Expression of TAR RNA-binding protein in baculovirus and co-immunoprecipitation with insect cell protein kinase

TAR RNA-binding protein TRBP was originally isolated by its binding affinity for radiolabeled HIV-1 leader RNA. Subsequent studies have suggested that this protein is one member of a family of double-stranded RNA-binding proteins. Recent findings indicate that TRBP might function to antagonize the translational inhibitory effect that can be mediated through cellular protein kinase, PKR. Here, we report on the over-expression of a cDNA coding for TRBP in eukaryotic SF9 cells using baculovirus. We characterized the nuclear localization of TRBP in insect cells, and we demonstrate that TRBP co-immunoprecipitates with a protein in these cells antigenically related to human PKR.     

Analysis of the role of autophagy inhibition by two complementary human cytomegalovirus BECN1/Beclin 1-binding proteins

Autophagy is activated early after human cytomegalovirus (HCMV) infection but, later on, the virus blocks autophagy. Here we characterized 2 HCMV proteins, TRS1 and IRS1, which inhibit autophagy during infection. Expression of either TRS1 or IRS1 was able to block autophagy in different cell lines, independently of the EIF2S1 kinase, EIF2AK2/PKR. Instead, TRS1 and IRS1 interacted with the autophagy protein BECN1/Beclin 1. We mapped the BECN1-binding domain (BBD) of IRS1 and TRS1 and found it to be essential for autophagy inhibition. Mutant viruses that express only IRS1 or TRS1 partially controlled autophagy, whereas a double mutant virus expressing neither protein stimulated autophagy. A mutant virus that did not express IRS1 and expressed a truncated form of TRS1 in which the BBD was deleted, failed to control autophagy. However, this mutant virus had similar replication kinetics as wild-type virus, suggesting that autophagy inhibition is not critical for viral replication. In fact, using pharmacological modulators of autophagy and inhibition of autophagy by shRNA knockdown, we discovered that stimulating autophagy enhanced viral replication. Conversely, inhibiting autophagy decreased HCMV infection. Thus, our results demonstrate a new proviral role of autophagy for a DNA virus.     

New Cdc2 Tyr 4 phosphorylation by dsRNA‐activated protein kinase triggers Cdc2 polyubiquitination and G2 arrest under genotoxic stresses

Cell division cycle 2 (Cdc2) protein is an essential subunit of M‐phase kinase (MPK), which has a key role in G2/M transition. Even though the control of MPK activity has been well established with regard to the phosphorylation of Cdc2 at Thr 14 and/or Tyr 15 and Thr 161, little is known about the proteolytic control of Cdc2. In this study, we observed that Cdc2 was downregulated under genotoxic stresses and that double‐stranded RNA‐activated protein kinase (PKR) was involved in the process. The PKR‐mediated Tyr4 phosphorylation triggered Cdc2 ubiquitination. Phospho‐mimic mutations at the Tyr 4 residue (Y4D or Y4E) caused significant ubiquitination of Cdc2 even in the absence of PKR. Our findings demonstrate that (i) PKR, Ser/Thr kinase, phosphorylates its new substrate Cdc2 at the Tyr 4 residue, (ii) PKR‐mediated Tyr 4‐phosphorylation facilitates Cdc2 ubiquitination and proteosomal degradation, (iii) unphosphorylated Tyr 4 prevents Cdc2 ubiquitination, and (iv) downstream from p53, PKR has a crucial role in G2 arrest and triggers Cdc2 downregulation under genotoxic conditions.     

mRNA Decapping Enzyme 1a (Dcp1a)-induced Translational Arrest through Protein Kinase R (PKR) Activation Requires the N-terminal Enabled Vasodilator-stimulated Protein Homology 1 (EVH1) Domain

We have shown previously that poliovirus infection disrupts cytoplasmic P-bodies in infected mammalian cells. During the infectious cycle, poliovirus causes the directed cleavage of Dcp1a and Pan3, coincident with the dispersion of P-bodies. We now show that expression of Dcp1a prior to infection, surprisingly, restricts poliovirus infection. This inhibition of infection was independent of P-body formation because expression of GFP-Dcp1a mutants that cannot enter P-bodies restricted poliovirus infection similar to wild-type GFP-Dcp1a. Expression of wild-type or mutant GFP-Dcp1a induced phosphorylation of eIF2α through the eIF2α kinase protein kinase R (PKR). Activation of PKR required the amino-terminal EVH1 domain of Dcp1a. This PKR-induced translational inhibition appears to be specific to Dcp1a because the expression of other P-body components, Pan2, Pan3, Ccr4, or Caf1, did not result in the inhibition of poliovirus gene expression or induce eIF2α phosphorylation. The translation blockade induced by Dcp1a expression suggests novel signaling linking RNA degradation/decapping and regulation of translation.     

