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.     

In vivo regulation of the dsRNA-dependent protein kinase PKR by the cellular glycoprotein p67

Regulation of eIF2alpha phosphorylation is critical to the maintenance of cellular homeostasis, and eIF2alpha kinases are subject to complex and multidimensional controls. A cellular 67 kDa glycoprotein (p67) has been proposed to have an important role in regulating the activity of eIF2alpha kinases including the interferon-induced, dsRNA-stimulated protein kinase PKR. To dissect p67-PKR interactions and evaluate their significance in vivo, we have used a vaccinia virus (VV) expression system that successfully mimics PKR control pathways. Recombinant VV were constructed that constitutively express p67 and inducibly express PKR in BSC-40 cells. Stable expression of p67 reduced the PKR-mediated antiviral response and apoptosis. These effects correlated with decreased eIF2alpha phosphorylation, with rescue of PKR-mediated inhibition of protein synthesis, and with partial inhibition of PKR-triggered activation of NF-kappaB. The direct interaction between PKR and p67 was suggested by in vivo and in vitro analyses. These data demonstrate that in vivo p67 is an important modulator of PKR-mediated signal transduction pathways and may provide a useful tool to dissect the relative contributions of PKR to cell growth and stress response.     

HIV-1 TAR RNA subverts RNA interference in transfected cells through sequestration of TAR RNA-binding protein, TRBP

TAR RNA-binding protein, TRBP, was recently discovered to be an essential partner for Dicer and a crucial component of the RNA-induced silencing complex (RISC), a critical element of the RNA interference (RNAi) of the cell apparatus. Human TRBP was originally characterized and cloned 15 years ago based on its high affinity for binding the HIV-1 encoded leader RNA, TAR. RNAi is used, in part, by cells to defend against infection by viruses. Here, we report that transfected TAR RNA can attenuate the RNAi machinery in human cells. Our data suggest that TAR RNA sequesters TRBP rendering it unavailable for downstream Dicer-RISC complexes. TAR-induced inhibition of Dicer-RISC activity in transfected cells was partially relieved by exogenous expression of TRBP.     

The staurosporine analog, Ro-31-8220, induces apoptosis independently of its ability to inhibit protein kinase C

A series of bisindolylmaleimide (Bis) compounds were designed as analogs of the natural compound staurosporine (STS), which is a potent inducer of apoptosis. Many of the Bis analogs appear to be highly selective inhibitors of the protein kinase C (PKC) family, including PKC-alpha, -beta, -gamma, -delta, -epsilon, and -zeta, unlike STS, which is an inhibitor of a broad spectrum of protein kinases. In this report we describe the effects of the Bis analogs, Bis-I, Bis-II, Bis-III and Ro-31-8220 on the survival and proliferation of HL-60 cells, which have been widely used as a model cell system for studying the biological roles of PKC. Treatment of HL-60 cells with Bis-I, Bis-II, Bis-III, or Ro-31-8220 blocked phosphorylation of the PKC target protein Raf-1 with equal potency but did not appear to affect the general phosphorylation of proteins by other kinases. However, the biological effects of the Bis compounds were different: Bis-I and Bis-II had no observable effects on either cell survival or proliferation; Bis-III inhibited cell proliferation but not survival, whereas Ro-31-8220 induced apoptosis. These results indicated that the members of the PKC family which could be inhibited by the Bis analogs were required neither for survival nor proliferation of HL-60 cells. Analyses of cells treated with Ro-31-8220 showed that the apoptotic effect of Ro-31-8220 on HL-60 cells was mediated by a well-characterized transduction process of apoptotic signals: i.e., mitochondrial cytochrome c efflux and the activation of caspase-3 in the cytosol. Moreover, the ability of Ro-31-8220 to induce apoptotic activation was completely inhibited by the over-expression of the apoptotic suppressor gene, Bcl-2, in the cells. Interestingly, proliferation of the Bcl-2-over-expressing cells was still sensitive to the presence of Ro-31-8220, suggesting that the inhibitory effects of Ro-31-8220 on viability and cell proliferation were mediated by different mechanisms. In particular, the apoptotic effect of Ro-31-8220 on cells was not altered by the presence of an excess amount of the other Bis analogs, suggesting that this effect is mediated by a factor(s) other than PKC or by a mechanism which was not saturable by the other Bis analogs. Finally, structure-function analyses of compounds related to Ro-31-8220 revealed that a thioamidine prosthetic group in Ro-311-8220 was largely responsible for its apoptotic activity.     

