Protein kinase R
Protein kinase RNA-activated also known as protein kinase R, interferon-induced, double-stranded RNA-activated protein kinase, or eukaryotic translation initiation factor 2-alpha kinase 2 is an enzyme that in humans is encoded by the EIF2AK2 gene.
PKR protects against viral infections.
Mechanism of action
Protein kinase-R is activated by double-stranded RNA, introduced to the cells by a viral infection. PKR can also be activated by the protein PACT or by heparin. PKR contains an N-terminal dsRNA binding domain and a C-terminal kinase domain, that gives it pro-apoptotic functions. The dsRBD consists of two tandem copies of a conserved double stranded RNA binding motif, dsRBM1 and dsRBM2. PKR is induced by interferon in a latent state. Binding to dsRNA is believed to activate PKR by inducing dimerization and subsequent auto-phosphorylation reactions. In situations of viral infection, the dsRNA created by viral replication and gene expression binds to the N-terminal domain, activating the protein. Once active, PKR is able to phosphorylate the eukaryotic translation initiation factor eIF2α. This inhibits further cellular mRNA translation, thereby preventing viral protein synthesis. Since ElF2α is involved in the commonly initiation translation from an AUG codon, the alternative non-AUG initiation takes place instead. An example of mRNAs using non-AUG initiation are mRNAs for the heat shock proteins. Active PKR is also able to mediate the activation of the transcription factor NFkB, by phosphorylating its inhibitory subunit, IkB. Activated NFkB upregulates the expression of Interferon cytokines, which work to spread the antiviral signal locally. Active PKR is also able to activate tumor suppressor PP2A which regulates the cell cycle and the metabolism. Through complex mechanisms, active PKR is also able to induce cellular apoptosis, to prevent further viral spread.PKR stress pathway
PKR is in the center of cellular response to different stress signals such as pathogens, lack of nutrients, cytokines, irradiation, mechanical stress, or ER stress. PKR pathway leads to stress response through activation of other stress pathway such as JNK, p38, NFkB, PP2A and phosphorylation of eIF2α. ER stress caused by excess of unfolded proteins leads to inflammatory responses. PKR contributes to this response by interacting with several inflammatory kinases such as IKK, JNK, ElF2α, insulin receptor and others. This metabolically activated inflammatory complex is called metabolic inflammasome or metaflammasome.Viral defense
Viruses have developed many mechanisms to counteract the PKR mechanism. It may be done by Decoy dsRNA, degradation, hiding of virus dsRNA, dimerization block, dephosphorylation of substrate or by a pseudosubstrate.For instance, Epstein–Barr virus uses the gene EBER1 to produce decoy dsRNA. This leads to cancers such as Burkitt's lymphoma, Hodgkin's disease, nasopharyngeal carcinoma and various leukemias.