Solution conformation of adenovirus virus associated RNA-I and its interaction with PKR

Adenovirus virus-associated RNA (VA_I) provides protection against the host antiviral response in part by inhibiting the interferon-induced double stranded RNA-activated protein kinase (PKR). VA_I consists of three base-paired regions; the apical stem responsible for the interaction with double-stranded RNA binding motifs (dsRBMs) of PKR, the central stem required for inhibition, and the terminal stem. The solution conformation of VA_I and VA_I lacking the terminal stem were determined using SAXS that suggested extended conformations that are in agreement with their secondary structures. Solution conformations of VA_I lacking the terminal stem in complex with the dsRBMs of PKR indicated that the apical stem interacts with both dsRNA-binding motifs whereas the central stem does not. Hydrodynamic properties calculated from ab initio models were compared to experimentally determined parameters for model validation. Furthermore, SAXS envelopes were used as a constraint for the in silico modeling of tertiary structure for RNA and RNA–protein complex. Finally, full-length PKR was also studied, but concentration-dependent changes in hydrodynamic parameters prevented ab initio shape determination. Taken together, results provide an improved structural framework that further our understanding of the role VA_I plays in evading host innate immune responses.     

Helicase associated 2 domain is essential for helicase activity of RNA helicase A

RNA helicase A (RHA), a DExD/H box protein, plays critical roles in a wide variety of cellular or viral functions. RHA contains a conserved core helicase domain that is flanked by five other domains. Two double-stranded RNA binding domains (dsRBD1 and dsRBD2) are at the N-terminus, whereas HA2 (helicase associated 2), OB-fold (oligonucleotide- or oligosaccharide-binding fold), and RGG (repeats of arginine and glycine–glycine residues) domains are at the C-terminus. The role of these domains in the helicase activity of RHA is still elusive due to the difficulty of obtaining enzymatically active mutant RHA. Here, we purified a series of mutant RHAs containing deletions in either N-terminus or C-terminus. Analysis of these mutant RHAs reveals that the dsRBDs are not required for RNA unwinding, but can enhance the helicase activity by promoting the binding of RHA to substrate RNA. In contrast, deletion of C-terminal domains including RGG, OB-fold, and HA2 does not significantly affect the binding of RHA to substrate RNA. However, HA2 is essential for the RNA unwinding by RHA whereas the RGG and OB-fold are dispensable. The results indicate that the core helicase domain alone is not enough for RHA to execute the unwinding activity.     

Interaction of Double-stranded RNA-dependent Protein Kinase (PKR) with the Death Receptor Signaling Pathway in Amyloid �� (A��)-treated Cells and in APPSLPS1 Knock-in Mice

For 10 years, research has focused on signaling pathways controlling translation to explain neuronal death in Alzheimer Disease (AD). Previous studies demonstrated in different cellular and animal models and AD patients that translation is down-regulated by the activation of double-stranded RNA-dependent protein kinase (PKR). Among downstream factors of PKR, the Fas-associated protein with a death domain (FADD) and subsequent activated caspase-8 are responsible for PKR-induced apoptosis in recombinant virus-infected cells. However, no studies have reported the role of PKR in death receptor signaling in AD. The aim of this project is to determine physical and functional interactions of PKR with FADD in amyloid-β peptide (Aβ) neurotoxicity and in APP_SLPS1 KI transgenic mice. In SH-SY5Y cells, results showed that Aβ42 induced a large increase in phosphorylated PKR and FADD levels and a physical interaction between PKR and FADD in the nucleus, also observed in the cortex of APP_SLPS1 KI mice. However, PKR gene silencing or treatment with a specific PKR inhibitor significantly prevented the increase in pT⁴⁵¹-PKR and pS¹⁹⁴-FADD levels in SH-SY5Y nuclei and completely inhibited activities of caspase-3 and -8. The contribution of PKR in neurodegeneration through the death receptor signaling pathway may support the development of therapeutics targeting PKR to limit neuronal death in AD.