some of them are considered to be responsible for the inhibition of cellular growth. However, the alterations of cell cycle-regulating genes produced by IFN still remain unclear. Accordingly, we studied the expression of cell cycle-regulating genes during IFN-induced growth arrest. Cell cycle synchronized and unsynchronized Daudi Burkitt lymphoma cells were treated with IFN. Both the cell cycle distribution and the expression of cell cycle-regulating genes (cdk2, cdc2, cyclins A, B, C, D3, cdc25, and wee 1) were studied by flow cytometry and by Northern blot hybridization or the reverse-transcription polymerase chain reaction, respectively. Treated cells passed through the first G1 phase and gradually accumulated in the following G1 phase. Expression of cyclins A, B, and D3 oscillated along with the cell cycle progression in control cells, and the alterations of cyclin B expression were especially prominent. Both cdc2 and cdk2 also showed changes, but these were not so distinct as observed with cyclin B. Expression of cdc25 and wee1 was little affected by cell cycle progression. In IFN-treated cells, expression of cyclins A and B were down-regulated, while that of cyclin C was not. Cyclin D3 expression was also down-regulated at 48 h, followed by an increase at 72 h. Expression of both cdc2 and cdk2 was down-regulated, especially that of the later. Wee1 expression was down-regulated by IFN but, the expression of cdc25 remained stable. These findings suggest that the modulation of cell cycle-regulating genes, particular by cyclin A and cdk2, plays an important role in IFN-induced cellular growth arrest.

The 58-kilodalton inhibitor of the interferon-induced double-stranded RNA-activated protein kinase is a tetratricopeptide repeat protein with oncogenic properties

The interferon-induced RNA-dependent protein kinase (PKR) is considered to play an important role in the cellular defense against viral infection and, in addition, has been suggested to be a tumor suppressor gene because of its growth-suppressive properties. Activation of PKR by double-stranded RNAs leads to the phosphorylation of the alpha subunit of eukaryotic initiation factor 2 (eIF-2 alpha) and a resultant block to protein synthesis initiation. To avoid the consequences of kinase activation, many viruses have developed strategies to down-regulate PKR. Recently, we reported on the purification and characterization of a cellular inhibitor of PKR (referred to as p58), which is activated during influenza virus infection. Subsequent cloning and sequencing has revealed that p58 is a member of the tetratricopeptide repeat (TPR) family of proteins. To further examine the physiological role of this PKR inhibitor, we stably transfected NIH 3T3 cells with a eukaryotic expression plasmid containing p58 cDNA under control of the cytomegalovirus early promoter. By taking advantage of a recently characterized p58 species-specific monoclonal antibody, we isolated cell lines that overexpressed p58. These cells exhibited a transformed phenotype, growing at faster rates and higher saturation densities and exhibiting anchorage-independent growth. Most importantly, inoculation of nude mice with p58-overexpressing cells gave rise to the production of tumors. Finally, murine PKR activity and endogenous levels of eIF-2 alpha phosphorylation were reduced in the p58-expressing cell lines compared with control cells. These data, taken together, suggest that p58 functions as an oncogene and that one mechanism by which the protein induces malignant transformation is through the down-regulation of PKR and subsequent deregulation of protein synthesis.

Mechanism of interferon action: evidence for intermolecular autophosphorylation and autoactivation of the interferon-induced, RNA-dependent protein kinase PKR

The interferon-induced RNA-dependent protein kinase (PKR) is postulated to have an important regulatory role in the synthesis of viral and cellular proteins. Activation of the enzyme requires the presence of a suitable activator RNA and is accompanied by an autophosphorylation of PKR. Active PKR phosphorylates the alpha subunit of protein synthesis eukaryotic initiation factor 2, resulting in an inhibition of translation initiation. The mechanism of autophosphorylation is not well understood. Here we present evidence that the autophosphorylation of human PKR can involve intermolecular phosphorylation events, i.e., one PKR protein molecule phosphorylating a second PKR molecule. Both wild-type PKR and the point mutant PKR(K296R) synthesized in vitro were phosphorylated, even though PKR(K296R) was deficient in kinase catalytic activity. Phosphorylation of both wild-type PKR and PKR(K296R) was inhibited in the presence of 2-aminopurine. Furthermore, purified human recombinant PKR(K296R) was a substrate for the purified wild-type human PKR kinase. This intermolecular phosphorylation of mutant PKR(K296R) by wild-type PKR was dependent on double-stranded RNA and was inhibited by 2-aminopurine. Finally, PKR mRNA was capable of mediating an autoactivation of wild-type PKR kinase autophosphorylation in vitro.

Translational regulation by the interferon-induced double-stranded-RNA-activated 68-kDa protein kinase

Activation of the interferon-inducible 68-kDa protein kinase (referred to as P68) by double-stranded RNA catalyzes phosphorylation of the alpha subunit of eukaryotic protein synthesis initiation factor 2. We have analyzed the transient expression of mutant and wild-type kinase molecules in transfected COS cells to examine the effects of the kinase on gene expression in the absence of other interferon-induced gene products. The wild-type P68 kinase was expressed inefficiently whereas a catalytically inactive P68 was expressed at 30- to 40-fold higher levels. Protein stability measurements and primer-extension analysis of human kinase-specific mRNA levels provided evidence that kinase expression was regulated at the level of mRNA translation. Further, cotransfection experiments revealed that the domain II catalytically inactive mutant could stimulate reporter gene protein synthesis in a transdominant manner. We also examined the expression of mutants with deletions in the N-terminal double-stranded RNA binding domains and found that a kinase construct lacking aa 156-243 was expressed at levels comparable to the wild type whereas a P68 construct lacking aa 91-243 was expressed at levels 70-fold higher. Both the inactive domain II P68 mutant and the deletion mutant lacking aa 91-243 were less inhibitory to growth in yeast due to the reduced ability to phosphorylate initiation factor 2 alpha in vivo. In conclusion we have demonstrated that the P68 kinase can regulate mRNA translation primarily of its own mRNA and to a lesser extent of a heterologous mRNA and that this regulation is notably affected by mutations in either the catalytic or N-terminal regulatory domains.