Caspase 9 activation by the dsRNA-dependent protein kinase,PKR: molecular mechanism and relevance

The double-stranded RNA-dependent protein kinase (PKR) induces apoptosis by activation of the FADD/caspase 8 pathway. Here we show that upon PKR expression, caspase 9 is processed and activated, correlating with the translocation of cytochrome c to the cytoplasm and breakdown of mitochondrial potential upon Bax insertion. However, treatment of cells with an inhibitor of caspase 9 could not prevent PKR-induced apoptosis. During PKR-induced apoptosis, caspase 9 is activated downstream of caspase 8. Our findings revealed that caspase 9, although dispensable, is a mediator of PKR-induced cell death.     

Relatedness of an RNA-binding motif in human immunodeficiency virus type 1 TAR RNA-binding protein TRBP to human P1/dsI kinase and Drosophila staufen.

TRBP is a human cellular protein that binds the human immunodeficiency virus type 1 TAR RNA. Here, we show that the intact presence of amino acids 247 to 267 in TRBP correlates with its ability to bind RNA. This region contains a lysine- and arginine-rich motif, KKLAKRNAAAKMLLRVHTVPLDAR. A 24-amino-acid synthetic peptide (TR1) of this sequence bound TAR RNA with affinities similar to that of the entire TRBP, thus suggesting that this short motif contains a sufficient RNA-binding activity. Using RNA probe-shift analysis, we determined that TR1 does not bind all double-stranded RNAs but prefers TAR and other double-stranded RNAs with G+C-rich characteristics. Immunoprecipitation of TRBP from human immunodeficiency virus type 1-infected T lymphocytes recovered TAR RNA. This is consistent with a TRBP-TAR ribonucleoprotein during viral infection. Computer alignment revealed that TR1 is highly homologous to the RNA-binding domain of human P1/dsI protein kinase and two regions within Drosophila Staufen. We suggest that these proteins are related by virtue of sharing a common RNA-binding moiety.     

Small interfering RNAs against the TAR RNA binding protein, TRBP, a Dicer cofactor, inhibit human immunodeficiency virus type 1 long terminal repeat expression and viral production

RNA interference (RNAi) is now widely used for gene silencing in mammalian cells. The mechanism uses the RNA-induced silencing complex, in which Dicer, Ago2, and the human immunodeficiency virus type 1 (HIV-1) TAR RNA binding protein (TRBP) are the main components. TRBP is a protein that increases HIV-1 expression and replication by inhibition of the interferon-induced protein kinase PKR and by increasing translation of viral mRNA. After HIV infection, TRBP could restrict the viral RNA through its activity in RNAi or could contribute more to the enhancement of viral replication. To determine which function will be predominant in the virological context, we analyzed whether the inhibition of its expression could enhance or decrease HIV replication. We have generated small interfering RNAs (siRNAs) against TRBP and found that they decrease HIV-1 long terminal repeat (LTR) basal expression 2-fold, and the LTR Tat transactivated level up to 10-fold. In the context of HIV replication, siRNAs against TRBP decrease the expression of viral genes and inhibit viral production up to fivefold. The moderate increase in PKR expression and activation indicates that it contributes partially to viral gene inhibition. The moderate decrease in micro-RNA (miRNA) biogenesis by TRBP siRNAs suggests that in the context of HIV replication, TRBP functions other than RNAi are predominant. In addition, siRNAs against Dicer decrease viral production twofold and impede miRNA biogenesis. These results suggest that, in the context of HIV replication, TRBP contributes mainly to the enhancement of virus production and that Dicer does not mediate HIV restriction by RNAi.     

The rotaviral NSP3 protein stimulates translation of polyadenylated target mRNAs independently of its RNA-binding domain

The non-structural protein 3 (NSP3) of rotaviruses is an RNA-binding protein that specifically recognises a 4 nucleotide sequence at the 3′ extremity of the non-polyadenylated viral mRNAs. NSP3 also has a high affinity for eIF4G. These two functions are clearly delimited in separate domains the structures of which have been determined. They are joined by a central domain implicated in the dimerisation of the full length protein. The bridging function of NSP3 between the 3′ end of the viral mRNA and eIF4G has been proposed to enhance the synthesis of viral proteins. However, this role has been questioned as knock-down of NSP3 did not impair viral protein synthesis. We show here using a MS2/MS2-CP tethering assay that a C-terminal fragment of NSP3 containing the eIF4G binding domain and the dimerisation domain can increase the expression of a protein encoded by a target reporter mRNA in HEK 293 cells. The amount of reporter mRNA in the cells is not significantly affected by the presence of the NSP3 derived fusion protein showing that the enhanced protein expression is due to increased translation. These results show that NSP3 can act as a translational enhancer even on a polyadenylated mRNA that should be a substrate for PABP1.     

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.     