| Defense type | Virus | Molecule |
| Decoy dsRNA | Adenovirus | VAI RNA |
| Decoy dsRNA | Epstein–Barr virus | EBER |
| Decoy dsRNA | HIV | TAR |
| PKR degradation | Poliovirus | 2Apro |
| hide viral dsRNA | Vaccinia virus | E3L |
| hide viral dsRNA | Reovirus | σ3 |
| hide viral dsRNA | Influenza virus | NS1 |
| Dimerization block | Influenza virus | p58IPK |
| Dimerization block | Hepatitis C virus | NS5A |
| Pseudosubstrate | Vaccinia virus | K3L |
| Pseudosubstrate | HIV | Tat |
| Dephosphorylation of substrate | Herpes simplex virus | ICP34.5 |
Memory and learning
PKR knockout mice or inhibition of PKR in mice enhances memory and learning.Neuronal degeneration disease
First report in 2002 has been shown that immunohistochemical marker for phosphorylated PKR and eIF2α was displayed positively in degenerating neurons in the hippocampus and the frontal cortex of patients with Alzheimer's disease, suggesting the link between PKR and AD. Additionally, many of these neurons were also immunostained with an antibody for phosphorylated Tau protein. Activated PKR was specifically found in the cytoplasm and nucleus, as well as co-localized with neuronal apoptotic markers. Further studies have assessed the levels of PKR in blood and cerebrospinal fluid of AD patients and controls. The result of an analysis of the concentrations of total and phosphorylated PKR in peripheral blood mononuclear cells in 23 AD patients and 19 control individuals showed statistically significant increased levels of the ratio of phosphorylated PKR/PKR in AD patients compared with controls. Assessments of CSF biomarkers, such as Aβ1-42, Aβ1-40, Tau, and phosphorylated Tau at threonine 181, have been a validated use in clinical research and in routine practice to determine whether patients have CSF abnormalities and AD brain lesions. A study found that "total PKR and pPKR concentrations were elevated in AD and amnestic mild cognitive impairment subjects with a pPKR value discriminating AD patients from control subjects with a sensitivity of 91.1% and a specificity of 94.3%. Among AD patients, total PKR and pPKR levels correlate with CSF p181tau levels. Some AD patients with normal CSF Aß, T-tau, or p181tau levels had abnormal total PKR and pPKR levels". It was concluded that the PKR-eIF2α pro-apoptotic pathway could be involved in neuronal degeneration that leads to various neuropathological lesions as a function of neuronal susceptibility.PKR and beta amyloid
Activation of PKR can cause accumulation of amyloid β-peptide via de-repression of BACE1 expression in Alzheimer Disease patients. Normally, the 5′untranslated region in the BACE1 promoter would fundamentally inhibit the expression of BACE1 gene. However, BACE1 expression can be activated by phosphorylation of eIF2a, which reverses the inhibitory effect exerted by BACE1 5′UTR. Phosphorylation of eIF2a is triggered by activation of PKR. Viral infection such as Herpes Simplex Virus or oxidative stress can both increase BACE1 expression through activation of PKR-eIF2a pathway.
In addition, the increased activity of BACE1 could also lead to β-cleaved carboxy-terminal fragment of β-Amyloid precursor protein induced dysfunction of endosomes in AD. Endosomes are highly active β-Amyloid precursor protein processing sites, and endosome abnormalities are associated with upregulated expression of early endosomal regulator, rab5. These are the earliest known disease-specific neuronal response in AD. Increased activity of BACE1 leads to synthesis of the APP-βCTF. An elevated level of βCTF then causes rab 5 overactivation. βCTF recruits APPL1 to rab5 endosomes, where it stabilizes active GTP-rab5, leading to pathologically accelerated endocytosis, endosome swelling and selectively impaired axonal transport of rab5 endosomes.
PKR and Tau phosphorylation
It is reported earlier that phosphorylated PKR could co-localize with phosphorylated Tau protein in affected neurons. A protein phosphatase-2A inhibitor – Okadaic acid – is known to increase tau phosphorylation, Aβ deposition and neuronal death. It is studied that OA also induces PKR phosphorylation and thus, eIF2a phosphorylation. eIF2a phosphorylation then induces activation of transcription factor 4, which induces apoptosis and nuclear translocation, contributing to neuronal death.
is responsible for tau phosphorylation and controls several cellular functions including apoptosis. Another study demonstrated that tunicamycin or Aβ treatment can induce PKR activation in human neuroblastoma cells and can trigger GSK3β activation, as well as tau phosphorylation. They found that in AD brains, both activated PKR and GSK3β co-localize with phosphorylated tau in neurons. In SH-SY5Y cell cultures, tunicamycin and Aβ activate PKR, which then can modulate GSK-3β activation and induce tau phosphorylation, apoptosis. All these processes are attenuated by PKR inhibitors or PKR siRNA. PKR could represent a crucial signaling point relaying stress signals to neuronal pathways by interacting with transcription factor or indirectly controlling GSK3β activation, leading to cellular degeneration in AD.