Functional characterization of and cooperation between the double-stranded RNA-binding motifs of the protein kinase PKR

The interferon-inducible double-stranded RNA (dsRNA)-activated protein kinase PKR is regulated by dsRNAs that interact with the two dsRNA-binding motifs (dsRBMs) in its N terminus. The dsRBM is a conserved protein motif found in many proteins from most organisms. In this study, we investigated the biochemical functions and cytological activities of the two PKR dsRBMs (dsRBM1 and dsRBM2) and the cooperation between them. We found that dsRBM1 has a higher affinity for binding to dsRNA than dsRBM2. In addition, dsRBM1 has RNA-annealing activity that is not displayed by dsRBM2. Both dsRBMs have an intrinsic ability to dimerize (dsRBM2) or multimerize (dsRBM1). Binding to dsRNA inhibits oligomerization of dsRBM1 but not dsRBM2 and strongly inhibits the dimerization of the intact PKR N terminus (p20) containing both dsRBMs. dsRBM1, like p20, activates reporter gene expression in transfection assays, and it plays a determinative role in localizing PKR to the nucleolus and cytoplasm of the cell. Thus, dsRBM2 has weak or no activity in dsRNA binding, stimulation of gene expression, and PKR localization, but it strongly enhances these functions of dsRBM1 when contained in p20. However, dsRBM2 does not enhance the annealing activity of dsRBM1. This study shows that the dsRBMs of PKR possess distinct properties and that some, but not all, of the functions of the enzyme depend on cooperation between the two motifs.     

Activation of the protein kinase PKR by short double-stranded RNAs with single-stranded tails

The human RNA-activated protein kinase PKR is an interferon-induced protein that is part of the innate immune response and inhibits viral replication. The action of PKR involves RNA-dependent autophosphorylation leading to inhibition of translation. PKR has an N-terminal dsRNA-binding domain that can interact non-sequence specifically with long (>33 bp) stretches of dsRNA leading to activation. In addition, certain viral and cellular RNAs containing non-Watson-Crick structures and multiple, shorter dsRNA sections can regulate PKR. In an effort to identify novel binders and possible activators of PKR, we carried out selections on a partially structured dsRNA library using truncated and full-length versions of PKR. A library with 10(11) sequences was constructed and aptamers that bound to His6-tagged proteins were isolated. Characterization revealed a novel minimal RNA motif for activation of PKR with the following unified structural characteristics: a hairpin with a nonconserved imperfect 16-bp dsRNA stem flanked by 10-15-nt single-stranded tails, herein termed a "ss-dsRNA motif." Boundary experiments revealed that the single-stranded tails flanking the dsRNA core provide the critical determinant for activation. The ss-dsRNA motif occurs in a variety of cellular and viral RNAs, suggesting possible novel functions for PKR in nature.     

Stress-induced phosphorylation of PACT reduces its interaction with TRBP and leads to PKR activation

PACT is a stress-modulated activator of interferon (IFN)-induced double-stranded (ds) RNA-activated protein kinase (PKR) and is an important regulator of PKR-dependent signaling pathways. Stress-induced phosphorylation of PACT is essential for PACT's association with PKR leading to PKR activation. PKR activation by PACT leads to phosphorylation of translation initiation factor eIF2α, inhibition of protein synthesis, and apoptosis. In addition to positive regulation by PACT, PKR activity in cells is also negatively regulated by TRBP. In this study, we demonstrate for the first time that stress-induced phosphorylation at serine 287 significantly increases PACT's ability to activate PKR by weakening PACT's interaction with TRBP. A non-phosphorylatable alanine substitution mutant at this position causes enhanced interaction of PACT with TRBP and leads to a loss of PKR activation. Furthermore, TRBP overexpression in cells is unable to block apoptosis induced by a phospho-mimetic, constitutively active PACT mutant. These results demonstrate for the first time that stress-induced PACT phosphorylation functions to free PACT from the inhibitory interaction with TRBP and also to enhance its interaction with PKR.     

Structure of the double-stranded RNA-binding domain of the protein kinase PKR reveals the molecular basis of its dsRNA-mediated activation.

Protein kinase PKR is an interferon-induced enzyme that plays a key role in the control of viral infections and cellular homeostasis. Compared with other known kinases, PKR is activated by a distinct mechanism that involves double-stranded RNA (dsRNA) binding in its N-terminal region in an RNA sequence-independent fashion. We report here the solution structure of the 20 kDa dsRNA-binding domain (dsRBD) of human PKR, which provides the first three-dimensional insight into the mechanism of its dsRNA-mediated activation. The structure of dsRBD exhibits a dumb-bell shape comprising two tandem linked dsRNA-binding motifs (dsRBMs) both with an alpha-beta-beta-beta-alpha fold. The structure, combined with previous mutational and biochemical data, reveals a highly conserved RNA-binding site on each dsRBM and suggests a novel mode of protein-RNA recognition. The central linker is highly flexible, which may enable the two dsRBMs to wrap around the RNA duplex for cooperative and high-affinity binding, leading to the overall change of PKR conformation and its activation.